U.S. patent application number 15/248588 was filed with the patent office on 2017-03-02 for fluid connections using guide mechanisms.
The applicant listed for this patent is EMULATE, Inc.. Invention is credited to Joshua Gomes, Christopher David Hinojosa, Daniel Levner, Petrus Wilhelmus Martinus van Ruijven, Christian Alexander Potzner, Josiah Daniel Sliz, Matthew Daniel Solomon, Guy Robert Thompson, Patrick Sean Tuohy.
Application Number | 20170056880 15/248588 |
Document ID | / |
Family ID | 57119971 |
Filed Date | 2017-03-02 |
United States Patent
Application |
20170056880 |
Kind Code |
A1 |
Levner; Daniel ; et
al. |
March 2, 2017 |
FLUID CONNECTIONS USING GUIDE MECHANISMS
Abstract
Drop-to-drop connection schemes are described for putting a
microfluidic device in fluidic communication with a fluid source or
another microfluidic device. Methods for establishing fluid
connections with guide mechanisms are described.
Inventors: |
Levner; Daniel; (Brookline,
MA) ; Sliz; Josiah Daniel; (Boston, MA) ;
Hinojosa; Christopher David; (Cambridge, MA) ;
Thompson; Guy Robert; (Watertown, MA) ; Martinus van
Ruijven; Petrus Wilhelmus; (Glen Waverley, AU) ;
Solomon; Matthew Daniel; (Hughesdale, AU) ; Potzner;
Christian Alexander; (Port Melbourne, AU) ; Tuohy;
Patrick Sean; (St. Kilda, AU) ; Gomes; Joshua;
(Somerville, MA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
EMULATE, Inc. |
Boston |
MA |
US |
|
|
Family ID: |
57119971 |
Appl. No.: |
15/248588 |
Filed: |
August 26, 2016 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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62366482 |
Jul 25, 2016 |
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62361244 |
Jul 12, 2016 |
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62250861 |
Nov 4, 2015 |
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62210122 |
Aug 26, 2015 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
B01L 2300/123 20130101;
C12M 21/08 20130101; B01L 2300/0681 20130101; B01L 2300/0887
20130101; C12M 23/40 20130101; B01L 3/502715 20130101; B01L
2300/161 20130101; B01L 2300/165 20130101; B01L 2300/14 20130101;
C12M 35/04 20130101; C12N 2521/00 20130101; A01N 1/0247 20130101;
B01L 2200/12 20130101; B01L 9/527 20130101; C12M 23/38 20130101;
C12M 41/40 20130101; B01L 3/502707 20130101; B01L 2200/027
20130101; C12N 5/0602 20130101; B01L 2400/06 20130101; C12M 23/16
20130101; C12M 23/42 20130101; B01L 2400/0487 20130101; C12M 41/48
20130101; B01L 3/502738 20130101; A01N 1/021 20130101; B01L
2400/0481 20130101; B01L 2200/025 20130101; C12M 29/10 20130101;
B01L 3/50273 20130101 |
International
Class: |
B01L 3/00 20060101
B01L003/00; C12M 3/06 20060101 C12M003/06 |
Claims
1. A system comprising: a) a first substrate comprising a first
fluidic port, b) a second substrate comprising a second fluidic
port, c) a guide mechanism adapted to align the first port and the
second port, and d) a retention mechanism adapted to retain the
first substrate in contact with the second substrate.
2. The system of claim 1, wherein the guide mechanism is a guide
track positioned on said first substrate, said guide track
configured to engage a portion of said second substrate.
3. The system of claim 1, wherein the retention mechanism is a clip
positioned on said second substrate, said clip configured to engage
said first substrate.
4. A system comprising: a) a first substrate comprising a first set
of one or more fluidic ports, b) a second substrate comprising a
second set of one or more fluidic ports, c) a guide mechanism
adapted to align the first set of ports and the second set of
ports, and d) a retention mechanism adapted to retain the first
substrate in contact with the second substrate.
5. The system of claim 4, wherein the guide mechanism is a guide
track positioned on said first substrate, said guide track
configured to engage a portion of said second substrate.
6. The system of claim 4, wherein the retention mechanism is a clip
positioned on said second substrate, said clip configured to engage
said first substrate.
7. A method for establishing a fluidic connection, comprising: a)
providing a first substrate comprising a first fluidic port, a
second substrate comprising a second fluidic port, and a guide
mechanism adapted to guide the second substrate, b) engaging the
second substrate with the guide mechanism, c) aligning the first
and second sets of fluidic ports by help of the guide mechanism,
and d) contacting the first and second fluidic ports to establish a
fluidic connection.
8. The method of claim 7 wherein said guide mechanism comprises a
guide track positioned on said first substrate, said guide track
configured to engage a portion of said second substrate.
9. The method of claim 7, wherein said second substrate comprises a
microfluidic device comprising a mating surface, wherein said
second fluidic port is positioned on said mating surface and
comprises a droplet protruding above said mating surface.
10. The method of claim 9, wherein said first substrate comprises a
mating surface, wherein said first fluidic port is positioned on
said mating surface and comprises a protruding droplet.
11. The method of claim 10, wherein said contacting of step d)
causes a droplet-to-droplet connection when said first and second
fluidic ports to establish a fluidic connection.
12. The method of claim 11, wherein said droplet-to-droplet
connection does not permit air to enter said one or more fluid
inlet ports.
13. The method of claim 8, wherein said aligning of step c)
comprises sliding the second substrate by means of the guide
track.
14. The method of claim 8, wherein said guide track comprises first
and second sections, said first section shaped to support the
aligning of step c), said second section shaped to support the
contacting of step d).
15. The method of claim 7, wherein said second substrate comprises
a retention mechanism adapted to retain the first substrate in
contact with the second substrate.
16. The method of claim 15, further comprising the step of e)
activating the retention mechanism.
17. A system comprising: a) a first substrate comprising a first
fluidic port, b) a second substrate comprising a second fluidic
port, c) a third substrate configured to support said second
substrate; a) a guide mechanism adapted to align the first port
with second port, and b) a retention mechanism means adapted to
retain the first substrate in contact with the second
substrate.
18. The system of claim 17, wherein the guide mechanism comprises a
guide track.
19. The system of claim 18, wherein the guide track is positioned
on said first substrate.
20. The system of claim 19, wherein the third substrate comprises
edges configured to engage said guide track.
21. The system of claim 20, wherein said retention mechanism is
positioned on said third substrate.
22. The system of claim 21, wherein said retention mechanism
comprises a clip configured to engage said first substrate.
23. The system of claim 21, wherein said retention mechanism
comprises a clamp configured to engage said first substrate under
conditions such that contact between said first and second
substrates is maintained.
24. The system of claim 21, wherein said retention mechanism
comprises a stud configured to engage a hole on said first
substrate.
25. The system of claim 21, wherein said retention mechanism
engages a portion of said first substrate in a friction fit.
26. The system of claim 21, wherein said retention mechanism is
selected from the group consisting of an adhesive, a heat stake,
and a screw.
27. The system of claim 26, wherein said adhesive is a
laminate.
28. An assembly, comprising: a) a first substrate comprising a
first fluidic port and a guide mechanism, said first substrate
positioned against and in contact with b) a second substrate
comprising a second fluidic port, wherein said first and second
ports are aligned so as to permit fluidic communication, said
second substrate supported by c) a carrier, said carrier comprising
a portion engaging said guide mechanism of said first
substrate.
29. The assembly of claim 28, wherein said carrier further
comprises a retention mechanism for retaining said contact between
said first and second substrates.
30. The assembly of claim 28, wherein the guide mechanism comprises
a guide track.
31. The assembly of claim 30, wherein the guide track is positioned
on one or more sides of said first substrate.
32. The assembly of claim 31, wherein the carrier portion engaging
said first substrate comprises one or more edges configured to
engage said guide track.
33. The assembly of claim 28, wherein said retention mechanism
comprises a clip configured to engage said first substrate.
34. The assembly of claim 28, wherein said retention mechanism
comprises a clamp configured to engage said first substrate.
35. The assembly of claim 28, wherein said retention mechanism
comprises a stud configured to engage a hole on said first
substrate.
36. The assembly of claim 28, wherein said retention mechanism
engages a portion of said first substrate in a friction fit.
37. The assembly of claim 28, wherein said retention mechanism is
selected from the group consisting of an adhesive, a heat stake,
and a screw.
38. The assembly of claim 37, wherein said adhesive is a
laminate.
39. A method for establishing a fluidic connection, comprising: a)
providing a first substrate comprising a first fluidic port, a
second substrate comprising a second fluidic port, a third
substrate configured to support said second substrate, and a guide
mechanism; b) aligning said first and second ports with said guide
mechanism; and c) contacting said first port with said second port
under conditions such that a fluidic connection is established
between said first and second substrate.
40. The method of claim 39, wherein the guide mechanism comprises a
guide track.
41. The method of claim 40, wherein the guide track is positioned
on said first substrate.
42. The method of claim 41, wherein the third substrate comprises
edges configured to engage said guide track.
43. The method of claim 42, wherein said aligning of step b)
comprises sliding said third substrate by means of said guide
track.
44. The method of claim 41, wherein said guide track comprises
first and second sections, said first section shaped to support the
aligning of step b), said second section shaped to support the
contacting of step c).
45. The method of claim 44, wherein said first section is linear
and said second section is curved.
46. The method of claim 39, wherein said guide mechanism comprises
a mechanism on which said third substrate rotates or pivots during
step d).
47. The method of claim 46, wherein said guide mechanism comprises
a hinge.
48. The method of claim 39, wherein said third substrate further
comprises a retention mechanism for retaining alignment of said
first and second ports.
49. The method of claim 48, wherein said retention mechanism
comprises a clip configured to engage said first substrate.
50. The method of claim 48, wherein said retention mechanism
comprises a clamp configured to engage said first substrate under
conditions such that contact between said first and second
substrates is maintained.
51. The method of claim 48, wherein said retention mechanism
comprises a stud configured to engage a hole on said first
substrate.
52. The method of claim 48, wherein said retention mechanism
engages a portion of said first substrate in a friction fit.
53. The method of claim 48, wherein said retention mechanism is
selected from the group consisting of an adhesive, a heat stake,
and a screw.
54. The method of claim 53, wherein said adhesive is a
laminate.
55. The method of claim 39, wherein said second substrate comprises
a microfluidic device comprising a mating surface, wherein said
second fluidic port is positioned on said mating surface and
comprises a droplet protruding above said mating surface.
56. The method of claim 55, wherein said first substrate comprises
a mating surface, wherein said first fluidic port is positioned on
said mating surface and comprises a protruding droplet.
57. The method of claim 56, wherein said contacting of step c)
causes a droplet-to-droplet connection when said first and second
fluidic ports to establish a fluidic connection.
58. The method of claim 57, wherein said droplet-to-droplet
connection does not permit air to enter said one or more fluid
inlet ports.
59. A method for establishing a fluidic connection, comprising: a)
providing a first substrate comprising a guide mechanism and a
first fluidic port on a first mating surface, a second substrate
comprising a second fluidic port on a second mating surface and a
bottom surface, and a carrier in contact with said bottom surface
of said second substrate, said carrier comprising a retention
mechanism and one or more edges for engaging said guide mechanism;
b) engaging said guide mechanism of said first substrate with one
or more edges of said carrier; c) aligning said first and second
ports with said guide mechanism; d) contacting said first mating
surface with said second mating surface under conditions such that
said first port contacts said second port and a fluidic connection
is established between said first and second substrate.
60. The method of claim 59, wherein the guide mechanism comprises a
guide track.
61. The method of claim 60, wherein the guide track is positioned
on one or more sides of said first substrate.
62. The method of claim 61, wherein the carrier comprises one or
more edges configured to engage said guide track.
63. The method of claim 62, wherein said aligning of step c)
comprises sliding said carrier by means of said guide track.
64. The method of claim 63, wherein said guide track comprises
first and second sections, said first section shaped to support the
aligning of step c), said second section shaped to support the
contacting of step d).
65. The method of claim 64, wherein said first section is linear
and said second section is curved.
66. The method of claim 59, wherein said guide mechanism comprises
a mechanism on which said carrier rotates or pivots during step
d).
67. The method of claim 66, wherein said guide mechanism comprises
a hinge.
68. The method of claim 59, further comprising the step of e)
activating said retention mechanism under condition such that said
alignment of said first and second ports is retained.
69. The method of claim 59, wherein said retention mechanism
comprises a clip configured to engage said first substrate.
70. The method of claim 59, wherein said retention mechanism
comprises a clamp configured to engage said first substrate under
conditions such that contact between said first and second
substrates is maintained.
71. The method of claim 59, wherein said retention mechanism
comprises a stud configured to engage a hole on said first
substrate.
72. The method of claim 59, wherein said retention mechanism
engages a portion of said first substrate in a friction fit.
73. The method of claim 59, wherein said retention mechanism is
selected from the group consisting of an adhesive, a heat stake,
and a screw.
74. The method of claim 73, wherein said adhesive is a
laminate.
75. The method of claim 59, wherein said second fluidic port
comprises a droplet protruding above said mating surface of said
second substrate
76. The method of claim 75, wherein said first fluidic port
comprises a protruding droplet.
77. The method of claim 76, wherein said contacting of step d)
causes a droplet-to-droplet connection when said first and second
fluidic ports to establish a fluidic connection.
78. The method of claim 77, wherein said droplet-to-droplet
connection does not permit air to enter said one or more fluid
inlet ports.
Description
FIELD OF THE INVENTION
[0001] A perfusion manifold assembly is contemplated that allows
for perfusion of a microfluidic device, such as an organ on a chip
microfluidic device comprising cells that mimic cells in an organ
in the body or at least one function of an organ, that is
detachably linked with said assembly so that fluid enters ports of
the microfluidic device from a fluid reservoir, optionally without
tubing, at a controllable flow rate. A drop-to-drop connection
scheme is contemplated as one embodiment for putting a microfluidic
device in fluidic communication with a fluid source or another
microfluidic device, including but not limited to, putting a
microfluidic device in fluidic communication with the perfusion
manifold assembly.
BACKGROUND OF THE INVENTION
[0002] Two-dimensional (2D) monolayer cell culture systems have
been used for many years in biological research. The most common
cell culture platform is the two-dimensional (2D) monolayer cell
culture in petri dishes or flasks. Although such 2D in vitro models
are less expensive than animal models and are conducive to
systematic, and reproducible quantitative studies of cell
physiology (e.g., in drug discovery and development), the
physiological relevance of the information retrieved from in vitro
studies to in vivo system is often questionable. It has now been
widely accepted that three-dimensional (3D) cell culture matrix
promotes many biological relevant functions not observed in 2D
monolayer cell culture. Said another way, 2D cell culture systems
do not accurately recapitulate the structure, function, physiology
of living tissues in vivo.
[0003] U.S. Pat. No. 8,647,861 describes microfluidic
"organ-on-chip" devices comprising living cells on membranes in
microchannels exposed to culture fluid at a flow rate. In contrast
to static 2D culture, micro channels allow the perfusion of cell
culture medium throughout the cell culture during in vitro studies
and as such offer a more in vivo-like physical environment. In
simple terms, an inlet port allows injection of cell culture medium
into a cell-laden microfluidic channel or chamber, thus delivering
nutrients and oxygen to cells. An outlet port then permits the exit
of remaining medium as well as harmful metabolic by-products.
[0004] While such microfluidic devices are an improvement over
traditional static tissue culture models, the small size, scale and
interface of these devices makes fluid handling difficult. What is
needed is a way to control perfusion of these devices in a manner
whereby fluid pressure creates a flow rate that applies a desired
fluid shear stress to the living cells. Ideally, the solution
should provide for a simple user workflow.
SUMMARY OF THE INVENTION
[0005] The present invention contemplates a number of devices
separately and in combination. The present invention contemplates a
perfusion manifold assembly (also referred to as a cartridge, pod
or perfusion disposable, whether or not there is any requirement or
intent to dispose of the component) is contemplated that retains
one or more microfluidic devices, such as "organ-on-a-chip"
microfluidic devices (or simply "microfluidic chip") that comprise
cells that mimic at least one function of an organ in the body, and
allow the perfusion and optionally the mechanical actuation of said
microfluidic devices, optionally without tubing. The present
invention contemplates a number of embodiments of the perfusion
manifold assembly. However, it is not intended that the present
invention be limited to these embodiments. For example, the present
invention contemplates combining features from different
embodiments (as discussed below). In addition, the present
invention contemplates removing features from the embodiments (as
discussed below). Furthermore, the present invention contemplates
substituting features in the embodiments (as discussed below).
[0006] A culture module is contemplated that allows the perfusion
and optionally mechanical actuation of one or more microfluidic
devices, such as organ-on-a-chip microfluidic devices comprising
cells that mimic at least one function of an organ in the body. In
one embodiment, the microfluidic device comprises a top channel, a
bottom channel, and a membrane separating at least a portion of
said top and bottom channels. In one embodiment, the microfluidic
device comprises cells on the membrane and/or in or on the
channels. In one embodiment, the culture module comprises a
pressure manifold that allows for perfusion of a microfluidic
device, such as an "organ on chip" microfluidic device comprising
cells that mimic cells in an organ in the body or at least one
function of an organ, that is optionally retained in contact with a
perfusion disposable and detachably linked with said assembly so
that fluid enters ports of the microfluidic device from a fluid
reservoir, optionally without tubing, at a controllable flow rate.
The perfusion disposable can be used separately from the culture
module, and the microfluidic device or chip can be used separately
from the perfusion disposable. In one embodiment, the present
invention contemplates a (moving or non-moving) pressure manifold
configured to mate with one or more microfluidic devices (such as
any one of the perfusion manifold assembly embodiments described
herein) with integrated valves that can prevent gas leaks when not
mated with a microfluidic device.
[0007] A drop-to-drop connection scheme is contemplated as one
embodiment for putting a microfluidic device in fluidic
communication with a fluid source or another microfluidic device,
including but not limited to, putting a microfluidic device in
fluidic communication with a perfusion disposable. In one
embodiment, the microfluidic device comprises a top channel, a
bottom channel, and a membrane separating at least a portion of
said top and bottom channels. In one embodiment, the microfluidic
device comprises cells on the membrane and/or in or on the
channels.
[0008] A pressure lid is contemplated that allows for the
pressurization of one or more reservoirs within a perfusion
disposable or perfusion manifold assembly (or other microfluidic
device), the pressure lid being movable or removably attached to
said perfusion disposable or other microfluidic device to allow
improved access to elements (e.g. reservoirs) within. The pressure
lid can be removed from the perfusion disposable and the perfusion
disposable can be used without the lid. In one embodiment, the
perfusion disposable comprises a microfluidic chip, and the chip
comprises a top channel, a bottom channel, and a membrane
separating at least a portion of said top and bottom channels. In
one embodiment, the microfluidic chip comprises cells on the
membrane and/or in or on the channels.
[0009] A method for pressure control is contemplated to allow the
control of flow rate (while perfusing cells) despite limitations of
common pressure regulators. Rather than having the pressure
controllers (or actuators) of a culture module "on" all of the time
(or at just one setpoint), in one embodiment, they are switched
"on" and "off" (or between two or more setpoints) in a pattern.
Accordingly, the switching pattern may be selected such that the
average value of pressure acting liquid in one or more reservoirs
of an engaged perfusion disposable (containing a microfluidic
device or chip) corresponds to a desired value. In one embodiment,
the microfluidic device comprises a top channel, a bottom channel,
and a membrane separating at least a portion of said top and bottom
channels. In one embodiment, the microfluidic device comprises
cells on the membrane and/or in or on the channels.
[0010] In one embodiment, the perfusion manifold assembly comprises
i) a cover or lid configured to serve as the top of ii) one or more
fluid reservoirs, iii) a capping layer under said fluid
reservoir(s), iv) a fluidic backplane under, and in fluidic
communication with, said fluid reservoir(s), said fluidic backplane
comprising a resistor, and v) a projecting member or skirt (for
engaging the microfluidic device or a carrier containing a
microfluidic device). As noted above, the cover or lid can be
removed and the perfusion manifold assembly can still be used. In
one embodiment, the assembly further comprises fluid ports
positioned at the bottom of the fluidic backplane. In one
embodiment, the capping layer caps the fluid backplane. Without
being bound by theory of any particular mechanism, it is believed
that these resistors serve to stabilize the flow of fluid coming
from the reservoirs so that a stable flow can be delivered to the
microfluidic device, and/or they serve to provide a means for
translating reservoir pressure to perfusion flow rate. In one
embodiment, the lid is held onto the reservoir using a radial seal.
This does not require an applied pressure to create a seal. In
another embodiment, the lid is held onto the reservoir using one or
more clips, screws or other retention mechanisms. In one
embodiment, the projecting member or skirt is engaged with a
microfluidic chip. In one embodiment, the microfluidic chip
comprises a top channel, a bottom channel, and a membrane
separating at least a portion of said top and bottom channels. In
one embodiment, the microfluidic device comprises cells on the
membrane and/or in or on the channels.
[0011] In one embodiment, the perfusion manifold assembly comprises
i) one or more fluid reservoirs, and ii) a fluidic backplane under,
and in fluidic communication with, said fluid reservoir(s), said
fluidic backplane comprising fluid channels that terminate a ports.
In one embodiment, the fluidic backplane comprises a resistor. In
one embodiment, the perfusion manifold assembly further comprises
iii) a projecting member or skirt. In one embodiment, the skirt
comprises a guide mechanism (for engaging the microfluidic device
or a carrier containing a microfluidic device). In one embodiment,
the guide mechanism comprises a guide shaft or a hole, groove,
orifice or other cavity configured to accept a guide shaft. In one
embodiment, the guide mechanism comprises (external or internal)
guide tracks. In one embodiment, the guide tracks are side tracks
(for engaging the microfluidic device or carrier). In one
embodiment, the perfusion manifold assembly may further include a
capping layer that caps the fluidic backplane. The embodiment may
further optionally include a cover or lid. In one embodiment, the
lid is held onto the reservoir using a radial seal. This does not
require an applied pressure to create a seal. In another
embodiment, the lid is held onto the reservoir using one or more
clips, screws or other retention mechanisms. In one embodiment,
fluidic ports are at the bottom of the fluidic backplane. In one
embodiment, the projecting member or skirt is engaged with a
microfluidic chip. In one embodiment, the microfluidic chip
comprises a top channel, a bottom channel, and a membrane
separating at least a portion of said top and bottom channels. In
one embodiment, the microfluidic device comprises cells on the
membrane and/or in or on the channels.
[0012] In one embodiment, the perfusion manifold assembly comprises
i) one or more fluid reservoirs, ii) a fluidic backplane under, and
in fluidic communication with, said fluid reservoir(s), said
fluidic backplane comprising a resistor, and iii) a projecting
member or skirt (for engaging the microfluidic device or a carrier
containing a microfluidic device). The embodiment may further
include a capping layer that caps the fluidic backplane. The
embodiment may further optionally include a cover or lid. In one
embodiment, the lid is held onto the reservoir using a radial seal.
This does not require an applied pressure to create a seal. In
another embodiment, the lid is held onto the reservoir using one or
more clips, screws or other retention mechanisms. In one
embodiment, fluidic ports are at the bottom of the fluidic
backplane. In one embodiment, the projecting member or skirt is
engaged with a microfluidic chip. In one embodiment, the
microfluidic chip comprises a top channel, a bottom channel, and a
membrane separating at least a portion of said top and bottom
channels. In one embodiment, the microfluidic device comprises
cells on the membrane and/or in or on the channels.
[0013] In one embodiment, the perfusion manifold assembly comprises
i) one or more fluid reservoirs, ii) a fluidic backplane under, and
in fluidic communication with, said fluid reservoir(s), and iii) a
capping layer that caps the fluidic backplane. In one embodiment,
said fluidic backplane comprising one or more resistors. In one
embodiment, the assembly further comprises optionally iv) a
projecting member or skirt (for engaging the microfluidic device or
a carrier containing the microfluidic device). The embodiment may
further optionally include a cover or lid. In some embodiments,
attachment of a microfluidic device to the perfusion disposable is
through an engagement with the skirt. However, in other
embodiments, attachment is achieved directly with the assembly
(without the skirt or other outward extension). In one embodiment,
the projecting member or skirt is engaged with a microfluidic chip.
In one embodiment, the microfluidic chip comprises a top channel, a
bottom channel, and a membrane separating at least a portion of
said top and bottom channels. In one embodiment, the microfluidic
device comprises cells on the membrane and/or in or on the
channels.
[0014] In one embodiment, the present invention contemplates a
perfusion manifold assembly, comprising i) one or more fluid
reservoirs, ii) a fluidic backplane positioned under, and in
fluidic communication with, said fluid reservoirs, said fluidic
backplane comprising a fluid resistor and fluid channels that
terminate at ports, and iii) a projecting member or skirt having
one or more side tracks. In one embodiment, the ports are
positioned at the bottom of the fluidic backplane. In one
embodiment, said one or more side tracks are configured for
engaging a microfluidic device positioned in a microfluidic device
carrier having one or more outer edges configured to slidably
engage said one or more side tracks. In one embodiment of slidably
engaging, the linking approach to the perfusion manifold comprises
1) a sliding action, 2) a pivoting movement, and 3) a snap fit so
as to provide alignment and fluidic connection in a single action.
In the 1) sliding step, the chip (or other microfluidic device) is
in the carrier, which slides along to align the fluidic ports. In
the 2) pivot step, the carrier and chip (or other microfluidic
device) is pivoted until ports come into fluid contact. In the 3)
clip or snap fit step, the force needed to provide a secure seal is
provided. In one embodiment, the projecting member or skirt is
engaged with a microfluidic chip. In one embodiment, the
microfluidic chip comprises a top channel, a bottom channel, and a
membrane separating at least a portion of said top and bottom
channels. In one embodiment, the microfluidic device comprises
cells on the membrane and/or in or on the channels.
[0015] In one embodiment, the carrier has a cutout or "window"
(e.g. a transparent window) for imaging (e.g. with a microscope)
the cells within the microfluidic chip. In one embodiment, there is
a corresponding cutout or window (e.g. transparent) in the
perfusion disposable. In one embodiment, the microfluidic device
comprises features of the carrier to avoid the need for a separate
substrate. In one embodiment, the microfluidic device comprises a
top channel, a bottom channel, and a membrane separating at least a
portion of said top and bottom channels. In one embodiment, the
microfluidic device comprises cells on the membrane and/or in or on
the channels.
[0016] In one embodiment, the present invention contemplates a
perfusion manifold assembly, comprising i) one or more fluid
reservoirs, ii) a fluidic backplane positioned under, and in
fluidic communication with, said fluid reservoirs, said fluidic
backplane comprising a fluid resistor and fluid channels that
terminate at iii) a projecting member or skirt having one or more
fluid ports and one or more side tracks. In one embodiment, said
one or more side tracks are configured for engaging a microfluidic
device positioned in a microfluidic device carrier having one or
more outer edges configured to slidably engage said one or more
side tracks. In one embodiment of slidably engaging, the linking
approach to the perfusion manifold comprises 1) a sliding action,
2) a pivoting movement, and 3) a snap fit so as to provide
alignment and fluidic connection in a single action. In the 1)
sliding step, the chip (or other microfluidic device) is in the
carrier, which slides along to align the fluidic ports. In the 2)
pivot step, the carrier and chip (or other microfluidic device) is
pivoted until ports come into fluid contact. In the 3) clip or snap
fit step, the force needed to provide a secure seal is provided. In
one embodiment, the microfluidic device comprises features of the
carrier to avoid the need for a separate substrate. In one
embodiment, the carrier has a cutout or "window" (e.g. a
transparent window) for imaging (e.g. with a microscope). In one
embodiment, there is a corresponding cutout or window (e.g.
transparent) in the perfusion disposable (e.g. in the fluid layer).
In one embodiment, the present invention contemplates control of
the focal plane position and alignment (flatness vs. the microscope
stage) at which the chip sits. It is preferred that the required
working distance for imaging be minimized (since larger working
distances put more burden on the objective). It is not intended
that the present invention be limited by the imaging approach;
imaging can be upright (objective from above) or inverted
(objective from the bottom). While certain embodiments have a
cutout or window on only one side for certain imaging modalities
(e.g. epifluorescence), in a preferred embodiment the present
invention contemplates cutouts or windows on both sides of the chip
to enable transmitted light imaging. In one embodiment, said
resistor comprises serpentine channels. In one embodiment, said
fluidic backplane is made of Cyclo Olefin Polymer (COP) (such as
Zeonor 1420R, which is commercially available) and comprises linear
fluid channels in fluidic communication with said serpentine
channels, said linear channels terminating at one or more ports. In
one embodiment, the skirt is made from polycarbonate (PC). In one
embodiment, the assembly further comprising a cover for said fluid
reservoirs, wherein said cover comprises a plurality of ports
optionally associated with filters. In some embodiments, the cover
ports comprise through-holes and filters positioned above
corresponding holes in a gasket. In some embodiments, the cover
comprises one or more channels that route one or more of the ports
(such that the port is not a simple through-hole). In one
embodiment, said side track comprises a closed first end proximal
to said reservoirs and an opened second end distal to said
reservoirs, said opened end comprising an angled slide for engaging
said one or more outer edges of said microfluidic device carrier.
In one embodiment, said side track comprises a linear region
between said closed first end and said opened second end. In one
embodiment, the projecting member or skirt is engaged with a
microfluidic chip. In one embodiment, the microfluidic chip
comprises a top channel, a bottom channel, and a membrane
separating at least a portion of said top and bottom channels. In
one embodiment, the microfluidic device comprises cells on the
membrane and/or in or on the channels.
[0017] The present invention also contemplates systems comprising
perfusion manifold assemblies. In one embodiment, the present
invention contemplates a system, comprising: a) a perfusion
manifold assembly, comprising i) one or more fluid reservoirs, ii)
a fluidic backplane positioned under, and in fluidic communication
with, said fluid reservoirs, and iii) a skirt or other projecting
member; and b) a microfluidic device or chip engaged with the
perfusion manifold assembly through said skirt. In one embodiment,
the microfluidic device is engaged in a detachable manner. In one
embodiment, the microfluidic device is engaged in a manner that is
not detachable (e.g. a one-time connection) whether through a
locking mechanism or by using adhesives (e.g. an adhesive layer to
assist with the quality of the fluidic seal). In one embodiment,
said skirt has a guide mechanism for engaging said microfluidic
device. In one embodiment, the guide mechanism comprises a guide
shaft or a hole, groove, orifice or other cavity configured to
accept a guide shaft. In one embodiment, said guide mechanism
comprises (external or internal) guide tracks. In one embodiment,
said guide tracks are side tracks. In one embodiment, said
microfluidic device or chip is in a carrier and said carrier is
engaged with the perfusion manifold assembly through said side
tracks of said skirt. In one embodiment, the microfluidic device
has one or more features of a carrier so as to avoid the need for
an additional substrate such as a carrier. In one embodiment, the
microfluidic device comprises a top channel, a bottom channel, and
a membrane separating at least a portion of said top and bottom
channels. In one embodiment, the microfluidic device comprises
cells on the membrane and/or in or on the channels. In one
embodiment, the assembly further comprising a cover or cover
assembly for said fluid reservoirs, wherein said cover comprises a
plurality of ports optionally associated with filters. In some
embodiments, the cover ports comprise through-holes and filters
positioned above corresponding holes in a gasket. In some
embodiments, the cover comprises one or more channels that route
one or more of the ports (such that the port is not a simple
through-hole).
[0018] In one embodiment, the present invention contemplates a
system, comprising: a) a perfusion manifold assembly, comprising i)
one or more fluid reservoirs, ii) a fluidic backplane positioned
under, and in fluidic communication with, said fluid reservoirs,
said fluidic backplane comprising a fluid resistor and fluid
channels that terminate at fluid outlet ports at the bottom of said
backplane, and iii) a skirt or other projecting member having one
or more side tracks; and b) a microfluidic device positioned in a
carrier, said carrier having one or more outer edges, said outer
edges detachably engaging said one or more side tracks of said
skirt, said microfluidic device comprising i) microchannels in
fluidic communication with said perfusion manifold assembly via ii)
one or more inlet ports on a iii) mating surface, wherein said one
or more fluid inlet ports of said microfluidic device are
positioned against said one or more fluid outlet ports of said
perfusion manifold assembly under conditions such that fluid flows
from said fluid reservoirs of said perfusion manifold assembly
through said one or more fluid outlet ports into said one or more
fluid inlet ports of said microfluidic device. In one embodiment,
the carrier is engaged in a detachable manner. In one embodiment,
the carrier is engaged in a manner that is not detachable (e.g. a
one-time connection) whether through a locking mechanism or by
using adhesives (e.g. an adhesive layer to assist with the quality
of the fluidic seal). In one embodiment, the microfluidic device
comprises a top channel, a bottom channel, and a membrane
separating at least a portion of said top and bottom channels. In
one embodiment, the microfluidic device comprises cells on the
membrane and/or in or on the channels. In one embodiment, the
assembly further comprising a cover for said fluid reservoirs,
wherein said cover comprises a plurality of openings associated
with channels. In one embodiment, the assembly further comprising a
cover for said fluid reservoirs, wherein said cover comprises a
plurality of ports optionally associated with filters. In some
embodiments, the cover ports comprise through-holes and filters
positioned above corresponding holes in a gasket. In some
embodiments, the cover comprises one or more channels that route
one or more of the ports (such that the port is not a simple
through-hole).
[0019] In one embodiment, the present invention contemplates a
system, comprising: a) a perfusion manifold assembly, comprising i)
one or more fluid reservoirs, ii) a fluidic backplane positioned
under, and in fluidic communication with, said fluid reservoirs,
said fluidic backplane comprising a fluid resistor and fluid
channels that terminate at iii) a skirt having one or more fluid
outlet ports and one or more side tracks; and b) a microfluidic
device positioned in a carrier, said carrier having one or more
outer edges, said outer edges detachably engaging said one or more
side tracks of said skirt, said microfluidic device comprising i)
microchannels in fluidic communication with said perfusion manifold
assembly via ii) one or more inlet ports on a iii) mating surface,
wherein said one or more fluid inlet ports of said microfluidic
device are positioned against said one or more fluid outlet ports
of said skirt of said perfusion manifold assembly under conditions
such that fluid flows from said fluid reservoirs of said perfusion
manifold assembly through said one or more fluid outlet ports into
said one or more fluid inlet ports of said microfluidic device. In
one embodiment, the microfluidic device comprises a top channel, a
bottom channel, and a membrane separating at least a portion of
said top and bottom channels. In one embodiment, the microfluidic
device comprises cells on the membrane and/or in or on the
channels. In a preferred embodiment, said microfluidic device
comprises living cells perfused with fluid from said fluid
reservoirs. In one embodiment, the assembly further comprising a
cover for said fluid reservoirs, wherein said cover comprises a
plurality of ports optionally associated with filters. In some
embodiments, the cover ports comprise through-holes and filters
positioned above corresponding holes in a gasket. In some
embodiments, the cover comprises one or more channels that route
one or more of the ports (such that the port is not a simple
through-hole).
[0020] In a particularly preferred embodiment, said microfluidic
device or chip (whether positioned in a carrier or not) comprises
at least two different cell types that function together in a
manner that mimic one or more functions of cells in an organ in the
body. In one embodiment, the microfluidic device comprises a
membrane having top and bottom surfaces, said top surface
comprising a first cell type, said bottom surface comprises a
second cell type. In one embodiment, the microfluidic device
comprises a top channel, a bottom channel, and a membrane
separating at least a portion of said top and bottom channels. In
one embodiment, said first cell type is epithelial cells and said
second cell type is endothelial cells. In a preferred embodiment,
said membrane is porous (e.g. porous to fluid, gases, cytokines and
other molecules, and, in some embodiments, porous to cells,
permitting cells to transmigrate the membrane).
[0021] In one embodiment, the present invention contemplates a
method of seeding cells into a microfluidic chip (e.g. having ports
associated with one or more microfluidic channels), the method
comprising a) providing i) a chip at least partially contained in a
carrier, ii) cells, iii) a seeding guide and iv) a stand with
portions configured to accept at least one seeding guide in a
stable mounted position; b) engaging said seeding guide with said
carrier to create an engaged seeding guide; c) mounting said
engaged seeding guide on said stand, and d) seeding said cells into
said chip while said seeding guide is in a stable mounted position.
In one embodiment, the seeding guide is configured (e.g. with guide
tracks) to engage the edges of said carrier. In one embodiment, the
seeding guide has side tracks (similar or identical to those in the
skirt of one embodiment of the perfusion manifold assembly) to
engage the edges of said carrier. In one embodiment of this method,
a plurality of seeding guides are mounted on the stand, permitting
a plurality of chips to be seeded with cells. In one embodiment,
the microfluidic chip comprises a top channel, a bottom channel,
and a membrane separating at least a portion of said top and bottom
channels. In one embodiment, the microfluidic chip, after said
seeding, comprises cells on the membrane and/or in or on the
channels. In one embodiment, the method further comprises, after
said seeding of step d), the steps of e) disengaging said carrier
from said seeding guide and f) engaging said perfusion manifold
assembly with said carrier comprising said microfluidic chip
comprising cells.
[0022] In one embodiment, the present invention contemplates a
method of seeding cells into a microfluidic chip (e.g. having ports
associated with one or more microfluidic channels), the method
comprising a) providing i) a chip at least partially contained in a
seeding guide, ii) cells and iii) a stand with portions configured
to accept at least one seeding guide in a stable mounted position;
b) engaging said stand with said seeding guide; and c) seeding said
cells into said chip while said seeding guide is in a stable
mounted position. In one embodiment of this method, a plurality of
seeding guides is engaged with said stand, permitting a plurality
of chips to be seeded with cells. In one embodiment of this method,
there is no chip carrier. In another embodiment, the chip carrier
serves as the seeding guide (without a separate seeding guide
structure engaging the carrier).
[0023] In a preferred embodiment, said carrier further comprises a
locking mechanism for restricting movement of the carrier when said
one or more fluid inlet ports of said microfluidic device are
positioned against said one or more fluid outlet ports of said
perfusion manifold assembly. It is not intended that the present
invention be limited to the nature of the locking mechanism. In one
embodiment, the locking mechanism is selected from the group
consisting of a clip, a clamp, a stud, and a screw. In one
embodiment, the locking mechanism engages in a friction fit. The
locking mechanism can permit either detachable engagement or
engagement that is not detachable.
[0024] The present invention also contemplates methods of perfusing
cells utilizing a perfusion manifold assembly. In one embodiment,
the present invention contemplates a method of perfusing cells,
comprising: A) providing a) a perfusion manifold assembly
comprising i) one or more fluid reservoirs, ii) a fluidic backplane
positioned under, and in fluidic communication with, said fluid
reservoirs, said fluidic backplane comprising fluid channels that
terminate at outlet ports, and iii) a skirt or other projecting
member comprising a guide mechanism; and b) a microfluidic device
positioned in a carrier, said carrier configured to engage said
guide mechanism of said skirt, said microfluidic device comprising
i) living cells, and ii) microchannels in fluidic communication
with ii) one or more inlet ports on a iii) mating surface; B)
positioning said carrier such that engages of said guide mechanism
of said skirt; and C) moving said carrier until said one or more
fluid inlet ports of said microfluidic device are positioned
against said one or more fluid outlet ports of said perfusion
manifold assembly under conditions such that said microfluidic
device is linked and fluid flows from said fluid reservoirs of said
perfusion manifold assembly through said one or more fluid outlet
ports into said one or more fluid inlet ports and into said
microchannels of said microfluidic device, thereby perfusing said
cells. In one embodiment, the fluidic backplane comprises a fluid
resistor. In one embodiment, the guide mechanism comprises a guide
shaft or a hole, groove, orifice or other cavity configured to
accept a guide shaft. In one embodiment, the guide mechanism
comprises (external or internal) guide tracks. In one embodiment,
said guide tracks are side tracks. In one embodiment, said carrier
comprises one or more outer edges, said outer edges configured for
engaging said one or more side tracks of said skirt. In one
embodiment, the moving of step C) comprises sliding said carrier
along said side tracks until said inlet and outlet ports are
positioned against each other. In one embodiment, said one or more
inlet ports on said mating surface of said microfluidic device
comprise droplets protruding above said mating surface and one or
more outlet ports on said perfusion manifold comprise protruding
droplets, such that sliding of step C) causes a droplet-to-droplet
connection. In one embodiment, said carrier is engaged in a
detachable fashion. In another embodiment, said carrier is engaged
in a manner that is not detachable (e.g. one time connection). In
one embodiment, the assembly further comprising a cover or lid for
said fluid reservoirs, wherein said cover comprises a plurality of
ports optionally associated with filters. In some embodiments, the
cover ports comprise through-holes and filters positioned above
corresponding holes in a gasket. In some embodiments, the cover
comprises one or more channels that route one or more of the ports
(such that the port is not a simple through-hole).
[0025] In one embodiment, the present invention contemplates a
method of perfusing cells, comprising: A) providing a) a perfusion
manifold assembly comprising i) one or more fluid reservoirs, ii) a
fluidic backplane positioned under, and in fluidic communication
with, said fluid reservoirs, said fluidic backplane comprising a
fluid resistor and fluid channels that terminate at iii) a skirt
having one or more fluid outlet ports and one or more side tracks;
and b) a microfluidic device positioned in a carrier, said carrier
having one or more outer edges, said outer edges configured for
detachably engaging said one or more side tracks of said skirt,
said microfluidic device comprising i) living cells, and ii)
microchannels in fluidic communication with ii) one or more inlet
ports on a iii) mating surface; B) positioning said carrier such
that said one or more outer edges engage said one or more side
tracks of said skirt; and C) sliding said carrier along said side
track until said one or more fluid inlet ports of said microfluidic
device are positioned against said one or more fluid outlet ports
of said skirt of said perfusion manifold assembly under conditions
such that said microfluidic device is linked and fluid flows from
said fluid reservoirs of said perfusion manifold assembly through
said one or more fluid outlet ports into said one or more fluid
inlet ports and into said microchannels of said microfluidic
device, thereby perfusing said cells. In one embodiment, said one
or more inlet ports on said mating surface of said microfluidic
device comprise droplets protruding above said mating surface and
one or more outlet ports on said skirt comprise protruding
droplets, such that sliding of step C) causes a droplet-to-droplet
connection when one or more fluid inlet ports of said microfluidic
device are positioned against said one or more fluid outlet ports
of said skirt of said perfusion manifold assembly.
[0026] In one embodiment, said droplet-to-droplet connection does
not permit air to enter said one or more fluid inlet ports. In one
embodiment, the mating surface proximate to said droplets is
hydrophobic.
[0027] In one embodiment, the method, further comprises the step of
activating a locking mechanism for restricting movement of the
carrier. In one embodiment, the method further comprises the step
of placing said perfusion manifold assembly with said linked
microfluidic device in an incubator.
[0028] In one embodiment, the method (as described for any of the
embodiments of the perfusing method above) further comprises the
step of placing said perfusion manifold assembly with said linked
microfluidic device on, within or in contact with, a culture
module. In one embodiment, said fluid reservoirs of said perfusion
manifold assembly are covered with a cover assembly comprising a
cover having a plurality ports, and said culture module comprises a
mating surface with pressure points that correspond to the ports on
the cover, such that the step of placing of said perfusion manifold
assembly with said linked microfluidic device in or on said culture
module results in contact of said ports with said pressure points.
In one embodiment, said fluid reservoirs of said perfusion manifold
assembly are covered with a cover assembly comprising a cover
having a plurality ports, and said culture module comprises a
mating surface with pressure points that correspond to the ports on
the cover, such that after the step of placing of said perfusion
manifold assembly with said linked microfluidic device in or on
said culture module, the pressure points of the mating surface of
the culture module are brought into contact with said through-holes
of the cover assembly. In one embodiment, said fluid reservoirs of
said perfusion manifold assembly are covered with a cover assembly
comprising a cover having a plurality of through-hole ports
associated with filters and corresponding holes in a gasket, and
said culture module comprises a mating surface with pressure points
that correspond to the through-hole ports on the cover, such that
the step of placing of said perfusion manifold assembly with said
linked microfluidic device on said culture module results in
contact of said through-holes with said pressure points. In one
embodiment, the fluid reservoirs of said perfusion manifold
assembly are covered with a cover assembly comprising a cover
having a plurality of through-hole ports associated with filters
and corresponding holes in a gasket, and said culture module
comprises a mating surface with pressure points that correspond to
the through-hole ports on the cover, such that after the step of
placing of said perfusion manifold assembly with said linked
microfluidic device in or on said culture module, the pressure
points of the mating surface of the culture module are brought into
contact with said through-holes of the cover assembly.
[0029] In one embodiment, said culture module comprises volumetric
controllers. In one embodiment, said volumetric controllers apply
pressure to said fluid reservoirs via said pressure points
corresponding to said ports on said cover. In one embodiment, said
culture module comprises pressure actuators. In one embodiment,
said culture module comprises pressure controllers. In one
embodiment, said pressure controllers apply pressure to said fluid
reservoirs via said pressure points (e.g. on a pressure manifold)
corresponding to said ports (e.g. through-hole ports) on said
cover. In one embodiment, said culture module comprises a plurality
of perfusion manifold assemblies. In one embodiment, said culture
module comprises integrated valves. In one embodiment, said
integrated valves are in a pressure manifold. In one embodiment,
said valves comprise Schrader valves.
[0030] The present invention also contemplates the culture module
as a device. In one embodiment, the device comprises an actuation
assembly configured to move a plurality of microfluidic devices
(such as the perfusion manifold assemblies described herein)
against a pressure manifold, said pressure manifold comprising
integrated valves. In one embodiment, it is configured to move the
microfluidic devices up against a non-moving pressure manifold. In
one embodiment, the device comprises an actuation assembly
configured to move one or more perfusion manifold assemblies into
contact with a pressure manifold. In one embodiment, the device
comprises an actuation assembly configured to move a pressure
manifold (up or down) into contact with the plurality of perfusion
manifold assemblies. In some embodiments, said pressure manifold
comprises integrated valves and elastomeric membranes. In some
embodiments, the elastic/pliable seal is disposed on the pod or lid
and not on the pressure manifold. In either embodiment, the present
invention is not intended to be limited to a membrane, since a
membrane is only one specific way to do this; in other embodiments,
o-rings, gaskets (thicker than a membrane), pliable materials, or
vacuum grease are used instead. In one embodiment, the said valves
comprise Schrader valves. In some embodiments, the pressure
manifold is adapted to sense the presence of a coupled perfusion
manifold assembly or microfluidic device, for example, in order to
reduce the leakage of pressure or fluid in the absence of a coupled
device. Importantly, the pressure manifold, in a preferred
embodiment, takes the few pressure sources and disperses them to
every perfusion manifold assembly. In some embodiments, the
pressure manifold is also designed to directly align with the
perfusion manifold assemblies (e.g. via alignment features in the
pressure manifold mating surface). In one embodiment, the perfusion
manifold assemblies slide into alignment features on the bottom of
the pressure manifold that make sure the seals in the pressure
manifold are always aligned with the ports on the perfusion
manifold assemblies. In some embodiments, the pressure manifold has
a set of springs that push down on the perfusion manifold
assemblies when the pressure manifold is actuated. These springs
force the lid up against the reservoir of the perfusion manifold
assembly to create the seal that holds pressure (and avoids leaks)
within the perfusion manifold assembly when pressure is passed
through the lid ports.
[0031] The present invention also contemplates the culture module
and the perfusion disposables (PDs) as a system. In one embodiment,
the system comprises a device comprising an actuation assembly
configured to move a plurality of microfluidic devices (such as the
perfusion manifold assemblies described herein) against a pressure
manifold, said pressure manifold comprising integrated valves. In
one embodiment, it is configured to move the microfluidic devices
up against a non-moving pressure manifold. In one embodiment, the
system comprises a) device, comprising an actuation assembly
configured to move b) a plurality of microfluidic devices (such as
the perfusion disposables) into contact with a pressure manifold.
In one embodiment, the system comprises a) device, comprising an
actuation assembly configured to move a pressure manifold, said
pressure manifold comprising integrated valves and seals (e.g.
elastomeric membranes), said seals (e.g. elastomeric membranes) in
contact with b) a plurality of microfluidic devices. In one
embodiment, said microfluidic devices are perfusion disposables. In
some embodiments, the elastic/pliable seal is disposed on the pod
or lid and not on the pressure manifold. In either embodiment, the
present invention is not intended to be limited to a membrane,
since a membrane is only one specific way to do this; in other
embodiments, o-rings, gaskets (thicker than a membrane), pliable
materials, or vacuum grease are used instead. In one embodiment,
said valves comprise Schrader valves. In one embodiment, the
manifold uses a bi-stable engagement mechanism so that the actuator
does not need to be always on to provide engagement and continuous
pressure to the lid. In a bi-stable mechanism, the actuator engages
the manifold and then can be turned off This is useful in
situations where the actuator might generate excessive heat while
powered for long periods of time. In one embodiment, the perfusion
disposable is engaged with a microfluidic chip. In one embodiment,
the microfluidic chip comprises a top channel, a bottom channel,
and a membrane separating at least a portion of said top and bottom
channels. In one embodiment, the microfluidic device comprises
cells on the membrane and/or in or on the channels.
[0032] The present invention also contemplates drop-to-drop
connection schemes for putting a microfluidic device in fluidic
communication with a fluid source or another device, including but
not limited to, putting a microfluidic device in fluidic
communication with the perfusion manifold assembly. In one
embodiment, the present invention contemplates a fluidic device
comprising a substrate having a first surface, said first surface
comprising one or more fluidic ports, wherein said first surface is
adapted to stably retain one or more liquid droplets comprising a
first liquid at the one or more fluidic ports. In one embodiment,
said first surface comprises one or more regions surrounding the
one or more fluidic ports, and wherein said regions are adapted to
resist wetting by said first liquid. In one embodiment, said
regions are adapted to be hydrophobic. In one embodiment, said one
or more regions comprise a first material selected to resist
wetting by said first liquid. It is not intended that the present
invention be limited by any particular first material. However, in
one embodiment, the first material is selected from the group
consisting of poly-tetrafluoroethylene (PTFE), a perfluoroalkoxy
alkane (PFA), fluorinated ethylenepropylene (FEP),
polydimethylsiloxane (PDMS), nylon (some grades are hydrophilic and
some are hydrophobic), polypropylene, polystyrene and polyimide. In
one embodiment, the substrate comprises said first material. In one
embodiment, said first material is bonded, adhered, coated or
sputtered onto said first surface. In one embodiment, said first
material comprises a hydrophobic gasket. In one embodiment, the one
or more regions are adapted to resist wetting by said first liquid
by means of plasma treatment, ion treatment, gas-phase deposition,
liquid-phase deposition, adsorption, absorption or chemical
reaction with one or more agents.
[0033] In one embodiment, said first surface comprises one or more
regions surrounding the one or more fluidic ports, and wherein said
regions are adapted to promote wetting by said first liquid. In one
embodiment, said regions are adapted to be hydrophilic In one
embodiment, said one or more regions comprise a first material
selected to promote wetting by said first liquid. Again, it is not
intended that the present invention be limited to any particular
first material. However, in one embodiment, the first material is
selected from the group consisting of polymethylmethacrylate
(PMMA), polyvinyl alcohol (PVOH), polycarbonate (PC), polyether
ether ketone (PEEK), polyethylene terephthalate (PET), polyfulfone,
polystyrene, polyvinyl acetate (PVA), nylon, polyvinyl fluoride
(PVF), polyvinylidiene chloride (PVDC), polyvinyl chloride (PVC)
and acrylonitrile-butadiene-styrene (ABS). In one embodiment, the
substrate comprises said first material. In one embodiment, said
first material is bonded, adhered, coated or sputtered onto said
first surface. In one embodiment, said first material comprises a
hydrophilic gasket. In one embodiment, the one or more regions are
adapted to promote wetting by said first liquid by means of plasma
treatment, ion treatment, gas-phase deposition, liquid-phase
deposition, adsorption, absorption or chemical reaction with one or
more agents.
[0034] In one embodiment, the first surface comprises one or more
ridges surrounding the one or more fluidic ports. In one
embodiment, the first surface comprises one or more recesses
surrounding the one or more fluidic ports. In one embodiment, said
first surface is adapted to stably retain one or more aqueous
liquid droplets. In one embodiment, said first surface is adapted
to stably retain one or more non-aqueous liquid droplets. In one
embodiment, said first surface is adapted to stably retain one or
more oil droplets.
[0035] The present invention also contemplates systems comprising
devices that retain droplets. In one embodiment, the system
comprises: a) a first substrate comprising a first surface, said
first surface comprising a first set of one or more fluidic ports,
wherein said first surface is adapted to stably retain one or more
liquid droplets comprising a first liquid at the first set of
fluidic ports, b) a second substrate comprising a second surface,
said second surface comprising a second set of one or more fluidic
ports, and c) a mechanism for fluidically contacting (and
connecting) the first set of fluidic ports to the second set of
fluidic ports.
[0036] The present invention also contemplates methods of retaining
droplets so that they can be combined to establish a fluidic
connection. In one embodiment, a method for establishing a fluidic
connection is contemplated, comprising: a) providing a first
substrate comprising a first surface, said first surface comprising
a first set of one or more fluidic ports, wherein said first
surface is adapted to stably retain one or more liquid droplets
comprising a first liquid at the first set of fluidic ports, b)
providing a second substrate comprising a second surface, said
second surface comprising a second set of one or more fluidic
ports, and c) contacting the first set of fluidic ports and the
second set of fluidic ports (e.g. via a controlled engagement). In
a preferred embodiment, the contacting of step c) comprises
aligning the first set of fluidic ports and the second set of
fluidic ports and bringing the aligned sets of ports into
contact.
[0037] In one embodiment, the present invention contemplates
systems and methods where a microfluidic device is brought into
contact with a fluid source in a drop-to-drop connection. In one
embodiment, the present invention contemplates a method,
comprising: a) providing i) a fluid source in fluidic communication
with a first fluid port positioned on a first mating surface, said
first fluid port comprising a first protruding fluid droplet; ii) a
microfluidic device comprising a microchannel in fluidic
communication with an second fluid port on a second mating surface,
said second fluid port comprising a second protruding fluid
droplet; and b) bringing said first protruding fluid droplet and
said second fluid droplet together in a droplet-to-droplet
connection, so that fluid can flow from said fluid source through
said first fluid port into said second fluid port of said
microfluidic device. In one embodiment, the present invention
contemplates a system, comprising: a) a fluid source in fluidic
communication with a first fluid port positioned on a first mating
surface, said first fluid port adapted to support a first
protruding fluid droplet; b) a microfluidic device comprising a
microchannel in fluidic communication with an second fluid port on
a second mating surface, said second fluid port adapted to support
a second protruding fluid droplet; and c) a mechanism for bringing
said first protruding fluid droplet and said second fluid droplet
together in a droplet-to-droplet connection, so that fluid can flow
from said fluid source through said first fluid port into said
second fluid port of said microfluidic device. In one embodiment,
the first protruding fluid droplet protrudes downward from said
first mating surface and said second protruding fluid droplet
protrudes upward from said second mating surface. In one
embodiment, the first protruding fluid droplet protrudes upward
from said first mating surface and said second protruding fluid
droplet protrudes downward from said second mating surface. In one
embodiment, said mechanism lifts the second mating surface upward
into contact with said first mating surface. In another embodiment,
said mechanism lifts the first mating surface upward into contact
with said second mating surface. In still another embodiment, said
mechanism lowers the second mating surface into contact with said
first mating surface. In yet another embodiment, said mechanism
lowers the first mating surface into contact with said second
mating surface.
[0038] In one embodiment, the present invention contemplates that
droplets are controlled by surface treatments. In one embodiment of
the system, said first mating surface comprises a region
surrounding said first fluid port, and wherein said region is
adapted to resist wetting by said fluid. In one embodiment said
region is adapted to be hydrophobic. In one embodiment, said region
comprises a first material selected to resist wetting by said
fluid. It is not intended that the present invention be limited by
the nature of the first material. However, in one embodiment, the
first material is selected from the group consisting of
poly-tetrafluoroethylene (PTFE), a perfluoroalkoxy alkane (PFA),
fluorinated ethylenepropylene (FEP), polydimethylsiloxane (PDMS),
nylon (some grades are hydrophobic), polypropylene, polystyrene and
polyimide. It is not intended that the present invention be limited
by the nature by which the first material is attached to the
surface. However, in one embodiment, said first material is bonded,
adhered, coated or sputtered onto said first mating surface. The
present invention also contemplates adding features with intrinsic
hydrophobic surfaces, or surfaces that can be made hydrophobic. In
one embodiment, said first material comprises a hydrophobic gasket.
It is not intended that the present invention be limited by the
particular treatment regime use to modify surfaces, or regions of
surfaces. However, in one embodiment, said region of said first
mating surface is adapted to resist wetting by means of plasma
treatment, ion treatment, gas-phase deposition, liquid-phase
deposition, adsorption, absorption or chemical reaction with one or
more agents.
[0039] While an embodiment has been discussed above for adapting
surfaces or regions of surfaces to resist wetting, the present
invention contemplates embodiments wherein said first mating
surface comprises a region surrounding said first fluid port, and
wherein said region is adapted to promote wetting by said fluid. In
one embodiment, said region is adapted to be hydrophilic. In one
embodiment, said region comprises a first material selected to
promote wetting by said first liquid. It is not intended that the
present invention be limited to particular first materials for
promoting wetting. However, in one embodiment, the first material
is selected from the group consisting of polymethylmethacrylate
(PMMA), polyvinyl alcohol (PVOH), polycarbonate (PC), polyether
ether ketone (PEEK), polyethylene terephthalate (PET), polyfulfone,
polystyrene, polyvinyl acetate (PVA), nylon (certain grades are
hydrophilic), polyvinyl fluoride (PVF), polyvinylidiene chloride
(PVDC), polyvinyl chloride (PVC) and
acrylonitrile-butadiene-styrene (ABS). It is also not intended that
the present invention be limited by the technique for attaching the
first material to the surface. However, in one embodiment, said
first material is bonded, adhered, coated or sputtered onto said
first mating surface. The present invention also contemplates
introducing structures or features with intrinsic hydrophilic
surfaces, or surfaces that can be made hydrophilic. For example, in
one embodiment, said first material comprises a hydrophilic gasket.
It is also not intended that the present invention be limited to
the treatment regime for promoting wetting. For example, in one
embodiment, said region of said first mating surface is adapted to
promote wetting by means of plasma treatment, ion treatment,
gas-phase deposition, liquid-phase deposition, adsorption,
absorption or chemical reaction with one or more agents.
[0040] The present invention also contemplates structures and
geometrical features that can be molded or formed as part of the
surface, attached to, deposited on, printed on or bonded to the
sources, or machined into, etched into or ablated into the surface.
For example, in one embodiment, the first mating surface comprises
one or more ridges surrounding said first fluid ports. In another
embodiment, the first mating surface comprises one or more recesses
surrounding said first fluid port.
[0041] The present invention is also not limited to drop-to-drop
connections with only aqueous fluids. While in one embodiment, said
first mating surface is adapted to stably retain an aqueous
protruding fluid droplet, in another embodiment, said first mating
surface is adapted to stably retain a non-aqueous protruding fluid
droplet, including but not limited to an oil protruding
droplet.
[0042] The present invention also contemplates method for merging
droplets using a drop-to-drop scheme. In one embodiment, the
present invention contemplates a method of merging droplets,
comprising: a) providing i) a fluid source in fluidic communication
with a first fluid port positioned on a first mating surface, said
first fluid port comprising a first protruding fluid droplet; and
ii) a microfluidic device or chip comprising a microchannel in
fluidic communication with a second fluid port on a second mating
surface, said second fluid port comprising a second protruding
fluid droplet; and b) bringing said first protruding fluid droplet
and said second fluid droplet together in a droplet-to-droplet
connection, whereby the first and second fluid droplets merge so
that fluid flows from said fluid source through said first fluid
port into said second fluid port of said microfluidic device. In
one embodiment, the microfluidic chip comprises a top channel, a
bottom channel, and a membrane separating at least a portion of
said top and bottom channels. In one embodiment, the microfluidic
device comprises cells on the membrane and/or in or on the
channels. It is not intended that the present invention be limited
to particular orientations or the two mating surfaces. In one
embodiment, the first protruding fluid droplet protrudes downward
from said first mating surface and said second protruding fluid
droplet protrudes upward from said second mating surface. In
another embodiment, the first protruding fluid droplet protrudes
upward from said first mating surface and said second protruding
fluid droplet protrudes downward from said second mating surface.
It is also not intended that the present invention be limited by
how the droplets are brought together. In one embodiment, step b)
comprises lifting the second mating surface upward into contact
with said first mating surface. In another embodiment, step b)
comprises lifting the first mating surface upward into contact with
said second mating surface. In yet another embodiment, step b)
comprising lowering the second mating surface into contact with
said first mating surface. In still another embodiment, step b)
comprises lowering the first mating surface into contact with said
second mating surface. In a preferred embodiment, said
droplet-to-droplet connection does not permit air to enter said
fluid inlet port.
[0043] The present invention contemplates surface treatments to
promote wetting. In one embodiment, said first mating surface
comprises a region surrounding said first fluid port, wherein said
region is adapted to promote wetting by said fluid. In one
embodiment, said region is adapted to be hydrophilic. In one
embodiment, said region comprises a first material selected to
promote wetting by said fluid. While not intended to limit the
invention to any particular first material, in one embodiment, the
first material is selected from the group consisting of
polymethylmethacrylate (PMMA), polyvinyl alcohol (PVOH),
polycarbonate (PC), polyether ether ketone (PEEK), polyethylene
terephthalate (PET), polyfulfone, polystyrene, polyvinyl acetate
(PVA), nylon, polyvinyl fluoride (PVF), polyvinylidiene chloride
(PVDC), polyvinyl chloride (PVC) and
acrylonitrile-butadiene-styrene (ABS). While not intending to limit
the invention to any particular attachment approach, in one
embodiment, said first material is bonded, adhered, coated or
sputtered onto said first mating surface.
[0044] In some embodiments, the present invention contemplates
adding features or structures to a surface, including structures
with intrinsically hydrophilic surfaces (or surfaces that can be
made hydrophilic). In one embodiment, said first material comprises
a hydrophilic gasket.
[0045] It is not intended that the present invention be limited to
any particular surface treatment technique. However, in one
embodiment, said region of said first mating surface is adapted to
promote wetting by means of plasma treatment, ion treatment,
gas-phase deposition, liquid-phase deposition, adsorption,
absorption or chemical reaction with one or more agents.
[0046] Additional structures can be molded or otherwise formed into
or on to the surfaces. For example, in one embodiment, the first
mating surface comprises one or more ridges surrounding said first
fluid port. In another embodiment, the first mating surface
comprises one or more recesses surrounding said first fluid
port.
[0047] As noted above, the fluid need not be an aqueous fluid.
While in one embodiment, the present invention contemplates said
first mating surface is adapted to stably retain an aqueous
protruding fluid droplet, in another embodiment, said first mating
surface is adapted to stably retain a non-aqueous protruding fluid
droplet, including but not limited to retaining an oil protruding
droplet.
[0048] The present invention also contemplates systems for linking
ports together. In one embodiment, the system comprises: a) a first
substrate comprising a first fluidic port, b) a second substrate
comprising a second fluidic port, c) a guide mechanism adapted to
align the first port and the second port, and (optionally) d) a
retention mechanism adapted to retain the first substrate in
contact with the second substrate. While not intending to limiting
the invention to any particular guide mechanism, in one embodiment,
the guide mechanism is a guide track positioned on said first
substrate, said guide track configured to engage a portion of said
second substrate. While the present invention contemplates
embodiments wherein the retention mechanism is on the first or
second substrate, in one embodiment, the retention mechanism is a
clip positioned on said second substrate, said clip configured to
engage said first substrate.
[0049] In another embodiment, the present invention contemplates a
system comprising: a) a first substrate comprising a first set of
one or more fluidic ports, b) a second substrate comprising a
second set of one or more fluidic ports, c) a guide mechanism
adapted to align the first set of ports and the second set of
ports, and d) a retention mechanism adapted to retain the first
substrate in contact with the second substrate. Again, a variety of
guide mechanisms are contemplated (and discussed herein). In one
embodiment, the guide mechanism comprises a guide shaft or a hole,
groove, orifice or other cavity configured to accept a guide shaft.
However, in one embodiment, the guide mechanism is a guide track
positioned on said first substrate, said guide track configured to
engage a portion of said second substrate. Again, a variety of
retention mechanisms are contemplated (and described herein).
However, in one embodiment, the retention mechanism is a clip
positioned on said second substrate, said clip configured to engage
said first substrate.
[0050] The present invention also contemplates methods for linking
ports in a manner such that a fluidic connection is established. In
one embodiment, the present invention contemplates a method for
establishing a fluidic connection, comprising: a) providing a first
substrate comprising a first fluidic port, a second substrate
comprising a second fluidic port, and a guide mechanism adapted to
guide the second substrate, b) engaging the second substrate with
the guide mechanism, c) aligning the first and second sets of
fluidic ports by help of the guide mechanism, and d) contacting the
first and second fluidic ports to establish a fluidic connection.
While a variety of guide mechanisms are contemplated, in one
embodiment, said guide mechanism comprises a guide track positioned
on said first substrate, said guide track configured to engage a
portion of said second substrate. In one embodiment of this method
for establishing a fluidic connection, said second substrate
comprises a microfluidic device comprising a mating surface,
wherein said second fluidic port is positioned on said mating
surface and comprises a droplet protruding above said mating
surface. In a further embodiment, said first substrate comprises a
mating surface, wherein said first fluidic port is positioned on
said mating surface and comprises a protruding droplet. Still
further in this embodiment, said contacting of step d) causes a
droplet-to-droplet connection when said first and second fluidic
ports to establish a fluidic connection. It is preferred that said
droplet-to-droplet connection does not permit air to enter said one
or more fluid inlet ports. While the present invention is not
limited to the manner of aligning, in one embodiment, said aligning
of step c) comprises sliding the second substrate by means of the
guide track. While a variety of designs and conformations for the
guide track are contemplated, in one embodiment, said guide track
comprises first and second sections, said first section shaped to
support the aligning of step c), said second section shaped to
support the contacting of step d).
[0051] While the present invention contemplates embodiments where
the retention mechanism is on the first substrate, in one
embodiment, said second substrate comprises a retention mechanism
adapted to retain the first substrate in contact with the second
substrate. In some embodiments, the retention mechanism
automatically engages when the first and second substrates make
contact and establish a fluidic connection. However, in one
embodiment, the present invention contemplates the active step of
e) activating the retention mechanism.
[0052] While two substrate systems have been described above, the
present invention also contemplates three substrate systems. In one
embodiment, the system comprises: a) a first substrate comprising a
first fluidic port, b) a second substrate comprising a second
fluidic port, c) a third substrate configured to support said
second substrate; d) a guide mechanism adapted to align the first
port with second port, and e) a retention mechanism means adapted
to retain the first substrate in contact with the second
substrate.
[0053] As noted previously, a variety of guide mechanisms are
contemplated (and described herein). In one embodiment, the guide
mechanism comprises a guide shaft or a hole, groove, orifice or
other cavity configured to accept a guide shaft. One or more guide
shafts or other projections can be on one substrate, with one or
more holes, grooves, orifices or other cavities on the other
substrate configured to accept the one or more guide shafts or
other projections. In one embodiment, the guide mechanism comprises
a guide track. The guide track(s) can be in any orientation (e.g.
coming from above rather than from either side). While the present
invention contemplates that the guide mechanism might be attached
to the first, second or third substrate, in one embodiment, the
guide track is positioned on said first substrate. While the
present invention contemplates embodiments wherein either the
second or third substrates are have features or structures
configured to engage the guide mechanism, in one embodiment, the
present invention contemplates that the third substrate comprises
edges configured to engage said guide track. In one embodiment, the
second substrate comprises edges configured to engage said guide
track. While the present invention contemplates embodiments wherein
the retention mechanism is positioned on the first or second
substrates, in one embodiment, said retention mechanism is
positioned on said third substrate. As noted previously, a variety
of retention mechanisms are contemplated. In one embodiment, said
retention mechanism comprises a clip configured to engage said
first substrate. In another embodiment, said retention mechanism
comprises a clamp configured to engage said first substrate under
conditions such that contact between said first and second
substrates is maintained. In yet another embodiment, said retention
mechanism comprises a stud configured to engage a hole on said
first substrate. In still another embodiment, said retention
mechanism engages a portion of said first substrate in a friction
fit. In one embodiment, said retention mechanism is selected from
the group consisting of an adhesive (including a laminate), a heat
stake, and a screw.
[0054] While the present invention contemplates systems wherein the
components of the systems are described (see above), the present
invention also contemplates assemblies, where the components are
arranged, attached or connected in certain ways. In one embodiment,
the present invention contemplates an assembly, comprising: a) a
first substrate comprising a first fluidic port and a guide
mechanism, said first substrate positioned against and in contact
with b) a second substrate comprising a second fluidic port,
wherein said first and second ports are aligned so as to permit
fluidic communication, said second substrate supported by c) a
carrier, said carrier comprising a portion engaging said guide
mechanism of said first substrate. While the present invention
contemplates embodiments, where a retention mechanism is positioned
on said first or second substrate, in one embodiment, said carrier
further comprises a retention mechanism for retaining said contact
between said first and second substrates. While a variety of guide
mechanisms are contemplated (and described herein), in one
embodiment, the guide mechanism comprises a guide track. The
present invention is not limited to a single guide track; two or
more guide tracks may be employed. For example, in one embodiment
the guide track is positioned on one or more sides of said first
substrate. In one embodiment, the carrier portion engaging said
first substrate comprises one or more edges configured to engage
said guide track.
[0055] While a variety of retention mechanisms are contemplated
(and described herein) in one embodiment of the assembly, said
retention mechanism comprises a clip configured to engage said
first substrate. In another embodiment, said retention mechanism
comprises a clamp configured to engage said first substrate. In yet
another embodiment, said retention mechanism comprises a stud
configured to engage a hole on said first substrate. In a
particular embodiment, said retention mechanism engages a portion
of said first substrate in a friction fit. In one embodiment, said
retention mechanism is selected from the group consisting of an
adhesive (including but not limited to a laminate), a heat stake,
and a screw.
[0056] The present invention also contemplates methods for
establishing a fluidic connection by bringing fluidic ports
together where three substrates are involved. In one embodiment,
the present invention contemplates a method for establishing a
fluidic connection, comprising: a) providing: a first substrate
comprising a first fluidic port, a second substrate comprising a
second fluidic port, a third substrate configured to support said
second substrate, and a guide mechanism; b) aligning said first and
second ports with said guide mechanism; and c) contacting said
first port with said second port under conditions such that a
fluidic connection is established between said first and second
substrate. In one embodiment of this three substrate method, said
second substrate comprises a microfluidic device comprising a
mating surface, wherein said second fluidic port is positioned on
said mating surface and comprises a droplet protruding above said
mating surface. Further in this embodiment, said first substrate
comprises a mating surface, wherein said first fluidic port is
positioned on said mating surface and comprises a protruding
droplet. Still further in this embodiment, said contacting of step
c) causes a droplet-to-droplet connection when said first and
second fluidic ports to establish a fluidic connection. It is
preferred that said droplet-to-droplet connection does not permit
air to enter said one or more fluid inlet ports.
[0057] Again, a variety of guide mechanisms are contemplated and
described herein. In one embodiment, the guide mechanism comprises
a guide track. While the present invention contemplates positioning
the guide track on said first, second or third substrates, in a
preferred embodiment, the guide track is positioned on said first
substrate. In one embodiment, the third substrate comprises edges
configured to engage said guide track. While not intending that the
invention be limited to the particular technique for aligning, in
one embodiment, the present invention contemplates said aligning of
step b) comprises sliding said third substrate by means of said
guide track. In one embodiment, said guide track comprises first
and second sections, said first section shaped to support the
aligning of step b), said second section shaped to support the
contacting of step c). In one embodiment, said first section is
linear and said second section is curved. In yet another
embodiment, said guide mechanism comprises a mechanism on which
said third substrate rotates or pivots during step d). For example,
in one embodiment, said guide mechanism comprises a hinge, joint,
or pivot point.
[0058] While the present invention contemplates embodiments where
the retention mechanism is positioned on the first or second
substrates, in one embodiment, the present invention contemplates
that said third substrate further comprises a retention mechanism
for retaining alignment of said first and second ports. Again, a
variety of retention mechanisms are contemplated. In one
embodiment, said retention mechanism comprises a clip configured to
engage said first substrate. In one embodiment, said retention
mechanism comprises a clamp configured to engage said first
substrate under conditions such that contact between said first and
second substrates is maintained. In yet another embodiment, said
retention mechanism comprises a stud configured to engage a hole on
said first substrate. In still another embodiment, said retention
mechanism engages a portion of said first substrate in a friction
fit. In one embodiment, said retention mechanism is selected from
the group consisting of an adhesive (including but not limited to a
laminate), a heat stake, and a screw. The present invention also
contemplates embodiments wherein the third substrate is a carrier
for the second substrate.
[0059] In one embodiment, the present invention contemplates a
method for establishing a fluidic connection, comprising: a)
providing: a first substrate comprising a guide mechanism and a
first fluidic port on a first mating surface, a second substrate
comprising a second fluidic port on a second mating surface and a
bottom surface, and a carrier in contact with said bottom surface
of said second substrate, said carrier comprising a retention
mechanism and one or more edges for engaging said guide mechanism;
b) engaging said guide mechanism of said first substrate with one
or more edges of said carrier; c) aligning said first and second
ports with said guide mechanism; d) contacting said first mating
surface with said second mating surface under conditions such that
said first port contacts said second port and a fluidic connection
is established between said first and second substrate. In one
embodiment of this method, said second fluidic port comprises a
droplet protruding above said mating surface of said second
substrate. In one embodiment, said first fluidic port comprises a
protruding droplet. In one embodiment, said contacting of step d)
causes a droplet-to-droplet connection when said first and second
fluidic ports to establish a fluidic connection. It is preferred
that said droplet-to-droplet connection does not permit air to
enter said one or more fluid inlet ports. While a variety of guide
mechanisms are contemplated, in one embodiment, the guide mechanism
comprises a guide track. The present invention is not limited to
embodiments where there is only one guide track; two or more guide
tracks may be used. In one embodiment, the guide track is
positioned on one or more sides of said first substrate. In a
preferred embodiment, the carrier comprises one or more edges
configured to engage said guide track. While a variety of aligning
approaches are contemplated, in one embodiment, said aligning of
step c) comprises sliding said carrier by means of said guide
track. While a variety of designs and configurations for the guide
track are contemplated, in one embodiment, said guide track
comprises first and second sections, said first section shaped to
support the aligning of step c), said second section shaped to
support the contacting of step d). In one embodiment, said first
section is linear and said second section is curved. In yet another
embodiment, said guide mechanism comprises a mechanism on which
said carrier rotates or pivots during step d). In this embodiment,
said guide mechanism may comprise a hinge, a joint, a socket or
other pivot point.
[0060] In some embodiments, the retention mechanism automatically
engages when or after contact is made in step d). However, in one
embodiment, the present invention contemplates the active step of
e) activating said retention mechanism under condition such that
said alignment of said first and second ports is retained. Again, a
variety of retention mechanisms are contemplated. In one
embodiment, said retention mechanism comprises a clip configured to
engage said first substrate. In one embodiment, said retention
mechanism comprises a clamp configured to engage said first
substrate under conditions such that contact between said first and
second substrates is maintained. In one embodiment, said retention
mechanism comprises a stud configured to engage a hole on said
first substrate. In one embodiment, said retention mechanism
engages a portion of said first substrate in a friction fit. In one
embodiment, said retention mechanism is selected from the group
consisting of an adhesive (including but not limited to a laminate,
a heat stake, and a screw).
[0061] The present invention also contemplates devices for
perfusing cells, including devices that apply pressure to fluid
reservoirs to create a flow of fluid (e.g. culture media). The
present invention contemplates, in one embodiment, a device,
comprising an actuation assembly configured to move a pressure
manifold, said pressure manifold comprising integrated valves. In
one embodiment, said device further comprises elastomeric
membranes. In one embodiment, said valves comprise Schrader valves.
In one embodiment, said pressure manifold comprises a mating
surface with pressure points. In one embodiment, the device further
comprises pressure controllers. In one embodiment, said pressure
controllers are configured to apply pressure via said pressure
points. In one embodiment, said actuation assembly comprises
pneumatic cylinder operably linked to said pressure manifold. In
one embodiment, said mating surface further comprises alignment
features configured to align a microfluidic device or chip when
said microfluidic device or chip engages said mating surface. In
one embodiment, said device is a culture module for perfusing
cells. In one embodiment, the microfluidic chip is engaged with a
perfusion manifold assembly (and the alignment features are
configured to align the perfusion manifold assembly). In one
embodiment, the microfluidic chip comprises a top channel, a bottom
channel, and a membrane separating at least a portion of said top
and bottom channels. In one embodiment, the microfluidic device
comprises cells on the membrane and/or in or on the channels.
[0062] The present invention also contemplates systems where a
device for delivering pressure is linked to a plurality of
microfluidic devices, and more preferably, the plurality of
microfluidic devices (such as the various embodiments of the
perfusion disposables discussed herein) are simultaneously linked
(although they can be linked individually or sequentially, if
desired). In one embodiment, the present invention contemplates a
system, comprising a) device comprising an actuation assembly
configured to move a pressure manifold, said pressure manifold
comprising integrated valves, said pressure manifold in contact
with b) a plurality of microfluidic devices (such as the various
embodiments of the perfusion disposables discussed herein). In one
embodiment, said pressure manifold further comprises elastomeric
membranes, and said elastomeric membranes are in contact with said
microfluidic devices. In one embodiment, said microfluidic devices
are perfusion disposables. In one embodiment, said valves comprise
Schrader valves. In one embodiment, each of said microfluidic
devices is covered with a cover assembly comprising a cover having
a plurality of ports, and said pressure manifold comprising a
mating surface with pressure points that correspond to the ports on
the cover, wherein the pressure points of the mating surface of the
pressure manifold are in contact with said ports of the cover
assembly. In one embodiment, said ports comprise through-hole ports
associated with filters and corresponding holes in a gasket. In one
embodiment, the device further comprises pressure controllers. In
one embodiment, said pressure controllers are configured to apply
pressure via said pressure points. In one embodiment, said
actuation assembly comprises pneumatic cylinder operably linked to
said pressure manifold. In one embodiment, said mating surface of
the pressure manifold further comprises alignment features
configured to align a microfluidic device when said microfluidic
device engages said mating surface. In a preferred embodiment, said
device is a culture module for perfusing cells. In one embodiment
of such a culture module, the culture module is configured to
accept one or more trays, each tray comprising a plurality of
microfluidic devices. In one embodiment, the culture module further
comprises a user interface to control said culture module. In one
embodiment, each tray comprising a plurality of perfusion manifold
assemblies. In one embodiment, a microfluidic chip is engaged with
each perfusion manifold assembly (and the alignment features of the
pressure manifold mating surface are configured to align each
perfusion manifold assembly). In one embodiment, the microfluidic
chip comprises a top channel, a bottom channel, and a membrane
separating at least a portion of said top and bottom channels. In
one embodiment, the microfluidic device comprises cells on the
membrane and/or in or on the channels.
[0063] The present invention also contemplates methods for
perfusing cells (e.g. cells in microchannels of a microfluidic
device, such as the various embodiments of the perfusion disposable
discussed herein, where cells were first seeded into said
microfluidic device, with or without a seeding guide of the type
described herein) with a culture module. In one embodiment, the
present invention contemplates a method of perfusing cells,
comprising: A) providing a) a culture module, said culture module
comprising i) an actuation assembly configured to move a plurality
of microfluidic devices against ii) a pressure manifold, said
pressure manifold comprising a mating surface with pressure points;
and b) a plurality of microfluidic devices, each of said
microfluidic devices comprising i) one or more microchannels
comprising living cells, ii) one or more reservoirs comprising
culture media, and iii) a cover assembly above said one or more
reservoirs, said cover assembly comprising a cover with ports that
correspond to the pressure points on the pressure manifold mating
surface; B) placing said plurality of microfluidic devices on or in
said culture module; and C) simultaneously (or sequentially)
contacting said ports on the cover of each microfluidic device of
said plurality of microfluidic devices with said mating surface of
said pressure manifold, such that the ports are in contact with
said pressure points, under conditions such that culture media
flows from said reservoirs into said microchannels of said
microfluidic devices, thereby perfusing said cells. In one
embodiment, said plurality of microfluidic devices are positioned
on one or more trays prior to step B) and said placing of step B)
comprising moving at least a subset of said plurality of
microfluidic devices simultaneously into said culture module. In
one embodiment, said simultaneous contacting of step C) is achieved
by moving, via the actuation assembly, the plurality of
microfluidic devices up against the mating surface of the pressure
manifold. In another embodiment, the present invention contemplates
a method of perfusing cells, comprising: A) providing a) a culture
module, said culture module comprising i) an actuation assembly
configured to move ii) a pressure manifold, said pressure manifold
comprising a mating surface with pressure points; and b) a
plurality of microfluidic devices, each of said microfluidic
devices comprising i) one or more microchannels comprising living
(viable) cells, ii) one or more reservoirs comprising culture
media, and iii) a cover assembly above said one or more reservoirs,
said cover assembly comprising a cover with ports that correspond
to the pressure points on the pressure manifold mating surface; B)
placing said plurality of microfluidic devices on or in said
culture module; and C) simultaneously (or sequentially) contacting
said ports on the cover of each microfluidic device of said
plurality of microfluidic devices with said mating surface of said
pressure manifold, such that the ports are in contact with said
pressure points, under conditions such that culture media flows
from said reservoirs into said microchannels of said microfluidic
devices, thereby perfusing said cells. In the above embodiment, the
plurality of microfluidic devices are simultaneously linked.
Thereafter, they can be simultaneously de-linked or disconnected
from the pressure manifold. In one embodiment, said plurality of
microfluidic devices are positioned on one or more trays (or nests)
prior to step B) and said placing of step B) comprising moving at
least a subset (at least three) of said plurality of microfluidic
devices simultaneously into said culture module. In one embodiment,
said simultaneous contacting of step C) is achieved by moving, via
the actuation assembly, the mating surface of the pressure manifold
down onto said cover assemblies of said plurality of microfluidic
devices. In one embodiment of the perfusion method, the
microfluidic device comprises a microfluidic chip (including but
not limited to the microfluidic chip shown in FIG. 3A, with one or
more microchannels and ports) engaged in a perfusion manifold
assembly, the assembly comprising i) a cover or lid configured to
serve as the top of ii) one or more fluid reservoirs, iii) a
fluidic backplane under, and in fluidic communication with, said
fluid reservoir(s), and iv) a projecting member or skirt that
engages the microfluidic chip (directly) or (indirectly through) a
carrier containing the microfluidic chip. It is preferred that the
perfusing is done at a rate that results in (or maintains) greater
than 80%, and more preferably greater than 90%, and most
preferably, greater than 95% viability of the cells contained
within the microfluidic chip. In one embodiment, the assembly
further comprises a capping layer under said fluid reservoir(s). In
one embodiment, said fluidic backplane comprises a resistor. In a
preferred embodiment, the microfluidic chip environment is
maintained to be sterile during said perfusing.
[0064] The present invention also contemplates controlling pressure
while perfusing cells (e.g. cells in microchannels of a
microfluidic device, such as the various embodiments of the
perfusion disposable discussed herein, where cells were first
seeded into said microfluidic device, with or without a seeding
guide of the type described herein), including controlling
pressure, in one embodiment, such that it is reliably maintained at
1 pKa (plus or minus 0.5 pKa, and more preferably, plus or minus
0.15 pKa). In one embodiment, the present invention contemplates a
method of controlling pressure while perfusing cells, comprising:
A) providing a) a plurality of microfluidic devices, each of said
microfluidic devices comprising i) one or more microchannels
comprising living cells, ii) one or more reservoirs comprising
culture media, b) one or more pressure actuators, B) coupling said
pressure actuators to at least one of the said reservoirs, the
coupling adapted such that actuated pressure modulates the
perfusion of at least some of said living cells, C) turning said
one or more pressure actuators between two or more pressure
setpoints, thereby controlling pressure while perfusing said cells.
In another embodiment, the present invention contemplates a method
of controlling pressure while perfusing cells, comprising: A)
providing a) a culture module, said culture module comprising i) an
actuation assembly configured to move ii) a pressure manifold, said
pressure manifold comprising a mating surface with pressure points,
and iii) one or more pressure controllers to provide pressure to
said pressure points; and b) a plurality of microfluidic devices,
each of said microfluidic devices comprising i) one or more
microchannels comprising living cells, ii) one or more reservoirs
comprising culture media, and iii) a cover assembly above said one
or more reservoirs, said cover assembly comprising a cover with
ports that correspond to the pressure points on the pressure
manifold mating surface; B) placing said plurality of microfluidic
devices on or in said culture module; C) simultaneously contacting
said ports on the cover of each microfluidic device of said
plurality of microfluidic devices with said mating surface of said
pressure manifold, such that the ports are in contact with said
pressure points, under conditions such that culture media flows
from said reservoirs into said microchannels of said microfluidic
devices, thereby perfusing said cells; and D) turning (or
switching) said one or more pressure controllers off for a period
of time and on for a period of time (or turning them between two or
more setpoints), thereby controlling pressure while perfusing said
cells. In one embodiment, the switching is between setpoints 1 kPa
and 0.5 kPa to get good resolution within that range. In one
embodiment, the switching is at three levels: 2 kPa, 1 kPa and 0
kPa for some advanced method. In one embodiment, said pressure
controllers are turned off and on (or between setpoints) in a
switching pattern (e.g. they are turned off and on, or between
setpoints, repeatedly at defined intervals). In a preferred
embodiment, the switching pattern is selected such that the average
value of pressure acting liquid in said one or more reservoirs
corresponds to a desired value. For cells, the desired value is
typically low. For example, in one embodiment, the switching
pattern is selected such that the average gas pressure is
maintained below 1 kPa. In one embodiment of the method of
perfusing and controlling pressure, the microfluidic device
comprises a microfluidic chip (including but not limited to the
microfluidic chip shown in FIG. 3A, with one or more microchannels
and ports) engaged in a perfusion manifold assembly, the assembly
comprising i) a cover or lid configured to serve as the top of ii)
one or more fluid reservoirs, iii) a fluidic backplane under, and
in fluidic communication with, said fluid reservoir(s), and iv) a
projecting member or skirt that engages the microfluidic chip
(directly) or (indirectly through) a carrier containing the
microfluidic chip. It is preferred that the perfusing is done at a
rate that results in greater than 80%, and more preferably greater
than 90%, and most preferably, greater than 95% viability of the
cells contained within the microfluidic chip. In one embodiment,
the assembly further comprises a capping layer under said fluid
reservoir(s). In one embodiment, said fluidic backplane comprises a
resistor. In one embodiment, the ports on the cover or lid are
associated with filters. In one embodiment, the filters are 0.2
micron, 0.4 micron or 25 micron filters. In a preferred embodiment,
the microfluidic chip environment is maintained to be sterile
during said perfusing. In one embodiment, cycling the pressure
regulators on and off brings the average value of pressure close to
the desired value, but the max and min values seen by the
microfluidic device or chip are brought much closer to the desired
value by incorporating the resistive filter at the inlet in the lid
of the perfusion manifold assembly.
[0065] A pressure lid is contemplated as a device that allows for
the pressurization of one or more fluid sources (e.g. reservoirs)
within or otherwise associated with a microfluidic device. The
present invention contemplates, in one embodiment, a pressure lid
comprising a plurality of ports configured to engage a pressure
manifold. In one embodiment, the ports are associated with filters.
In one embodiment, the lid is associated with a gasket. In one
embodiment, the pressure lid is movable or removably attached to a
microfluidic device to allow improved access to elements (e.g.
reservoirs) within. In one embodiment, the present invention
contemplates a method comprising a) providing a pressure lid, a
microfluidic device comprising a fluid source, and a pressure
manifold, wherein the pressure lid comprising a plurality of ports
configured to engage a pressure manifold; b) positioning said
pressure lid over said fluid source so as to create a positioned
pressure lid; and c) engaging said positioned pressure lid with
said pressure manifold under conditions such that pressure is
applied through said ports such that fluid from said fluid source
moves into or through said microfluidic device. In one embodiment,
the method further comprising d) disengaging said positioned
pressure lid from said pressure manifold. Thereafter, the pressure
lid can be (optionally) removed and the microfluidic device can be
used without the lid.
[0066] The present invention also contemplates a system comprising:
a) instrument for interfacing with b) a microfluidic device, said
microfluidic device either comprising or in fluidic communication
with i) one or more fluid reservoirs and ii) a pressure lid
comprising one or more instrument-interface ports and one or more
reservoir-interface ports, wherein the pressure lid is adapted to
convey pressure between at least one of the instrument-facing ports
and at least one of the reservoir-facing ports. In one embodiment,
the instrument comprises a (moving or non-moving) pressure
manifold. In one embodiment, the one or more fluid reservoirs are
disposed in a cartridge, said cartridge in fluidic communication
with said microfluidic device. In one embodiment, the one or more
fluidic reservoirs are disposed in the said microfluidic
device.
[0067] The present invention also contemplates, as a device, a
pressure lid comprising one or more instrument-interface ports and
one or more reservoir-interface ports, wherein the pressure lid is
adapted to convey pressure between at least one of the
instrument-facing ports and at least one of the reservoir-facing
ports, and wherein the pressure lid is adapted to form a pressure
interface with at least one fluid reservoir.
[0068] The present invention also contemplates, as a device, a
pressure lid comprising one or more channels, each channel
comprising an instrument-interface end and an reservoir-interface
end, the channel configured to convey pressure between an
instrument and a fluid reservoir.
DESCRIPTION OF THE FIGURES
[0069] FIG. 1A is an exploded view of one embodiment of the
perfusion manifold assembly showing the cover (or cover assembly)
off of the reservoirs (the reservoir body can be made of acrylic,
for example), the reservoirs positioned above the backplane, the
backplane in fluidic communication with the reservoirs, the skirt
with a side track for engaging a representative microfluidic device
or "chip" (which can be fabricated out of plastic, such as PDMS,
for example) having one or more inlet, outlet and (optional) vacuum
ports, and one or more microchannels, the chip shown next to (but
not in) one embodiment of a chip carrier (which can be fabricated
out of a thermoplastic polymer, such as acrylonitrile butadiene
styrene (ABS), for example), the carrier being configured to
support and carrier the chip, e.g. dimensioned so that the chip
fits within a cavity. FIG. 1B shows the same embodiment of the
perfusion manifold assembly with the cover on and over the
reservoirs, and the chip inside the chip carrier fully linked to
the skirt of the perfusion manifold assembly, and thereby in
fluidic communication with the reservoirs. In one embodiment, each
chip has two inputs, two outputs and (optionally) two connections
for the vacuum stretch. In one embodiment, putting the chip in
fluidic communication connects all six in one action, rather than
connecting them one at a time. FIG. 1C is an exploded view of one
embodiment of the perfusion manifold assembly (before the
components have been assembled) comprising reservoirs positioned
over a fluidic backplane (comprising a fluid resistor), that is
fluidically sealed with a capping layer and is positioned over a
skirt, with each piece dimensioned to fit over the next. In one
embodiment, the skirt comprises structure (e.g. made of polymer)
that borders or defines two open spaces, one of the spaces
configured to receive the carrier with the chip inside. In one
embodiment, the skirt has structure that completely surrounds one
open space and two "arms" that extend outwardly that define a
second open space for receiving the carrier. In one embodiment, the
two arms have side tracks for slidably engaging the carrier
edges.
[0070] FIG. 2A is an exploded view of one embodiment of the cover
assembly comprising a pressure cover or pressure lid. In the
illustrated embodiment, the pressure lid comprises a plurality of
ports (e.g. through-hole ports) associated with filters and
corresponding holes in a gasket. The illustrated design of the
holes in the gasket is intended to permit the gasket to aid in
retaining the illustrated filters in position. In alternative
embodiments, gasket openings may employ a shape different from
openings in the lid. For example, the gasket can be shaped to
follow the contour of one or more reservoirs with which it is
intended to form a fluidic or pressure seal. In some embodiments, a
plurality of gaskets may be employed. In some embodiments, the
filters and/or gasket may be fixed using an adhesive, heat
stacking, bonding (ultrasonic, solvent-assisted, laser welding),
clamped, or captured by elements of the lid and/or an additional
substrate. Although the illustrated pressure lid comprises
through-hole ports, alternative embodiments comprise one or more
channels that route at least one top-surface port to one or more
bottom surface ports, which need not be directly underneath the
top-surface port. FIG. 2B shows the same embodiment of the cover
assembly illustrated in FIG. 2A with the filters and gasket
positioned within (and under) the cover. FIG. 2C-1 is a
cross-section view of one embodiment of the cover assembly showing
the ridges or sealing tooth that surrounds both the through-hole
ports in the cover. FIG. 2C-2 is a magnified view of one portion of
FIG. 2C-1 (circled). In the illustrated embodiment, the cross
section shape of the sealing tooth is a trapezoidal shape, but
other contemplated embodiments employ other tooth shapes including
but not limited to semi-circular, rectangular, polygonal, and
triangular. FIG. 2D is a top view of one embodiment of the
reservoir chamber-cover assembly seal showing the sealing tooth,
vacuum chamber and inlet and outlet chambers. FIG. 2E-1 is a
cross-section view of one embodiment of the cover assembly seal in
connection with the reservoir, showing the cover gasket and sealing
tooth. FIG. 2E-2 is a magnified view of one portion of FIG. 2E-1
(circled). As the pressure manifold (discussed below) engages the
cover assembly, the pressure drives the cover assembly (including
the cover gasket) onto the sealing tooth, forming seals between
each of the reservoir chambers.
[0071] FIG. 3A shows one embodiment of the microfluidic device or
chip, showing two channels, each with an inlet and outlet port, as
well as (optional) vacuum ports. FIG. 3B is a topside schematic of
an alternative embodiment of the perfusion disposable or "pod"
featuring the transparent (or translucent) cover over the
reservoirs, with the chip inserted. The chip can be seeded with
cells and then placed in a carrier for insertion into the perfusion
disposable. FIG. 3C is a schematic of the same assembled perfusion
disposable embodiment shown in FIG. 3B, except that the ports on
the cover assembly and the cutout (above the inserted chip for
visualization, imaging, etc.) are now shown. FIG. 3D is a schematic
of the same perfusion disposable embodiment of FIG. 3C, but
unassembled to show the relationships of the cover, reservoirs,
skirt, chip and carrier.
[0072] FIG. 4A shows a side view of one embodiment of a chip
carrier (with the chip inside) approaching (but not yet engaging) a
side track of a skirt of one embodiment of the perfusion manifold
assembly, the carrier aligned at an angle matching an angled front
end portion of the side track, the carrier comprising a retention
mechanism configured as a upwardly protecting clip. Without being
bound by theory, a suitably large angle permits chip engagement
without smearing or premature engagement of liquid droplets present
on the chip and/or the perfusion manifold assembly during the
insertion and alignment processes. FIG. 4B shows a side view of one
embodiment of a chip carrier (with the chip inside) engaging a side
track of a skirt of one embodiment of (but not yet linked to) the
perfusion manifold assembly. FIG. 4C shows a side view of one
embodiment of a chip carrier (with the chip inside) fully engaging
a side track of a skirt of one embodiment of (but not yet linked
to) the perfusion manifold assembly (with an arrow showing the
necessary direction of movement to get a snap fit whereby the
retention mechanism will engage to prevent movement). FIG. 4D shows
a side view of one embodiment of a chip carrier (with the chip
inside) detachably linked to the perfusion manifold assembly, where
the retention mechanism is engaged to prevent movement. While
detachability and optionally re-attachability is desirable in
certain applications (for example, permitting chip removal to
enable the addition of cells, imaging, performing various assays),
in alternative embodiments, the linking is not detachable. For
example, an adhesive layer, glue and/or heat staking may be
employed to provide a robust linkage that may pose a challenge in
detachment or reattachment. FIGS. 4E1-4E3 is a summary slide
schematically showing one embodiment of a linking approach to the
perfusion manifold comprising a 1) sliding action (4E-1), 2)
pivoting (4E-2), and 3) snap fit (4E-3) so as to provide alignment
and fluidic connection in a single action. In the 1) sliding step,
the chip (or other microfluidic device) is inserted into the
carrier, which slides along to align the fluidic ports. In the 2)
pivot step, the chip (or other microfluidic device) is pivoted
until ports come into fluid contact. In the 3) clip or snap fit
step, the force needed to provide a secure seal is provided.
[0073] FIG. 5 is a schematic of one embodiment of a work flow (with
arrows showing each progressive step), where the chip is linked
(e.g. snapped in) to a disposable perfusion manifold assembly
("perfusion disposable"), which in turn is positioned with other
assemblies on a culture module, which is placed in an incubator. In
alternative embodiments, the culture module may comprise features
of an incubator (e.g. a heat source and/or a source of warm moist
air), so as to avoid the need for a separate incubator. While the
present invention contemplates "disposable" embodiments, the
element may (alternatively) be reusable (e.g. as a cost
consideration). In a further embodiment of the work flow or method,
the chip can be placed in a carrier, the carrier can be placed in a
seeding guide (discussed and illustrated below), cells can be
seeded into the chip, the carrier can be removed from the seeding
guide, and the carrier can engage the perfusion disposable (with
the rest of the work flow as illustrated in FIG. 5).
[0074] FIG. 6 shows one embodiment of a removable tray with a
plurality of assemblies (with linked chips) positioned thereon,
next to one embodiment of a culture module with pressure points on
a mating surface that correspond to the ports on the cover of each
perfusion manifold assembly held in the tray, such that they can be
brought together by the tray mechanism so that pressure can be
applied via the pressure controllers. The tray mechanism thereby
attaches all of the perfusion manifold assemblies to pressure or
flow controllers in a single action (whether lifting the tray up or
coming down to meet the tray), allowing for a simultaneous
linking.
[0075] FIG. 7 is a schematic of another embodiment of a culture
module from the side, showing the platform for positioning the
removable tray which is moved upward into a mating surface so that
pressure can be applied through the pressure controllers (not
shown).
[0076] FIG. 8A is a schematic of another embodiment showing the
tray (or rack) and sub-tray (or nest) for transporting and
inserting the perfusion disposables (PDs) into the pressure module,
which has a user interface on outside of the housing. FIG. 8B is a
schematic of another embodiment showing the trays (or racks)
inserted within the housing of the culture module, which has a user
interface. The illustrated nested design in which (in the present
example) a tray carries multiple removable sub-trays provides the
user with the flexibility to remove or carry various numbers of PDs
depending on use. For example, the user may carry a full tray to a
bio-safety cabinet in order to replenish media or collect samples
from all PDs in the tray, move a sub-tray of 3 PDs to a microscope
stage in order to image them without permitting the remaining PDs
from dysregulating in terms of temperature or gas content, or
remove or load a single PD for careful inspection or
replacement.
[0077] FIG. 9A is a schematic of the interior of one embodiment of
the pressure module (in an open position), showing the positioning
of the tray (or rack), sub-tray (or nest), perfusion disposables
(PDs) under a pressure manifold (but not engaging it, so the
clearance is sufficient to remove them), with the actuation
assembly (including the pneumatic cylinder) above. Three
microfluidic devices or perfusion disposables are shown to
illustrate, although more (e.g. 6, 9 or 12) are typically used at
once.
[0078] FIG. 9B is a schematic of the interior of one embodiment of
the pressure module (in a closed position), showing the positioning
of the tray (or rack), sub-tray (or nest), perfusion disposables
(PDs) under the pressure manifold (and engaging it), with the
actuation assembly (including the pneumatic cylinder) above. Again,
three microfluidic devices or perfusion disposables are shown to
illustrate, although more (e.g. 6, 9 or 12) are typically used at
once.
[0079] FIG. 10A is a schematic of one embodiment of the pressure
manifold (50) showing the view of the PD engaging face (54) with
several PD engaging locations (in this case, six engaging
locations). FIG. 10B shows a magnified portion of the engaging face
(54) of the pressure manifold (50) highlighting the spring shuttle
(55), valve seals (56) and alignment features (57) (so that the PD
is aligned with the manifold). FIG. 10C is a schematic of another
embodiment of the pressure manifold (50) showing the PD engaging
face (54), along with an magnified portion highlighting the lid
compressor (58), valve seals (56) and alignment features (57) (so
that the PD is aligned with the manifold). FIG. 10D is a schematic
of one embodiment of the pressure manifold (50) showing the PD
engaging face (54) from the side. FIG. 10E is a schematic of one
embodiment of the pressure manifold (50) showing the opposite face
(67). FIG. 10F is a schematic of one embodiment of the pressure
manifold (50) showing the PD engaging face (54) view with the PD
guide (68) and lower backer plate (69) removed, highlighting one
spring carrier (70) and spring (71) (out of many) by showing it
removed from the manifold body, along with one seal (72), shuttle
(73), and valve body (74) (out of many) by showing it removed from
the manifold body. An exterior spring (75) adapted to depress the
pressure manifold against the perfusion disposables is also
highlighted by showing it removed. FIG. 10G is a schematic of one
embodiment of the pressure manifold (50) showing the opposite face
(67) (not the PD engaging face) view with the upper backer plate
(76) and capping strip (77) removed. Illustrated are manifold
routing channels (78), which are adapted to direct and optionally
distribute pressure and/or fluid from one or more pressure ports.
Additionally illustrated is one screw (79) (among many) and one gas
port (80) (out of five, including both gas and vacuum ports) by
showing it removed from the manifold body (50). FIG. 10H is a
schematic of one embodiment of the pressure manifold (50) showing a
top view of the manifold routing channels (78) and one port (81)
among many.
[0080] FIG. 11A is a schematic of one embodiment of a valve (59) (a
Schrader valve) in the pressure manifold (50), showing the silicone
membrane (60), shuttle (61), air inlet (62) and cover plate (63).
FIG. 11B is a side view and FIG. 11C is a top view photograph of
one embodiment of a valve for the pressure manifold, showing the
valve seat (64) and a membrane (60) acting as the valve seal. FIG.
11D is an interior side view schematic of one embodiment of the
pressure manifold (50) showing a plurality of valves (59) in the
manifold body, the poppet (65), valve seal (66) and PD cover (11).
In operation (to engage the PD), the valve seal (66) deflects with
the displacement of the poppet (65).
[0081] FIG. 12A is a schematic of one embodiment of a connection
scheme comprising a tube connecting manifold (82) permitting four
culture modules (30) (three are shown) to be connected inside a
single incubator (31) using one or more hub modules (the two
circles provide magnified views of a first end (83) and second end
(84) of the connections). FIG. 12B is a photograph of gas hubs and
vacuum hubs (collectively 85), along with the tubing (86) for the
connection shown in FIG. 12A.
[0082] FIG. 13 is a photograph of one embodiment of an incubator
(from the outside with the outer door closed) containing shelves
(not shown) which can support the perfusion manifold assemblies of
the present invention. The incubator may have automated liquid
handling, imaging and sensing features for automatic experiments,
evaluating cell viability and/or collecting experimental results.
In one embodiment, the microfluidic devices are linked during
incubation.
[0083] FIGS. 14A-14B is a schematic showing one embodiment of
connecting two microfluidic devices, resulting in the introduction
of air bubbles into the microchannels. FIG. 14A shows two
fluidically primed devices (the fluid is shown with a meniscus)
with ports and microchannels that are not yet connected. FIG. 14B
shows the devices of FIG. 14A contacting in a manner that results
in the introduction of air bubbles (air is shown in the middle,
between each meniscus) into the ports (and ultimately, the
microchannels).
[0084] FIGS. 15A-15B is a schematic showing one embodiment of
connecting two microfluidic devices (or a microfluidic device to a
fluid source) utilizing a drop-to-drop approach, resulting in no
air bubbles. FIG. 15A shows two fluidically primed devices with
microchannels with protruding droplets formed on the surfaces of
the devices but not in the areas around the fluidic vias or port,
and more particularly, formed directly on and above the ports. FIG.
15B shows that when the surfaces come near each other during a
connection, the droplet surfaces join typically without introducing
any air bubbles.
[0085] FIG. 16A shows one embodiment for bringing a microfluidic
device into contact with a fluid source or another microfluidic
device, wherein the microfluidic device approaches from the side.
FIG. 16B shows one embodiment for bringing a microfluidic device
into contact with a fluid source or another microfluidic device,
wherein the microfluidic device approaches from the side and
underneath, so as to cause a drop-to-drop connection establishing
fluidic communication (FIG. 16C). FIG. 16D shows yet another
approach for brings a microfluidic device into contact with a fluid
source or another microfluidic device, wherein the microfluidic
device pivots.
[0086] FIG. 17 is a schematic showing a confined droplet (22) on
the surface (21) of a microfluidic device (16) in the via or
port.
[0087] FIG. 18 is a schematic showing a confined droplet (22) above
the surface (21) of a microfluidic device (16) in the area of the
via or port, wherein the droplet sits on a molded-in pedestal or
mount (42) and covers the mouth of the port and protrudes above the
port, and where the port is in fluidic communication with a
microchannel.
[0088] FIG. 19 is a schematic showing a confined droplet (22) above
the surface (21) of a microfluidic device (16) in the area of the
via or port, wherein the droplet sits on a gasket (43), covers the
mouth of the port, and protrudes above the port, and where the port
is in fluidic communication with a microchannel.
[0089] FIG. 20 is a schematic showing a confined droplet (22), a
portion of the droplet positioned below the surface (21) of a
microfluidic device (16) in the area of the via or port, wherein
the droplet sits on a molded-in depression or recess (44) and
covers the mouth of the port, with a portion protruding above the
surface, and where the port is in fluidic communication with a
microchannel.
[0090] FIG. 21 is a schematic showing a confined droplet (22), a
portion of the droplet positioned below the surface (21) of a
microfluidic device (16) in the area of the via or port, wherein
the droplet sits in a surrounding gasket and covers the mouth of
the port, with a portion protruding above the gasket.
[0091] FIGS. 22A-22B is a schematic showing a surface modification
embodiment. FIG. 22A employs a hydrophilic adhesive layer or
sticker (45) upon which the droplet (22) spreads out to the edges
of the sticker, constrained by a surrounding hydrophobic surface.
FIG. 22B shows a droplet (22) spreading out on a hydrophilic
surface of the device, constrained by a surrounding hydrophobic
surface.
[0092] FIG. 23 is a schematic showing a surface modification
embodiment employing surface treatment (indicated by downward
projecting arrows) in conjunction with a mask (41).
[0093] FIGS. 24A-24D is a schematic of one embodiment of a
drop-to-drop connection scheme whereby a combination of geometric
shapes and surface treatments are used to control the droplet. FIG.
24A shows an embodiment of the microfluidic device or "chip"
comprising a fluid channel and ports, having an elevated region at
each port (e.g. a pedestal or gasket). FIG. 24B shows the
hydrophilic channel filled with fluid where the droplet radius is
balanced at each end (i.e. at the port openings). FIG. 24C shows
one portion of the microfluidic device of FIG. 24B with an upward
projecting droplet (22) approaching (but not yet in contact with)
one portion of the mating surface of the perfusion manifold
assembly, which also has a projecting droplet (in this case, the
droplet (23) is projecting downward). FIG. 24D shows the same
portion of the microfluidic device of FIG. 24C with the upward
projecting droplet (22) of the microfluidic device making contact
with (and merging with) the downwardly projecting droplet (23) of
the perfusion manifold assembly.
[0094] FIGS. 25A-25B shows an embodiment of drop-to-drop connecting
using surface treatments alone (i.e. without geometric shapes such
as pedestals or gaskets). FIG. 25A shows an embodiment of the
perfusion manifold assembly comprising a fluid channel and a
port.
[0095] FIG. 25B shows the hydrophilic channel filled with fluid to
a level (e.g. height of the column of fluid).
[0096] FIG. 26 is a chart showing (without being bound by theory)
the relationship between the port diameter (in millimeters) and the
maximum hydrostatic head (in millimeters) that the stabilized
droplet can support.
[0097] FIG. 27 shows an embodiment where the microfluidic device
("chip") is linked from below to the perfusion manifold assembly
(above) at a port with a venting gasket (43), where the assembly
does not cover or close off the gasket, allowing any air trapped
during the linking to be vented out (right hand arrow). It may be
desirable to ensure that any air preferentially flows out through
the venting gasket rather than continue to flow through the
channels. In some embodiments, this preferential flow is encouraged
by subjecting fluid in the fluid channel of the assembly (left hand
arrow) to a first pressure (P1) and fluid in the microfluidic
device channel to a second pressure (P2), where P1 and P2 are
greater than the back-pressure of the venting gasket. In some
embodiments, the pressure P1 and/or P2 are applied using a pressure
source and/or gravitational head. In some embodiments, the pressure
P1 and/or P2 are generated by the flow resistance of the fluid.
[0098] FIG. 28 shows another embodiment where the microfluidic
device (16) ("chip") is linked from below to the perfusion manifold
assembly (10) (above) at a port with a venting gasket (43), where
the assembly covers the gasket (i.e. the gasket is enclosed by the
assembly mating surface), but where there is a path in the assembly
above the gasket to allow any air trapped during the linking to be
vented out.
[0099] FIG. 29 shows another embodiment where the microfluidic
device (16) ("chip") is linked from below to the perfusion manifold
assembly (10) (above) at a port with a venting gasket (43), where
the fluid path goes over the gasket (the gasket can be larger if
desired). This embodiment facilitates the removal of air trapped
during the linking including smaller bubbles, since, without being
bound by theory, it enables smaller bubbles to interact with
("wet") the venting gasket.
[0100] FIGS. 30A-30B and 31A-31B are a series of still photos from
a video showing one embodiment of the microfluidic device (having
droplets protruding from gaskets) moving along a essentially linear
(i.e. along the x axis in the x/y plane) rail or guide track of a
fluid source, or microfluidic device such as the perfusion manifold
assembly (compare FIGS. 30A to 30B) until it gets close (FIG. 31A)
to the corresponding ports of the perfusion manifold assembly,
whereupon a combination of movement in the x axis and z axis (i.e.
side movement and upward movement) causes the droplets to merge and
the chip to link (FIG. 31B).
[0101] FIG. 32A shows one embodiment of a fluidic backplane
comprising serpentine fluid resistor channels (91), vacuum channels
(92) and output channels (93). FIG. 32B is an edge view. FIG. 32C
shows the chip engagement bosses (94) of the fluidic backplane,
which serve as its fluidic outlet ports, along with assembly
alignment features (95) and a visualization cutout (96) which
permits microscopy and other imaging.
[0102] FIGS. 33A-33B shows a schematic of an illustrative
microfluidic device or "organ-on-chip" device. The assembled device
is schematically shown in FIG. 33A. FIG. 33B shows an exploded view
of the device of FIG. 33A.
[0103] FIG. 34 is a schematic showing an embodiment with two
membranes.
[0104] FIG. 35A shows first and second end caps (106 and 107) and
first and second side panels (108 and 109) as the components of one
embodiment of an unassembled culture stand or holder (100). FIG.
35B shows the chip (16) and carrier (17) within a seeding guide,
the seeding guide approaching (but not engaging) the stand (100).
FIG. 35C shows six seeding guides comprising carriers (17) (with
chips) mounted on the stand (100).
[0105] FIGS. 36A-C are photographs of a perfusion manifold assembly
embodiment that lacks a skirt (or other projection) with side
tracks for engaging a chip (or other microfluidic device) in a
carrier). Instead, the base (110) of the assembly (10) is
configured to accept the carrier (17) from underneath in a Lego.TM.
block type connection (instead of from the side), i.e. the base
(110) has a cavity (111) and openings (112) dimensioned to accept
the carrier (17), while the carrier's handle or tab (18) is
configured to fit in the openings (112). FIG. 36A is a topside view
of the assembly (10) before engaging the carrier (17) and chip
(16). FIG. 36B shows an underside view of the assembly (10) with
fluidic outlet ports (94) configured to align with ports (2) on the
chip (16). FIG. 36C shows the assembly (10) engaged with the
carrier such that the carrier tab (18) is positioned in the
openings (112).
DEFINITIONS
[0106] "Bond number" is a dimensionless ratio of gravity forces to
capillary forces on a liquid interface. When the Bond number is
high air, liquid interfaces tend to be shaped by gravity. When the
Bond number is low, those surfaces tend to be shaped by the
capillary force.
[0107] "Hydrophobic reagents" are used to make "hydrophobic
coatings" on surfaces (or portions thereof), including projections,
platforms or pedestals at or near ports, as well as mating surfaces
(or portions thereof). It is not intended that the present
invention be limited to particular hydrophobic reagents. In one
embodiment, the present invention contemplates the use of silanes
to make hydrophobic coatings, including but not limited to
halogenated silanes and alkylsilanes. In this regard, it is not
intended that the present invention be limited to particular
silanes; the selection of the silane is only limited in a
functional sense, i.e. that it render the surface hydrophobic. The
present invention also contemplates using commercially available
products, such as the Rain-X.TM. product which is a synthetic
hydrophobic surface-applied product that causes water to bead, most
commonly used on glass automobile surfaces.
[0108] A surface or a region on a surface is "hydrophobic" when it
displays (e.g. advancing) contact angles for water greater than
approximately ninety (90) degrees (in many cases, it is preferable
that both advancing and receding contact angles are greater than
approximately 90 degrees). In one embodiment, the hydrophobic
surfaces of the present invention display advancing contact angles
for water between approximately ninety (90) and approximately one
hundred and ten (110) degrees. In another embodiment, hydrophobic
surfaces have regions displaying advancing contact angles for water
greater than approximately one hundred and ten (110) degrees. In
another embodiment, hydrophobic surfaces have regions displaying
receding contact angles for water greater than approximately 100
degrees. It is important to note that some liquids, and
particularly some biological liquids, contain elements that may
coat a surface after wetting it, thereby affecting its
hydrophobicity. In the context of the present invention, it may be
important that a surface resists such coating from a liquid of
intended use, for example, that such coating does not create an
advancing and/or receding contact angle that is less than 90
degrees over the duration that the surface remains wetted by the
said liquid.
[0109] A surface or a region on a surface is "hydrophilic" when it
displays (e.g. advancing) contact angles for water less than
approximately ninety (90) degrees, and more commonly less than
approximately seventy (70) degrees (in many cases it is preferable
that both the advancing and receding contact angles are less than
approximately 90 degrees or approximately 70 degrees).
[0110] Measured contact angles can fall in a range, i.e. from the
so-called advancing (maximal) contact angle to the receding
(minimal) contact angle. The equilibrium contact is within those
values, and can be calculated from them.
[0111] Hydrophobic surfaces "resist wetting" by aqueous liquids. A
material is said to resist wetting by a first liquid where the
contact angle formed by the first liquid on the material is greater
than 90 degrees. Surfaces can resist wetting by aqueous liquids and
non-aqueous liquids, such as oils and fluorinated liquids. Some
surfaces can resist wetting by both aqueous liquids and non-aqueous
liquids. Hydrophobic behavior is generally observed by surfaces
with critical surface tensions less than 35 dynes/cm. At first, the
decrease in critical surface tension is associated with oleophilic
behavior, i.e., the wetting of the surfaces by hydrocarbon oils. As
the critical surface tensions decrease below 20 dynes/cm, the
surfaces resist wetting by hydrocarbon oils and are considered
oleophobic as well as hydrophobic.
[0112] Hydrophilic surfaces "promote wetting" by aqueous liquids. A
material is said to promote wetting by a first liquid where the
contact angle formed by the first liquid on the material is less
than 90 degrees, and more commonly less than 70 degrees.
[0113] As used herein, the phrases "linked," "connected to,"
"coupled to," "in contact with" and "in communication with" refer
to any form of interaction between two or more entities, including
mechanical, electrical, magnetic, electromagnetic, fluidic, and
thermal interaction. For example, in one embodiment, channels in a
microfluidic device are in fluidic communication with cells and
(optionally) a fluid reservoir. Two components may be coupled to
each other even though they are not in direct contact with each
other. For example, two components may be coupled to each other
through an intermediate component (e.g. tubing or other
conduit).
[0114] "Channels" are pathways (whether straight, curved, single,
multiple, in a network, etc.) through a medium (e.g., silicon,
plastic, etc.) that allow for movement of liquids and gasses.
Channels thus can connect other components, i.e., keep components
"in communication" and more particularly, "in fluidic
communication" and still more particularly, "in liquid
communication." Such components include, but are not limited to,
liquid-intake ports and gas vents.
[0115] "Microchannels" are channels with dimensions less than 1
millimeter and greater than 1 micron. Additionally, the term
"microfluidic" as used herein relates to components where moving
fluid is constrained in or directed through one or more channels
wherein one or more dimensions are 1 mm or smaller (microscale).
Microfluidic channels may be larger than microscale in one or more
directions, though the channel(s) will be on the microscale in at
least one direction. In some instances the geometry of a
microfluidic channel may be configured to control the fluid flow
rate through the channel (e.g. increase channel height to reduce
shear). Microfluidic channels can be formed of various geometries
to facilitate a wide range of flow rates through the channels.
[0116] The present invention contemplates a variety of
"microfluidic devices," including but not limited to microfluidic
chips (such as that shown in FIG. 3A), perfusion manifold
assemblies (without chips), and perfusion manifold assemblies
engaged with microfluidic chips (such as that shown in FIG. 3B).
However, the methods described herein for engaging microfluidic
devices (e.g. by drop-to-drop connections), and for perfusing
microfluidic devices are not limited to the particular embodiments
of microfluidic devices described herein, and may be applied
generally to microfluidic devices, e.g. devices having one or more
microchannels and ports.
[0117] A "stable droplet" is a droplet of media that does not
experience significant movement away from its intended location
(e.g. to remain in contact with a fluidic port) and preferably does
not experience a significant (>10%) change in volume or
placement on a microfluidic device over the course of several
seconds, and more preferably one minute, and even more preferably
several minutes (2-10 minutes). In a preferred embodiment, the
present invention contemplates a stable droplet during drop-to-drop
engagement. A surface may intrinsically (e.g. because of what it is
made of) be able to stably retain, or be made to stably retain, a
droplet, meaning that the droplet will not spontaneously expand or
shift beyond a limited (or designated) area. Stable droplets do not
experience a significant change in volume or placement. The present
invention contemplates this spatial control of droplets, i.e.
retaining the droplet within a defined spatial extent and/or
retaining the droplet within the spatial extent of the one or more
regions. In a preferred embodiment, the present invention
contemplates both preventing the droplet from extending too far,
and ensuring that it is centered on the port (i.e. making sure that
the area right on top of the fluidic port remains covered by the
droplet). In terms of preventing the droplet from extending or
spreading too wide, the present invention contemplates, in one
embodiment, retaining the droplet within the spatial extent of the
one or more regions. In a particularly preferred embodiment, the
present invention contemplates preventing the droplet from shifting
away during manipulation (i.e. rolling away on the surface as the
microfluidic device or chip is moved around or even inverted. Of
course, such movements are contemplated without violent shaking. A
droplet that is found to be stable if a particular engagement
procedure is used, may be found unstable if another procedure (e.g.
more violent procedure) is utilized.
[0118] "Controlled engagement" refers to engagement of two devices
that allows for both adequate alignment of vias or ports, and
smooth drop-to-drop connection, which does not result in loss of
droplet stability. If the devices, for example, snap violently into
place or the droplets on opposite devices touch prior to
engagement, droplet stability will be compromised.
General Description of the Invention
[0119] In one embodiment, the present invention contemplates a
perfusion manifold assembly that allows for perfusion of a
microfluidic device, such as an organ on a chip microfluidic device
comprising cells that mimic cells in an organ in the body or at
least one function of an organ, that is (preferably detachably)
linked with said assembly so that fluid enters ports of the
microfluidic device from a fluid reservoir, optionally without
tubing, at a controllable flow rate. In one embodiment (as shown in
FIGS. 1A, 1B and 1C), the perfusion manifold assembly (10)
comprises i) a cover or lid (11) configured to serve as to top of
ii) one or more fluid reservoirs (12), iii) a capping layer (13)
under said fluid reservoir(s), iv) a fluidic backplane (14) under,
and in fluidic communication with, said fluid reservoir(s), said
fluidic backplane comprising a fluidic resistor, and v) a
projecting member or skirt (15) for engaging the microfluidic
device (16) or chip which is preferably positioned in a carrier
(17), the chip having one or more microchannels (1) and in fluidic
communication with one or more ports (2). The assembly can be used
with or without the lid or cover. Other embodiments (discussed
below) lack a skirt or projecting member. In one embodiment, the
carrier (17) has a tab or other gripping platform (18), a retention
mechanism such as a clip (19), and a visualization cutout (20) for
imaging the chip. The cutout (20) can enable placing a carrier
(e.g. a carrier engaged with the perfusion manifold assembly or
"pod" or not so engaged) onto a microscope or other inspection
device, allowing the chips to be observed without having to remove
the chip from the carrier. In one embodiment, the fluidic resistor
comprises a series of switchbacks or serpentine fluid channels.
FIG. 32 shows an enhanced schematic of one embodiment of the
backplane, showing the fluid resistor channels (32A) and chip
engagement bosses (32C) or ports. A variety of fluid resistors
designs are contemplated, as described more fully in U.S.
Provisional Application Ser. Nos. 62/024,361 and 62/127,438, which
became PCT/US2015/040026, hereby incorporated by reference (and in
particular, the discussion of resistors, resistor design, and
pressures is incorporated herein by reference). In one embodiment,
the perfusion manifold assembly is made of plastic and is
disposable, i.e. it is disposed of after docking with and perfusing
a microfluidic device. While the present invention contemplates
"disposable" embodiments, the element may (alternatively) be
reusable (e.g. as a cost consideration).
[0120] In one embodiment, the microfluidic device (e.g. chip) (16)
may first be placed in a carrier (17) (e.g. chip carrier) before
engaging the perfusion manifold assembly (10) or may engage the
assembly directly. In either case, the (optional) detachable
linking of the microfluidic device with the manifold should either
a) prevent air from entering the microchannels, or b) provide a way
for undesirable air to be removed or vented out of the system.
Indeed, air removal may be needed in some embodiments during both
chip attachment and use of the microfluidic device.
[0121] In one embodiment for preventing air from entering the
microchannels, the microfluidic device is detachably linked using a
"drop-to-drop" "chip-to-cartridge" connection. In this embodiment,
an inlet port of the microfluidic device has a droplet (22)
projecting therefrom (FIG. 15A), and the surface of the perfusion
manifold assembly or "cartridge" (10) for engaging the device has a
corresponding droplet (23). When the two are brought together (FIG.
15B), the droplets merge allowing for fluidic communication without
the introduction of air into the channels. In one embodiment, the
chip carrier is designed so as to not interfere with the
"drop-to-drop" connection. For example, the carrier, in one
embodiment, surrounds the sides, but not the mating surface (21) of
the microfluidic device. It should be noted that FIG. 15A shows a
skirt-free perfusion manifold (10) where the microfluidic device or
chip engages from underneath (rather than from the side).
[0122] It is not intended that the present invention be limited to
only one manner for detachably linking the microfluidic device. In
one embodiment, the microfluidic device, such as an organ on a chip
microfluidic device comprising cells that mimic one or more
functions of cells in an organ in the body or at least one function
of an organ, approaches the assembly from the side (FIG. 16A) or
underneath (FIG. 16B), with the droplet (22) projecting upward,
while the corresponding droplet (23) on the assembly (or other type
of fluid source) projects downward. The microfluidic device (or the
device carrier) may comprises a portion (24) configured to engage a
side track (25) or other guide mechanism. In another embodiment,
the microfluidic device, such as an organ on a chip microfluidic
device comprising cells that mimic cells in an organ in the body or
at least one function of an organ, approaches the assembly from
above, with the droplet projecting downward, while the
corresponding droplet on the assembly projects upward. In still
another embodiment, the microfluidic device, such as an organ on a
chip microfluidic device comprising cells that mimic cells in an
organ in the body or at least one function of an organ, approaches
the assembly from the side and is positioned by pivoting (FIG. 16D,
see the arrow) about a hinge, socket, or other pivot point (26). In
still another embodiment, the microfluidic device engages in the
manner of an audio cassette or CD with the droplet projecting
upward, while the corresponding droplet on the assembly projects
downward, where there is a combined sideways movement and upward
movement (FIGS. 16B-16C).
[0123] In one embodiment, the microfluidic device (16) is
detachably linked with the perfusion manifold assembly (10) by a
clipping mechanism that temporarily "locks" the microfluidic
device, including organ-on-chip devices, in place (FIGS. 4A, 4B, 4C
and 4D). In one embodiment, the clipping or "snap fitting" involves
a projection on the carrier (19) which serves as a retention
mechanism when the microfluidic device (16) is positioned. In one
embodiment, the clipping mechanism is similar to the interlocking
plastic design of a Lego.TM. chip and comprises a straight-down
clip, friction fit, radial-compression fit or combination thereof.
However, in another embodiment, the clipping mechanism is triggered
only after the microfluidic device, or more preferably, the carrier
(17) comprising the microfluidic device (16), engages the perfusion
manifold assembly (or cartridge) on a guide rail, side slot,
internal or external track (25) or other mechanism that provides a
stable glide path for the device as it is conveyed (e.g. by machine
or by hand) into position. The guide rail, side slot, internal or
external track (25) or other mechanism can be, but need not be,
strictly linear and can be positioned in a projecting member or
skirt (15) attached to the main body of the perfusion manifold
assembly (10). In one embodiment, the beginning portion of the
guide rail (25) (or side slot, internal or external track or other
mechanism) comprises an angled slide (27) which provides a larger
opening for easier initial positioning, followed by a linear or
essentially linear portion (28). In one embodiment, the end portion
(29) (close to the corresponding ports of the assembly) of an
otherwise linear (or essentially linear) guide rail (25) (or side
slot, internal track or other mechanism) is angled (or curves)
upward (FIG. 16B) so that there is a combination of linear movement
(e.g. initially) and upward movement to achieve linking.
[0124] In several embodiments, it is important that droplets remain
placed at their corresponding fluidic port despite the motion of
their substrate or any period of upside-down orientation. In
addition, it is desirable that the droplets retain their size, for
example, so that the drop-to-drop process is consistent regardless
of the speed of the engagement process. Accordingly, the present
invention contemplates designs and method to provide stable
droplets. Stable droplets are contemplated for aqueous as well as
non-aqueous liquids. Although we focus our examples without loss of
generality on aqueous droplets, one familiar with the art should be
able to adapt the examples and particularly the use of hydrophilic
and hydrophobic regions or materials based on the wetting
properties of the liquid. In some embodiments, a droplet may be
restricted within a first region of a substrate by surrounding the
first region with a second region, wherein the second region is
hydrophobic (or more generally, with a propensity against wetting
by the droplet's liquid). The said second region may be hydrophobic
due to selection of one or more hydrophobic materials that it
comprises (e.g. PTFE, FEP, certain grades of Nylon, etc.), surface
treatment (e.g. plasma treatment, chemical treatment, ink
treatment), the use of a gasket (e.g. a film, an o-ring, an
adhesive gasket), by masking during treatment of at least one other
region of the substrate, or a combination thereof. In some
embodiments, a droplet may be restricted within a first region of a
substrate by surrounding the first region with a geometric feature.
In some embodiments, the geometric feature may be a ridge or a
depression. Without being bound by theory, such features may act to
restrict the droplet by means of their edges , which interact with
the surface layer of the droplet (and correspondingly with the
surface tension of the droplet), for example, by "pinning" the
surface of the droplet. In some embodiments, a droplet may be
restricted to cover a first region of a substrate by adapting the
first region to be hydrophobic (or more generally, with a
propensity for wetting by the droplet's liquid). The said first
region may be hydrophilic due to selection of one or more
hydrophilic materials that is comprises (e.g. PMMA, PLA), surface
treatment (e.g. plasma treatment, chemical treatment, ink
treatment), the use of a gasket (e.g. a film, an o-ring, an
adhesive gasket), by masking during the treatment of at least one
of other region of the substrate, or a combination thereof.
[0125] In one embodiment, the mating surface (21) of a microfluidic
device (or at least a portion thereof adjacent the port opening) is
hydrophobic or made hydrophobic (or protected with a mask during
plasma treatment to keep it from becoming hydrophilic). In one
embodiment, the mating surface of a perfusion manifold assembly or
cartridge (or at least a portion thereof adjacent the port opening)
is hydrophobic or made hydrophobic (or protected with a mask during
plasma treatment to keep it from becoming hydrophilic). In one
embodiment, both the mating surface of the microfluidic device (or
at least a portion thereof adjacent the port opening) and the
mating surface of the perfusion manifold (or at least a portion
thereof adjacent the port opening) is hydrophobic or made
hydrophobic (or protected with a mask during plasma treatment to
keep it from becoming hydrophilic).
[0126] The advantage of the carrier is that the surfaces of the
microfluidic device need not be touched during the detachable
linkage with the perfusion manifold assembly. The carrier can have
a plate, platform, handle or other mechanism for gripping the
carrier (18), without contacting the mating surface (21) of the
microfluidic device (16). The retention mechanism (19) can comprise
a projection, hook, latch or lip that engages one or more portions
of the perfusion manifold assembly, and more preferably the skirt
of the perfusion manifold assembly, to provide a "snap fit."
[0127] In other embodiments (FIGS. 27, 28 and 29), one or more
gaskets can be used to vent air (e.g. any air that has been
introduced because of the detachable linking of the microfluidic
device with the perfusion manifold assembly). While in one
embodiment, bubbles can be trapped (and their impact thereby
limited), in an alternative embodiment, they are vented. One method
involves use of hydrophobic vent material (molded or sheet). For
example, the hydrophobic vent material may comprise PTFE, PVDF,
hydrophobic grades of Nylon, or a combination thereof. In some
embodiments venting can be accomplished by employing materials that
display high gas permeability (e.g. PDMS). In other embodiments,
venting can be accomplished by employing porous materials, for
example, sintered materials, porous membranes (e.g. track-etched
membranes, fiber-based membranes), open-cell foams, or a
combination thereof. In a preferred approach, air escapes from a
vented (or venting) gasket. In some embodiments, the perfusion
manifold assembly or microfluidic device comprise a vent adapted to
provide a path for undesired gas to escape.
[0128] Once a microfluidic device (or "chip") has docked with the
perfusion manifold assembly, the assembly-chip combination can be
placed into an incubator (31) (typically set at a temperature above
room temperature, e.g. 37.degree. C.), or more preferably, into a
culture module (30) capable of holding a plurality of assembly-chip
combinations, the culture module configured to fit on an incubator
shelf (see FIG. 5). This allows for the easy handling of many (e.g.
5, 10, 20, 30, 40, 50 or more) microfluidic devices at one time.
For example, where the culture module comprises 9 assembly-chip
combinations, and an incubator is sized for 6 to 9 culture modules,
between 54 and 81 "organs-on-chip" can be handled in a single
incubator (FIG. 5 and FIG. 8). In another example, where the
culture module comprises 12 assembly-chip combinations, and an
incubator is sized for 4 to 6 culture modules, between 48 and 72
"organs-on-chip" can be handled in a single incubator. The
perfusion manifold can be easily removed and inserted into the
culture module without breaking the fluidic connections to the
chip. In one embodiment, the culture module is capable of
maintaining the temperature above room temperature, e.g. 37.degree.
C., without being placed in an incubator.
[0129] The culture module (30), in one embodiment (FIG. 6),
comprises a removable tray (32) for positioning the assembly-chip
combinations, a pressure surface (33), and pressure controllers
(34), along with an optional user interface (46) to control the
movement of the various elements. In one embodiment, the tray (32)
can slide. In one embodiment, the tray is positioned on the culture
module and the tray is moved up via a tray mechanism (35) to engage
the pressure surface (33) of the culture module, i.e. the cover or
lid (11) of the perfusion manifold assembly (10) engages the
pressure surface of the culture module (30). Multiple perfusion
assemblies (10) can be attached to the pressure controllers in a
single action by the tray mechanism. In another embodiment, the
tray is positioned on the culture module and the pressure surface
of the culture module (30) is moved down to engage the tray (32),
i.e. the cover or lid (11) of the perfusion manifold assembly (10).
In either case, in one embodiment (FIGS. 2A and 2B), the cover or
lid comprises ports such as through-hole ports (36) that are
engaged by corresponding pressure points on the pressure surface
(33) of the culture module. These ports (36), when engaged,
transmit applied pressure inward through the cover and through a
gasket (37) and apply the pressure to the fluid in the reservoirs
(12) of the perfusion manifold assembly (10). Thus, in this
embodiment, pressure is applied through the lid (11) and the lid
seals against the reservoir(s). For example, when on applies 1 kPa,
this nominal pressure results, in one embodiment, in a flow rate of
approximately 30-40 uL/hr. Alternatively, these ports (36), when
engaged, move inward on the cover so as to contact the gaskets
(i.e. the ports act essentially like plungers).
[0130] FIG. 8A is a schematic of another embodiment of the culture
module (30) showing the tray (or rack) (32) and sub-tray (or nest)
for transporting and inserting the perfusion disposables (10) into
the culture module, which has two openings (48, 49) in the housing
to receive the trays, and a user interface (46) to control the
process of engaging the perfusion disposables and applying
pressure. A typical incubator (not shown) can hold up to six
modules (30). FIG. 8B is a schematic of the same embodiment of FIG.
8A, but showing both of the trays (or racks) (32) inserted into the
two openings (48, 49) in the housing (53) of the pressure module
(30), which has a user interface (46) (e.g. LCD screen) to control
the process.
[0131] FIG. 9A is a schematic of the interior of one embodiment of
the module (i.e. the housing has been removed), showing the
pressure manifold (50) in an open position, with the positioning of
the tray or rack (32), sub-tray or nest (47), perfusion disposables
(10) under the pressure manifold (50) but not engaging it (so the
clearance is sufficient to remove them), with the actuation
assembly (51) including the pneumatic cylinder (52) above.
[0132] FIG. 9B is a schematic of the interior of one embodiment of
the module (i.e. the housing has been removed), showing the
pressure manifold (50) in a closed position, with the positioning
of the tray or rack (32), sub-tray or nest (47), perfusion
disposables (10) under the pressure manifold (50) and engaging it,
with the actuation assembly (51) including the pneumatic cylinder
(52) above. The pressure manifold (50) simultaneously engages all
of the perfusion disposables (10) while media perfusion is required
or needed. Independent control of the flow rate in the top and
bottom channels of the chip (16) can be achieved. The pressure
manifold (50) can disengage (without complicated fluid disconnects)
as desired to allow removal of the trays (32) or nests (47) for
imaging or other tasks. In one embodiment, the pressure manifold
(50) can simultaneously disengage from a plurality of perfusion
manifold assemblies. In one embodiment, the perfusion disposables
(10) are not rigidly fixed inside the nests (47), allowing them to
locate relative to the pressure manifold (50) as it closes. In a
preferred embodiment, integrated alignment features in the pressure
manifold (50) provide guidance for each perfusion disposable
(10).
[0133] In one embodiment, the cover or lid is made of
polycarbonate. In one embodiment, each through-hole port is
associated with a filter (38) (e.g. a 0.2 um filter). In one
embodiment, the filters are aligned with holes (39) in a gasket
positioned underneath the cover.
[0134] A culture module comprising a pressure manifold is
contemplated that allows the perfusion and optionally mechanical
actuation of one or more microfluidic devices, such as
organ-on-a-chip microfluidic devices comprising cells that mimic at
least one function of an organ in the body. FIG. 10A is a schematic
of one embodiment of the pressure manifold (50) showing the view of
the PD engaging face (54) with several PD engaging locations (in
this case, six engaging locations). FIG. 10B shows a magnified
portion of the engaging face (54) of the pressure manifold (50)
highlighting the spring shuttle (55), valve seals (56) and
alignment features (57) (so that the PD is aligned with the
manifold). The spring shuttle is an optional means by which the
pressure manifold may sense the presence of a PD in the particular
PD engaging location. In a specific embodiment, the presence of a
PD depresses the spring shuttle, which opens one or more valves
disposed within the pressure manifold to enable the application of
pressure or fluid flow to the PD. In turn, when a PD is absent, the
shuttle is not depressed, leaving the valve closed; this is
intended to prevent pressure or fluid leakage. The illustrated
valve seals are adapted to form pressure and/or fluid seals against
corresponding features in the PD and if present, a pressure lid.
FIG. 10C is a schematic of another embodiment of the pressure
manifold (50) showing the PD engaging face (54), along with an
magnified portion highlighting the lid compressor (58), valve seals
(56) and alignment features (57) (so that the PD is aligned with
the manifold). Lid compressors may apply force onto a pressure lid
in order to aid the establishment of maintenance of a pressure
and/or fluidic seal between the pressure lid and reservoirs. In one
embodiment, the lid compressors comprise springs, elastomeric
material, pneumatic actuators or combination thereof, which can be
selected and sized to apply a force corresponding to the force
required to maintain the said pressure and/or fluidic seal. FIG.
10D is a schematic of one embodiment of the pressure manifold (50)
showing the PD engaging face (54) from the side. FIG. 10E is a
schematic of one embodiment of the pressure manifold (50) showing
the opposite face (67). FIG. 10F is a schematic of one embodiment
of the pressure manifold (50) showing the PD engaging face (54)
view with the PD guide (68) and lower backer plate (69) removed,
highlighting one spring carrier (70) and spring (71) (out of many)
by showing it removed from the manifold body, along with one seal
(72), shuttle (73), and valve body (74) (out of many) by showing it
removed from the manifold body. An exterior spring (75) adapted to
depress the pressure manifold against the perfusion disposables is
also highlighted by showing it removed. FIG. 10G is a schematic of
one embodiment of the pressure manifold (50) showing the opposite
face (67) (not the PD engaging face) view with the upper backer
plate (76) and capping strip (77) removed. Illustrated are manifold
routing channels (78), which are adapted to direct and optionally
distribute pressure and/or fluid from one or more pressure ports.
Additionally illustrated is one screw (79) (among many) and one gas
port (80) (out of five, including both gas and vacuum ports) by
showing it removed from the manifold body (50). FIG. 10H is a
schematic of one embodiment of the pressure manifold (50) showing a
top view of the manifold routing channels (78) and one port (81)
among many. The routing channels can be produced using a number of
methods known in the art, including molding, machining, ablation,
lamination, 3D printing, photolithography and a combination
thereof.
[0135] FIG. 11A is a schematic of one embodiment of a valve (59) (a
Schrader valve) in the pressure manifold (50), showing the silicone
membrane (60), shuttle (61), air inlet (62) and cover plate (63).
In this embodiment, the spring shuttle is integrated into the valve
and is adapted to depress the Schrader valve's poppet to actuate
the valve. FIG. 11B is a side view and FIG. 11 C is a top view
photograph of one embodiment of a valve for the pressure manifold,
showing the valve seat (64) and a membrane (60) acting as the valve
seal. FIG. 11D is an interior side view schematic of one embodiment
of the pressure manifold (50) showing a plurality of valves (59) in
the manifold body, the poppet (65), valve seal (66) and PD cover
(11). In operation (to engage the PD), the valve seal (66) deflects
with the displacement of the poppet (65).
[0136] FIG. 12A is a schematic of one embodiment of a connection
scheme comprising a tube connecting manifold (82) permitting four
culture modules (30) (three are shown) to be connected inside a
single incubator (31) using one or more hub modules (the two
circles provide magnified views of a first end (83) and second end
(84) of the connections). FIG. 12B is a photograph of gas hubs and
vacuum hubs (collectively 85), along with the tubing (86) for the
connection shown in FIG. 12A. While this connection scheme is
optional, it provides a convenient way to utilize multiple culture
modules with a single incubator.
Detailed Description of the Invention
[0137] A. Pressure Lid
[0138] The present invention contemplates in one embodiment
"perfusion manifold assemblies" or "perfusion disposables," which
facilitate the culture of Organs-on-Chips within a culture
instrument. While the present invention contemplates "disposable"
embodiments, the element may (alternatively) be reusable (e.g. as a
cost consideration).
[0139] In one embodiment, these perfusion disposables (PDs) include
one or more input and one or more output reservoirs, as well as
elements required for pumping. In particular, in our present
embodiment perfusion disposables include one or more resistors (see
FIG. 32A), which are used for pressure-driven pumping. In the
pressure-driven embodiment, the instrument creates or controls
fluid flow by applying a pneumatic pressure (whether positive or
negative) to one or more of the reservoirs. One advantage of this
approach is that the pressure-driven design can avoid liquid
contact with the instrument, which offers benefits in terms of
sterility and ease of use (e.g. avoiding gas bubbles in liquid
lines). In some embodiments, the instrument applies pressure
directly to the one or more reservoirs (with no lid). A sufficient
pressure seal may be attained by integrated one or more gaskets on
the perfusions disposable and/or the instrument (for example, as
part of a pressure manifold). However, it is desirable that when
the perfusion disposables are outside of the instrument the
reservoirs are protected from contamination, for example, from
environmental particles or airborne microbes. Accordingly, in the
same embodiments it may be desirable to provide a lid that a user
can employ to cover the reservoirs when outside of the instrument
and/or to employ PD embodiments that comprise a substrate that
conveys pressure but blocks contamination (for example, a suitable
filter disposed on a reservoir's opening). However, such solutions
typically pose drawbacks. In particular, expecting a user to place
a lid requires the user to manage lids while the perfusion
disposables are engaged with the instrument and ideally place the
lids as soon as the PDs leave the instrument; in most
circumstances, these actions adversely affect user experience. In
turn, a filter disposed on a reservoir's opening typically blocks
access to the said reservoir by pipettes and other typical lab
tools, thereby adversely limiting their ease of use.
[0140] According to an aspect of the present invention, we disclose
a "pressure lid", a lid that may be disposed on a microfluidic
device or a device adapted to accept a microfluidic device (e.g. a
perfusion disposable) even while the said device is engaged with an
instrument, with the pressure lid adapted to permit the
communication of pressure between the instrument and the said
device. The present invention contemplates that in some
embodiments, a pressure lid is a removable cover adapted to be
disposed onto one or more reservoirs of a microfluidic device or a
device adapted to accept a microfluidic device (e.g. a perfusion
disposable), the pressure lid comprising at least one
instrument-interface port and at least one reservoir-interface
port, wherein the pressure lid is adapted to convey pressure
between at least some of the instrument-facing port and at least
some of the reservoir-facing ports. In some embodiments, the
pressure lid comprises at least one "through hole" port--an opening
that connect a first and second surface of the lid, wherein the
opening on the first surface is adapted to form an
instrument-facing port and the opening on the second surface is
adapted to foul a reservoir-facing port. In some embodiments, the
though-hole port is round, rectangular, triangular, polygonal,
rectilinear, curvilinear, elliptical, and/or curved. In some
embodiments, however, the lid comprises a channel that links at
least one instrument-facing port and at least one reservoir-facing
ports, which may not be disposed directly opposite each other. Such
embodiments may be useful, for example, where there is a need to
adapt between locations of instrument interface and reservoir
locations, for example, when it is desired for the same instrument
to support the actuation of a plurality of versions of perfusion
disposables.
[0141] In some embodiments, the pressure lid is adapted to form a
pressure seal between said pressure lid and at least one reservoir.
In some embodiments, the pressure lid is engaged with at least one
reservoir forming a lid-to-reservoir pressure seal. In some
embodiments, the pressure lid is adapted to form a pressure seal
between said pressure lid and at least one instrument. In some
embodiments, the pressure lid is engaged with at least one
instrument forming a lid-to-instrument pressure seal. Any of the
lid-to-reservoir seals and lid-to-instrument seals may employ any
sealing methodology known in the art and can be selected for
example, from the list of face seal, radial seal, tapered seal,
friction fit or a combination thereof. Any of the said seals may
employ one or more gaskets, O-Rings, elastic materials, pliable
materials, adhesive, sealants, greases or combination thereof. It
is not intended that the present invention be limited to a design
that has a perfect pressure seal, as this may not be required.
Rather, some amount of gas leakage can be tolerated, since the
instrument may actively regulate pressure, thereby compensating for
the leak. The relaxing of a requirement to obtain a perfect seal on
one or both sides can simplify design and reduce costs.
[0142] In some embodiments, the pressure lid comprises a load
concentrator. For example, in some embodiments, the pressure lid
comprises a ridge surrounding at least one instrument-facing port.
In some embodiments, the pressure lid comprises a ridge surrounding
at least one reservoir-facing port. It is known in the art that
such load concentrators can act to improve pressure seals by
enhancing reliability or reducing the required force; designs known
in the art include, for example, rectangular, semi-circular,
triangular, trapezoidal and polygonal ridges. Accordingly, a load
concentrator surrounding an instrument-facing port may be employed
to improve a lid-to-instrument pressure seal, and a load
concentrator surrounding a reservoir-facing port may be used to
improve a lid-to-reservoir pressure seal.
[0143] In some embodiments, the pressure lid comprises a filter.
For example, the pressure lid may comprise a membrane filter,
sintered filter, fiber-based filter and/or track-etched filter. In
some embodiments, the said filter is disposed within or abutting a
through-hole port and/or one of its openings. In some embodiments,
the said filter is disposed within or abutting a channel included
in the lid and/or one of the openings of said channel.
[0144] In some embodiments, the filter is selected to improve the
sterility of a reservoir and/or block particles, contaminated or
microbes. In some embodiments, the filter feature an effective pore
size of 0.4 um or less, 0.2 um to 2 um, 1 um to 10 um, 5 um to 20
um, 10 um to 50 um. It is known in the art that filters that
feature an effective pore size of 0.4 um or less are preferable for
maintaining sterility. However, a filter such as the Porex 4901
possess a 25 um effective pore size has been shown to be effective
in maintaining sterility.
[0145] In some embodiments, the pressure lid comprises one or more
gaskets. In some embodiments, the one or more gaskets are adapted
to permit or improve a pressure seal (which may nevertheless not be
a perfect seal). In some embodiments, at least one gasket is
disposed on a reservoir-contact surface of the said lid. In some
embodiments, at least one gasket is disposed on an
instrument-contact surface of the said lid. In some embodiments, a
gasket is adapted to permit or improve pressure seals with a
plurality of reservoirs. In some embodiments, a gasket is adapted
to permit or improve pressure seals at a plurality of
instrument-facing ports. In some embodiments, the one or more of
the gaskets comprise an elastomer, pliable material, O-Ring and/or
a combination thereof. In some embodiments, one or more of the
gaskets are formed by extrusion, casting, injection molding
(including reaction-injection molding), dye cutting and/or a
combination thereof. In some embodiments, at least one gasket is
mechanically coupled to the lid by adhesion (e.g. using adhesive
tape), clamping, screwing down, bonding, heat-staking, welding
(e.g. ultrasonically, by laser), fusing (e.g. using
solvent-assisted bonding), and/or a combination thereof.
[0146] For example, one of our present embodiments of the lid
includes a port (5) that allows pneumatic (e.g. vacuum) control of
(optional) chip stretching to be communicated through the lid (see
FIGS. 2A-2E). It is not intended that the lid be limited to
communicating only pneumatic pressure; it is contemplated that the
lid can communicate additionally fluidic or electrical
interfaces.
[0147] In one embodiment, the lid can include sensors. For example,
the lid may comprise a pressure sensor to determine, for example,
the pressure incident on one or more reservoirs. Further, the lid
may include liquid-level sensing to determine the amount of liquid
present in the reservoir or whether specific fill (or depletion)
thresholds have been passed. This can be done in a variety of ways.
In one embodiment, the detecting liquid optically using the
difference of refractive indexes is contemplated. In this
embodiment, air-filled compartments and channels disperse light,
while liquid or fluid-filled channels focus light. More
specifically, the refractive indexes of liquid are from 1.3 to 1.5
while that of air is only 1.0. In one embodiment, each optical
sensor consists of a matched pair of an IR emitter (SEP8736, 880
nm, Honeywell) and a phototransistor (SDP8436, 880 nm, Honeywell).
In this embodiment, IR is chosen over visible light for it is less
susceptible to interfering light.
[0148] The ability to easily remove fluids from the various
reservoirs (e.g. take sample, replenish media, add test agents,
etc.) is a desired feature. An especially desired feature is to be
able to use standard laboratory pipettes and syringes for such
operations. However, such fluidic access (especially using a
pipette) requires the accessed reservoir to be open to the
environment. This, in terms, is undesirable particularly when the
chip or disposable are in transit or in use outside of the
instrument, as the opening can provide a means for contamination of
the reservoir. A typical solution to this problem is to include a
lid that can be applied to one or more of the reservoirs when they
are not being accessed. However, including a simple lid can
complicate the use of the technology, since the user typically
would have to actively install and remove the lid, as well as
maintain lids near the instrument in a sterile way.
[0149] One solution is to include a means for automatically
removing and/or installing lids as part of the system (whether
integrated in the culture instrument or a separate module). For
example, the system can include a mechanical actuator that is
capable of engaging a lid installed on a disposed perfusion
disposable and removing it prior to engagement with the pressure
system. This mechanical actuator can re-install the lid upon
removal of the perfusion disposable. In an alternate embodiment,
the system includes a means for applying a lid to a perfusion
disposable prior to or upon removal, for example, with the lid
originating from a magazine of stored lids.
[0150] A shortcoming of the system with the means for automatically
removing and/or installing lids (discussed in the prior paragraph)
is that it requires one or more mechanical actuators whose
operation can be challenging in practice. Another challenge is the
following: the design of the reservoirs and in particular its
opening aims to satisfy the demands of liquid access (e.g. manual
sample taking or replenishing using a pipette), the pressure-driven
system (e.g. ensuring a good pressure seal against the instrument)
and manufacturing (e.g. injection-molding of the reservoirs). In
practice, these requirements can oppose each other. For example,
manual access may demand a broad reservoir opening; in contrast, it
may be desirable for the pressure interface to be narrower, to
reduce the force on the instrument.
[0151] A better solution disclosed herein is to include a "pressure
lid" (see FIGS. 2A, 2B, 2C and 2D). This pressure lid is a lid that
may be installed on to the reservoirs to reduce the likelihood of
contamination, and is designed to stay predominantly in place while
the perfusion disposable is engaged with the instrument. In order
to stay predominantly in place while engaged with the instrument,
the lid preferably includes a) one or more features designed to
interface with the instrument (e.g. to received positive or
negative pressure), b) one or more features designed to interface
with one or more reservoirs (e.g. create a pressure seal or
minimize gas leakage so that pressure can be applied to the
reservoir), and c) a means for pressure to be communicated from at
least some of the features (a) and at least some of the features
(b). The pressure lid or portions thereof may be transparent or
translucent. This can allow, for example, viewing liquid levels
within the reservoirs. The pressure lid may include markings that
indicate the nature or name of respective reservoirs.
[0152] In one embodiment of the pressure lid, the opening in the
pressure lid (e.g. on its top) may be smaller than the reservoir,
to reduce the surface area open for contamination and/or reduce the
area subject to a pressure seal. In another embodiment, the lid may
include a filter or a plurality of filters (38) to prevent solids
and particles from entering (see FIG. 2A). For example, the lid may
include a 0.2 um or 0.4 um filter known to reduce entry of bacteria
and other contaminants. Many materials and technologies can be used
for such filters. For example, track-etched filters (e.g. PTFE,
polycarbonate, PET), paper filters, porous and expanded materials
(e.g. cellulose and derivatives, polypropylene, etc.), sintered
materials (e.g. Porex filters) may be used since the filter need
only conduct pressure and not liquids.
[0153] In one embodiment, the lid may include a means for
permitting gas flow but predominantly no liquid flow. This can
include, for example, hydrophobic porous membranes or filters, gas
permeable membranes or filters, etc. This approach can also help
reduce the likelihood of spillage.
[0154] In one embodiment, the lid may include a deformable portion
that can deform to conduct pressure. For example, this can be an
elastic or plastic membrane that stretches into the reservoir as
positive pressure is applied. Similarly, the lid may include a
plunger used to transmit pressure from the instrument to one or
more reservoirs. Care must be taken to ensure that the desired
pressure is applied to the inside of the reservoir, as the membrane
or plunger can apply a back force. This can be done, for example,
by a) ensuring that the back force is small or understood through
design of the membrane, plunger or the operating pressure range, b)
measuring the pressure inside the reservoir and using it to control
the applied pressure, c) monitoring the resulting flow to control
the applied pressure. The deformable portion offers one way for
pressure to be communicated.
[0155] Either side of the pressure lid (instrument-facing or
perfusion disposable-facing) as well as each of the opposing
surfaces (instrument and perfusion-disposable features that
interact with the pressure lid) can be designed to enable a
pressure seal in a number of different ways. In one embodiment, the
present invention contemplates one or more regions comprising one
or more elastic or pliable materials. In one embodiment, this is
done with one or more gaskets (see FIG. 2A), which can be made for
example from elastomeric or pliable materials (e.g. silicone, SEBS,
polypropylene, Viton, rubber, etc.). The gaskets can be shaped in a
variety of ways, including cut flat sheets, o-rings (not
necessarily round in shape or cross-section), etc. In one
embodiment, this is done with one or more ridges that act as load
concentrators (see FIG. 2C). Without wishing to be bound by theory,
these act to localize the sealing force to create elevated
localized sealing pressure. These ridges may potentially engage a
gasket or pliable material on the opposing surface. Care must be
taken to design the shape of the ridge (particularly the portion of
the shape that engages the opposing surface), as this shape can
have a substantial effect on the required sealing pressure. A
variety of shapes are contemplated (e.g. rectangular, triangular,
trapezoidal, half-circular or circular section, etc.). In one
embodiment, the sealing tooth has a trapezoidal shape for improved
sealing (see FIG. 2C). Alternatively, the gasket could be
integrated into either the Reservoir or Lid in the faun of an
overmolded elastomer (e.g. silicone, SEBS, etc). This overmolded
elastomer could then, itself, have an appropriate shape to act as a
seal (e.g. a tooth or o-ring half-round section).
[0156] The approach need not be limited to a single design. In one
embodiment, the present invention contemplates a combination of one
or more regions comprising one or more elastic or pliable
materials. Moreover, gasketing or ridges can be done per-reservoir,
so that each is isolated in terms of applied pressure, or it can
encompass two or more reservoirs, which may reduce complexity. In
one embodiment (see FIG. 2D) the path encircles all chambers of the
reservoir chamber--cover assembly seal, so each chamber is isolated
from the other. In one embodiment (see FIG. 2D), there are two
reservoirs, each with an inlet chamber (6A, 6B) and an outlet
chamber (7A, 7B), and a separate (optional) vacuum chamber (8) that
allows for transfer of a vacuum to the chip or other microfluidic
device. In one embodiment (FIG. 2E), the reservoir chamber--cover
assembly seal comprises a sealing tooth (9).
[0157] It is not intended that the present invention be limited to
a design that has a perfect pressure seal, as this may not be
required. Rather, some amount of gas leakage can be tolerated,
since the instrument may actively regulate pressure, thereby
compensating for the leak. The relaxing of a requirement to obtain
a perfect seal on one or both sides can simplify design and reduce
costs.
[0158] The pressure lid can be affixed or rest upon the reservoirs
(whether on the perfusion disposable or directly on chip) in a
variety of different ways. Embodiments can involve instances
wherein the liquid or gas seal between the lid and reservoir(s) is
present even outside of the instrument (e.g. the lid is held
tightly in place by something other than the instrument), and
wherein the seal is created by action of the instrument (e.g. the
instrument presses the lid against the reservoirs during
perfusion). In another embodiment, the present invention
contemplates a combined approach, e.g. the lid is designed to
create at least a partial seal as in the first option above, but
the seal is approved or assured by action of the instrument as in
the second option above. An advantage of approaches that provide at
least some degree of sealing of the lid against the reservoir even
outside of the instrument is that they may reduce the risk of
spills and contamination (e.g. due to handling or transport).
[0159] Examples of approaches to affix or rest the pressure lid
(regardless of which of the above three approaches they fall under)
include a) where the lid can simply rest upon the reservoirs or
perfusion disposable (this can be aided by overhanding portions of
the lid, so that the lid cannot simply slide off); b) the lid can
be screwed, glued or pinned into place; and c) the lid can be
clipped into place. In an alternative embodiment, it could also be
held down by a spring, e.g. a hinged lid with a spring that forces
the lid closed.
[0160] Clip features may reside in the lid, the perfusion
disposable, chip or combination thereof. Furthermore, some
embodiments make use of a separate substrate that provides clipping
elements (i.e. a separate piece that one brings in to clip the lid
into place). An advantage of the clipping approach is that it can
facilitate easy application and removal of a lid while still
securing the lid in place. The clipping may be optional; for
example, it may be applied when shipping or transporting the device
and ignored during regular use.
[0161] In some embodiments, the lid is asymmetric or includes
lock-and-key features to ensure that the lid is correctly oriented
with respect to a perfusion disposable and/or an instrument.
[0162] Many of the features of the perfusion disposable (PD) could
potentially be included in the "chip" itself or a different device
for coupling to a chip. If the reservoirs, for example, are
included in the chip, one could use a pressure lid directly on top
of the chip.
[0163] While the pressure lid has been discussed above in
connection with the pressurization of one or more reservoirs within
a perfusion disposable or perfusion manifold assembly, it is not
intended that the pressure lid be limited by use with only these
embodiments. Indeed, it is contemplated that the pressure lid can
be used with other microfluidic devices. The pressure lid can be
movable or removably attached to other microfluidic devices to
allow improved access to elements (e.g. reservoirs) within. The
pressure lid can be removed from such other devices, and the other
devices can be used without the lid. In one embodiment, the other
microfluidic devices comprise cells on a membrane and/or in or on
one or more microchannels.
[0164] B. Tray System
[0165] It is desirable to be able to remove chips and/or perfusion
disposables from the instrument without having the remove the
instrument itself from, for example, an incubating enclosure. It is
also desirable to be able to remove groups of chips and/or
perfusion disposables together. This is because the operations that
are performed on the chips/disposables often need to be done in
batches at a time (e.g. media replenishing, dosing with an agent,
sample taking), regardless of whether the operations are performed
automatically or manually. For example, it is convenient to remove
groups of chips/disposables at a time if only to help transport
them to a bio-safety cabinet or culture hood.
[0166] To address these needs, the present invention contemplates,
in one embodiment, a system in which perfusion disposables can be
inserted or removed from an instrument (or module) in groups by
means of a tray system (see FIG. 6). For example, a current
embodiment allows each instrument to accept two trays (or racks) of
six perfusion-disposables each (8A and 8B).
[0167] In one embodiment, the tray (or rack) (32) may facilitate
the alignment of the perfusion disposables (10) with the instrument
(30) (e.g. aligning reservoirs or port locations with corresponding
pressure or fluid interfaces included in the instrument). This can
be done in a number of ways, including providing locating features
for the perfusion disposables (or any additional elements that
carry them) within the tray, and providing locating features for
the tray within the instrument and alignment features (57) for the
perfusion disposables (see FIG. 10B). Features that can be used to
support such alignment include reference surfaces, pins, guides,
shaped surfaces (e.g. fillets and/or chamfers), spring or elastic
elements to promote registration, etc. These may be included in the
tray, instrument, perfusions disposables or combinations
thereof.
[0168] The tray may optionally be designed to capture leaks
originating from the perfusion disposables or instrument
interfaces. The tray may optionally include one or more optical
windows that may facilitate microscopy or inspection. This can
enable placing a tray onto a microscope or other inspection device,
allow the chips to be observed without having to remove each
disposable from the tray. Correspondingly, the tray may be
optionally designed to minimize imaging working distance, e.g. lay
flat on or fit into a microscope stage, etc. The system may
optionally include a means for retaining one or more of the
perfusion disposable within the tray. For example, the perfusion
disposable may clip into the tray, with clip features present on
the perfusion disposable, tray, an additional substrate or
combinations thereof.
[0169] In some embodiments, the tray system includes one or more
sub-trays (or nests) (47) that fit into a carrier tray (32) (see
FIG. 8A). Sub-trays allow subsets of perfusion disposables (e.g.
three) to be removed from the tray simultaneously. This can be
useful, for example, where one or more operations performed on the
chips/disposables benefits from a smaller number of chips that are
present on the carrier tray. For example, in some instances, we
prefer to place no more than three disposable on a microscope stage
at one time, to minimize the time that the chips/disposables spend
outside of their preferred incubation and perfusion environments.
Consequently, a current embodiment includes carrier trays (32) that
support two sub-trays (47) each, each sub-tray supporting three
perfusion disposables (10) (see FIG. 8A).
[0170] The sub-trays may facilitate the alignment of the perfusion
disposables with the instrument. This can be done in a number of
ways, including by providing locating features for the perfusion
disposables within the tray, by providing locating features for the
sub-tray within the carrier tray, and by providing locating
features for the carrier tray within the instrument. Features that
can be used to support such alignment include reference surfaces,
pins, guides, shaped surfaces (e.g. fillets and/or chamfers), and
spring or elastic elements to promote registration, etc. These may
be included in the carrier tray, sub-tray, instrument, perfusions
disposables or combinations thereof. By way of an example, the
present invention contemplates an embodiment wherein the perfusion
disposables align to the sub-tray, which in turn aligns to the
carrier tray, which in turn aligns to the instrument (see FIGS. 9A
and 9B). It is not intended that all of these alignments or
necessary; indeed, some steps in this chain may be skipped. For
example, the sub-tray may align directly to the instrument using
any of the described features, and not requiring the carrier tray
for alignment purposes.
[0171] The sub-tray may optionally be designed to capture leaks
originating from the perfusion disposables or instrument
interfaces. The sub-tray may optionally include one or more optical
windows that may facilitate microscopy or inspection. This can
enable placing a sub-tray onto a microscope or other inspection
device, allow the chips to be observed without having to remove
each disposable from the tray. Correspondingly, the sub-tray may be
optionally designed to minimize imaging working distance, e.g. lay
flat on or fit into a microscope stage, etc. The system may
optionally include a means for retaining one or more of the
perfusion disposables within the sub-tray. For example, the
perfusion disposable may clip into the sub-tray, with clip features
present on the perfusion disposable, sub-tray, an additional
substrate or combinations thereof. The system may optionally
include a means for retaining the sub-tray within the carrier tray.
For example, the sub-tray may clip into the carrier tray, with clip
features present on the sub-tray, carrier tray, an additional
substrate, or combinations thereof.
[0172] It may be convenient to divide some of the desired features
between the carrier tray and the one or more sub-trays. For
example, the sub-trays can provide an optical window and the
carrier tray can be designed to capture leaks. As this example
illustrates, it may be desired to include a sub-tray even if the
carrier tray is designed to support only one sub-tray.
[0173] The same instrument may support different tray or sub-tray
types, as well as different numbers of trays. For example, an
instrument may accept two different tray types, each tray type
designed for a different type of perfusion disposable. In such a
case, the tray can in essence act as an adaptor that adapts the
different perfusion-disposable types to the same instrument.
[0174] The present invention also contemplates in one embodiment,
microscope stages, stage-inserts or adapters (e.g. that plug into
the stage inserts) designed to accept one or more chips, perfusion
disposables, trays or sub-trays. These can make it easy to "drop
in" a number of chips for imaging, with the chips securely retained
on the stage (thereby avoiding drift, for example, as the
microscope stage moves).
[0175] C. Engaging Perfusion Disposables With the Instrument
[0176] In one embodiment, the present invention contemplates a
pressure-driven system for the biological culture in fluidic
devices, which applies pressure (whether positive or negative) to
one or more fluidic elements. These fluidic elements can include,
for example, chips, reservoirs, perfusion disposables, pressure
lids or combinations thereof. In such system, the instrument
interfaces with the respective fluidic element or elements in order
to apply the pressure where desired. Such interfacing typically
involves establishing a gas seal, although in some embodiments a
tight seal is not required (e.g. the pressure-regulation can
maintain the desired pressure despite gas leak). Without loss of
generality, the following description refers to establishing a
seal, but the intent is to also encompass embodiments that do not
require a seal.
[0177] In the present disclosure, a system and method are
contemplated for establishing a pressure interface between a
biological culture instrument and one or more fluidic elements. In
particular, a system is contemplated wherein, in one embodiment,
the one or more fluidic elements are lifted into contact with one
or more pressure manifolds included in the instrument, the said one
or more pressure manifolds are lowered into contact with the said
one or more fluidic elements, or a combination thereof. In some
embodiments, the said raising or lowering engages multiple fluidic
elements with the instrument in unison (e.g. through a single
operation or single movement) (see FIGS. 9A and 9B), simultaneously
linking a plurality of microfluidic devices (such as one or more of
the embodiments of the perfusion manifold assembly discussed
herein).
[0178] Some embodiments wherein the fluidic elements are raised
include one or more platforms onto which one or more of the fluidic
elements are disposed. In such embodiments, one or more of the
platforms may be raised in order to affect the said raising of the
one or more fluidic elements (FIG. 6). In some embodiments, the
instrument or system includes a mechanical means (35) for manually
achieving the said raising or lowering involved in the said
establishing of a pressure interface. Such mechanical means (35)
for manual actuation can include the moving of a user-accessible
control surface, which may include, for example, a level, pull/push
knob, rotational control, or combinations thereof.
[0179] In some embodiments, the instrument or system includes a
mechanical actuator (51) in order to facilitate the raising or
lowering involved in the said establishing of a pressure interface
(See FIGS. 9A and 9B). Such mechanical actuator can involve, for
example, one or more pneumatic components (52) (e.g. cylinders),
hydraulic components (e.g. cylinders), solenoids, electrical
motors, magnets (e.g. fixed magnets mechanically moved into place),
or combinations thereof. In some embodiments, the mechanical
actuation can be under computer control. In some embodiments, the
mechanical actuation is augmented with manual control (e.g. using
any of the means for mechanical control described above), for
example, in order to provide a manual override. A user interface on
the instrument can control this process.
[0180] Regardless of whether the actuation is manual or automatic,
the system can, in some embodiments, further include one or more
mechanisms for increasing the applied mechanical force. This may be
desirable in order to provide sufficient force on the pressure
interface in order to obtain a sufficient or sufficiently robust
seal. Such mechanisms for increasing the applied mechanical force
can include levers, cams, pneumatic or hydraulic amplifiers, or
combinations thereof.
[0181] In some embodiments, the mechanical motion can be controlled
and or constrained using various mechanical components or designs
known in the art. These mechanical components or designs include,
for example, rails, guide rots, pivots, cams, four-bar linkages,
etc. It is important to note that the raising or lowering motion
can, but need not, be linear. For example, a rotational motion
(e.g. in the case of a pivot) or a compound motion (e.g. in the
case of a linkage) are desirable in some embodiments.
[0182] Although the forgoing describes raising or lowering and
features present on the top of bottom of various substrates, one
with typical skill in the art would appreciate that the description
can also be applied to lateral motions or motions along other axes
(and not necessarily linear motions), and to features present on
any sides or orientations. Additionally, although the forgoing
implies that the one or more fluidic elements are disposed beneath
the one or more pressure manifolds, one with typical skill in the
art would appreciate that the said pressure manifolds may instead
lie beneath the said fluidic elements (for example, the pressure
interfaces may be disposed on the bottom surface of a perfusion
disposable).
[0183] A current embodiment (illustrated in the attached figures)
includes two mechanics, each of which permits 6 perfusion
disposables to be interfaced with a pressure manifold (50) in a
single motion. In this embodiment, the pressure manifolds are
lowered (FIG. 9B) into contact with the perfusion disposables (or
optionally in contact with pressure lids covering the perfusion
disposables) using an electrically controlled pneumatic actuator.
The force of the actuator is directed using a cam system, which
also increases the applied force due to its mechanical advantage.
The illustrated mechanism is also bi-stable, i.e. once the actuator
pushes the manifold up or down it can be unpowered, while
maintaining the position of the manifold. This can help with heat
reduction.
[0184] D. Pressure Manifolds and Distribution Manifolds
[0185] In many applications of the pressure-driven system, it is
desirable to distribute one or more pressure sources to two or more
fluidic elements (including, for example, fluidic chips, perfusion
disposables, reservoirs, pressure lids, or combinations thereof).
For example, it may be desirable for two or more perfusion
disposables to share a single set of pressure regulators in order
to reduce the number of regulators in the system (e.g. in contrast
with providing a different set of regulators for each perfusion
disposable).
[0186] In one aspect of the present disclosure, the instrument
includes one or more distribution manifolds. The said distribution
manifolds includes one or more fluidic conduit (e.g. gas channels
or tubes) adapted to distribute one or more pressure sources to two
or more fluidic elements (e.g fluidic chips, perfusion disposables,
reservoirs, pressure lids, or combination thereof).
Correspondingly, the distribution manifold may include one or more
pressure input ports, which may for example be adapted to
communicate with one or more pressure regulators (each input port
may communicate with a single or multiple regulators). The
distribution manifold, in one embodiment, can also have pressure
regulation components (valves, pressure sensors, pressure source)
integrated into the manifold itself. Similarly, the distribution
manifold may include two or more interfaces, which may for example
be adapted to communicate with one or more fluidic elements. In
some embodiments, the two or more interfaces include at least one
region comprising an elastomeric or pliable material. Examples
include gaskets, o-rings, etc. made of materials including
silicone, SEBS, polypropylene, rubber, Viton, etc. Such regions
comprising an elastomeric or pliable region can aid in providing or
improving a fluidic seal. Such elastomeric or pliable regions can
also be included in pressure manifolds that are not distribution
manifolds to provide similar advantages.
[0187] In addition to distributing pressure that can be used, for
example, to produce pressure-driven flow, the distribution manifold
may distribute pressure used for other purposes, for example, to
produce mechanical strain or compression (e.g. in actuating
mechanical forces in organs-on-chips), to create gas flow within
the fluidic element. Moreover, the distribution manifold may
optionally distribute one or more liquids. Such liquids can
include, for example, wash solutions, disinfectant solutions,
working liquids (e.g. for liquid-handling or flow control
purposes), tissue-culture media, test agents or compound,
biological samples (e.g. blood), or combinations thereof. In some
embodiments, the distribution manifold may comprise a working
fluid, a membrane and/or a plunger disposed to conduct pressure.
For example, a working fluid may be used to reduce the amount of
gas required in order to establish a desired pressure, or to
facilitate more precise volumetric control. A membrane, plunger
and/or working fluid can be used to isolate fluids used in
different parts of the distribution manifold (e.g. isolate 5% CO2
tissue-culture gas on the "reservoir side" of the distribution
manifold from dry air on the actuation side).
[0188] In many applications, it is desirable to enable proper
function of the instrument even when fewer fluidic elements are
engaged than the instrument can accept. For example, it is often
desirable that an instrument that includes a distribution manifold
designed to interface with six perfusion disposables still support
proper operation of the instrument when only four perfusion
disposable are present. For example, it may be undesirable to gas
to escape through the interfaces intended for the missing perfusion
disposables, as such gas escape may reduce gas pressure or deplete
gas supplies. Such considerations are relevant even without a
distribution manifold (i.e. with a non-distributing pressure
manifold).
[0189] According to one aspect of the present disclosure, a
pressure manifold (or specifically a distribution manifold) can
include one or more valves adapted to controllably shut-off one or
more of the fluidic (e.g. gas) conduits included in the manifold. A
variety of valves suitable are known in the art, including for
example pinch valves, screw valve, needle valve, ball valves,
spring-loaded valves, poppet valves, umbrella valves, Belleville
valves, etc. In some embodiments, one or more of the valves are
controlled by a user. For example, a user may configure the valves
to match the configuration of perfusion disposables in use. In some
embodiments, one or more of the valves are controlled
electronically. For example, software may configure the valves
according to knowledge of experimental settings or other
information available to it. In some embodiments, one or more of
the valves are controlled by sensing whether the intended fluidic
element is present, for example, in order to shut off a gas line if
the fluidic element is missing. Such sensing can involve electrical
means (e.g. contact switches, conductors closing circuits), optical
means (e.g. optical gates), magnetic means (e.g. magnetic
switches), or mechanical means (e.g. levers, buttons). In some
embodiments, one or more of the sensing elements affects one or
more of the valves by means of interposed software or electronic
hardware. In some embodiments, one or more of the sensing elements
affects one or more of the valves directly (e.g. by mechanical
coupling or by electrically signaling to the valve). As a specific
example, the presence of a perfusion disposable can act to depress
a protruding feature, which in turn affects the state of a valve.
In some embodiments, such configuration lends itself well, for
example, to pinch valves, spring valves, poppet valves, or umbrella
valves, as the depressed protruding feature can act directly on the
valve to augment flow.
[0190] In some embodiments, it is desirable or convenient to
include the said one or more valves at one or more of the
interfaces to the fluidic elements. This may be desirable, for
example, since a number of successful valve designs are known that
respond to a force present at their outlets. Examples of such
valves include Schrader valves, Dunlop valves, Presta valves,
umbrella valves, their modifications, and related valves. As a
specific example, a Schrader valve may be integrated at an
interface to a pressure lid such that when the pressure lid is
present, it acts to depress the central stem of the Schrader valve,
thereby allowing gas flow.
[0191] Valves suitable for inclusion in the interfaces to the
fluidic element as described above often have their control feature
(e.g. the pin of a Schrader valve) (FIG. 11A) located in the middle
of the valve. This, however, can pose a difficulty in some
potential embodiments, since a corresponding feature must be
provided on the fluidic element to depress such a central control
feature. An alternative approach is described herein. As
illustrated in FIGS. 11A and 11D, the pressure manifold (50) or
distribution can manifold can include a valve (59) such as a
Schrader valve (or any listed above) and further include a shuttle
(61). The said shuttle includes a first surface that faces the
location of a potential fluidic element, and a second surface that
faces the said valve. The first surface is designed to accept
contact from the fluidic element at the desired location. For
example, the first surface can be designed to accept contact from
the periphery of a port that may be present on, e.g., a pressure
lid (11) (FIG. 11D). The second surface, in term, is design to
mechanically engage the said valve's control surface, which may for
example lie in the center of the valve. A further advantage of this
approach is that the thickness of the shuttle can be adjusted, for
example, to control at what distance from the fluidic element the
valve will open.
[0192] As further illustrated in the FIGS. 11A and 11C, the
interface can be optionally covered at least in part by an elastic,
pliable or deformable substrate, such as a pliable membrane (e.g.
silicone membrane) (60). The presence of this elastic, pliable or
deformable substrate can aid in the sealing of the fluidic element
against the manifold (50). The elastic, pliable or deformable
substrate can, for example, be a membrane, a gasket or a suitably
shaped plug, and it may comprise, for example, silicone, SEBS,
Viton, polypropylene, rubber, PTFE, etc. As illustrated, the
elastic, pliable or deformable substrate can be held in place by
capturing it with an additional component (e.g. a cover plate (63)
in this example). However, the elastic, pliable or deformable
substrate can also be retained in a variety of other ways,
including for example by bonding, adhesion, welding, etc.
[0193] The desired function of the embodiments illustrated in FIGS.
9B, 11A and 11D are hereby illustrated by example: a pressure lid
(11) of a perfusion manifold assembly (10) possessing a ridge
around its instrument interface is brought into contact with the
pressure manifold (50). As the lid is moved closer to the valve,
the lid's ridge begins forming a pressure seal against the
manifold's silicone membrane. With the lid's advance, the shuttle
gradually moves up and at some point begins depressing the central
pin or poppet (65) of the Schrader valve (59). However, according
to the example, the shuttle would be designed such that a
sufficiently good gas seal is formed before the valve's pin is
depressed enough to open the Schrader valve (59). Once the valve
open (and ideally not before) gas is able to flow between the
manifold (50) and pressure lid (11). It is important to note that
in this example, Schrader valves sense the presence of each
pressure-lid ridge independently, rather than sensing the presence
of a perfusion disposable (or pressure lid) as a single unit. Such
embodiments may provide a further advantage in that they may accept
different configurations of pressure lids or perfusion disposables,
for example, a configuration that employs only 4 of the 5
illustrated ports.
[0194] FIG. 10A illustrates one embodiment of the PD engaging face
(54) of a pressure manifold (50) that is a distribution manifold
and shows elastomeric regions, which act as gaskets to improve gas
seal against the fluidic element. In a current embodiment, a gas
seal can be formed by compressing these elastomeric regions against
ridges present on the top of pressure lids (11), which are in turn
disposed onto perfusion disposables (10). The illustrated
distribution manifold (50) can distribute to each of six pressure
lids pressure (positive or negative) used for enact pressure-driven
flow as well as pressure (positive or negative) used to actuate
mechanical stretch within the included organ-on-chip devices (in
this example, each of these is disposed within a perfusion
disposable, which is in turn covered with a pressure lid). The
illustrated distribution manifold includes several Schrader-like
valves (see FIG. 11D).
[0195] As the manifold engages the PDs, the valve seals engage the
sealing teeth or ridges on the top of the cover (see FIG. 2C)
forming a seal for transferring pressurized gas from the manifold
into the reservoir chambers. The poppet (65) (FIG. 11D) acts as a
backing to provide a rigid surface for the sealing tooth on the
cover to compress the valve seal. This provides load transfer from
the cover to the Schrader valve (59) to actuate it when a PD is in
position. Simultaneously, the Schrader Valve (or similar type valve
system) is actuated by the engagement to the PD Cover to all gas
flow from the pressure regulator into the PD. When no PD is in the
respective position, the valve prevents any gas flow.
[0196] The spring shuttle (55) (FIG. 10B) provides the load to the
cover assembly (11) to create the reservoir chamber-cover assembly
seals (e.g. pressure lid-to-reservoir seals) (FIG. 2D). In
operation, there is a deflection of the valve seal and the
displacement of the poppet (65) when the PD is engaged.
[0197] Alternatively, a lid compressor (FIG. 10C) provides the load
to the cover assembly to create the reservoir chamber-cover
assembly seals (e.g. pressure lid-to-reservoir seals).
[0198] In one embodiment, each valve assembly has an optional
spring, flexure or elastic component built in that allows for
pressure to be applied to each seal independently. In one
embodiment, the spring (or similar element) is an integral part of
the valve function, but one can get additional function out of it
by using it to apply pressure to the sealing tooth on the reservoir
lid. The spring (or similar element) can work to restore the
shuttle and to apply pressure against the fluidic element to
provide or improve the gas seal. Independently applying this load
to each sealing element on the lid results in a design that is more
robust both to variations due to manufacturing tolerances, and how
many PDs happen to be loaded into the instrument.
[0199] In some embodiments, one or more of the described valves are
controlled by software or a user. For example, the user or software
may aim to disconnect gas flow even if a fluidic element (e.g.
perfusion disposable) is present at the corresponding interface.
This could be desired, for example, if the user suspects or the
software or sensor detects that there is excess gas flow to the
fluidic element, perhaps because the element is damaged. The
pressure manifold (whether a distribution manifold or not) may
further include sensors, for example, pressure sensors, flow
sensors, etc.
[0200] E. Controlling Pressure and Flow
[0201] In one embodiment, a flow rate of between 5 and 200 uL/hr,
and more preferably between 10 and 60 uL/hr, is desired through the
one or more microchannels of the device. In one embodiment, this
flow rate is controlled by the applied gas pressure from the
pressure manifold (described above). For example, when one applies
between 0.5 and 1 kPa, this nominal pressure results, in one
embodiment, in a flow rate of between 15 uL/hr and 30 uL/hr.
[0202] In addition to maintaining control over this gas pressure
over time (and thereby maintain control over flow), in some
embodiments, one must also address the gas pressure that may be
applied by the process of engaging or disengaging the manifold
against the perfusion disposable. That is to say, it is been
observed, in a particular embodiment, that the step of engaging the
manifold results in a pressure spike of as much as 100 kPa on the
gas present within a reservoir included in the perfusion
disposable. This can cause a spike in the flow rate and/or an
undesired pressure on a coupled microfluidic device. In the
particular case wherein the coupled microfluidic device comprises a
membrane, an undesired pressure spike may deform the membrane,
create trans-membrane flow and/or damage any included cells.
[0203] Without being bound by theory, the described pressure spikes
can be caused because the mechanical force applied by the manifold
to the pressure lid deforms one or more compliant materials
included in the pressure lid or perfusion disposable (e.g.
compressing any gaskets and the like). Such deformation can act to
shrink the volume of gas present in the reservoir, increasing its
pressure. The opposite effect leading to a negative spike in
pressure may occur during manifold disengagement; one skilled in
the art will appreciate that while this discussion primarily
contemplates positive spikes that are typical to manifold
engagement, analogous consideration may be given to negative
pressure spikes that may be typical during manifold disengagement.
Whether positive or negative, spikes can be particularly
troublesome where the gas volume in the reservoir is low, which may
occur when the volume of liquid in a reservoir is high (for
example, in the preferred embodiment when more than 3 milliliters,
and particularly when the volume is more than 5 milliliters). These
engagement spikes may take time to dissipate, as the excess
pressure must typically vent. In embodiments wherein the pressure
lid includes a filter, this filter may provide the dominant
resistance to the venting, dictating the dynamics of pressure-spike
dissipation. In one embodiment, the present invention contemplates
reducing the venting resistance in the system so as to avoid,
reduce the magnitude and/or reduce the duration of such spikes. In
on embodiment, the present invention contemplates selecting filters
in order to mitigate the pressure spikes during cartridge insertion
and removal.
[0204] In this regard, reference is made to FIGS. 2A-2E-2. FIG. 2A
is an exploded view of one embodiment of the cover assembly (11)
comprising a cover or lid having a plurality of ports (e.g.
through-hole ports) associated with filters (38) and corresponding
holes (39) in a gasket. FIG. 2B shows the same embodiment of the
cover assembly with the filters (38) and gasket positioned within
(and under) the cover. In one embodiment, the filters for the
outlet pressure ports are selected for low gas-flow resistance. For
example, some embodiments employ 25 micron filters instead of 0.2
micron filters (used in the inlet pressure ports), in order to
decrease resistance and cause the manifold-engagement related gas
pressure (discussed above) to rapidly dissipate, avoiding a
prolonged spike in the flow rate. In particular embodiments,
filters with an average pore size of 25 um (commercially available
from Porex, filter 4901) do not compromise sterility when 1/8 inch
in thickness. These filters maintain sterility, despite their
larger pore size (much larger than typical bacteria/spores), by
creating a tortuous path through their thickness, which is
significantly thicker than the previously mentioned filter
membrane/sheets.
[0205] It is important to note that the design of inlet and outlet
pressure ports may demand different treatment with regards to the
venting resistance. For example, in embodiments wherein the
perfusion disposable or microfluidic device comprise a resistor,
pressure applied on the resistor side (whether the resister is
placed upstream or downstream of a region of interest) typically
does not act directly on the region of interest (which may, for
example, include cells). This can be the case, for example, if
liquid flow through the resistor generates a pressure drop. In
contrast, pressure spikes on a side without the resistor (whether
inlet or outlet) may act directly on the region of interest, as
there may not be a sufficient pressure drop to provide some degree
of insulation. In a particular example with a resistor on the inlet
side of the region of interest, a pressure spike on the inlet may
produce a corresponding spike in flow rate but minimal increase in
the pressure experienced within the region of interest; in
contrast, a pressure spike on the outlet may produce both a spike
in flow rate and in experienced pressure. In some applications, for
example where the microfluidic device includes a membrane,
pressures in the regions of interest may be significantly more
detrimental than a temporary spike in flow rate. Accordingly, in
this example it may be advisable to include low-resistance filters
only in the outlet ports and include more typical (higher
resistance) filters in the inlet ports, as these can provide
advantages in flow regulation (discussed further in the present
disclosure).
[0206] Having discussed the engagement/disengagement spike issue,
the issue of controlling gas pressure, particularly in low pressure
ranges is now addressed. Some commercially available pressure
regulators (or pressure controllers) advertise an addressable
pressure range with a lower pressure limit that is greater than
zero. For example the SMC ITV-0011 regulators are marketed for
pressure control in the range of 1 to 100 kPa (it has been observed
that their linearity is poor in the 0 to 1 kPa range). In some
applications, it may be desirable to nevertheless attain flow rates
that correspond to pressures below the commercially available
regulator's specified or linear range. Moreover, the accuracy of
commercially available pressure regulators is typically a
percentage of "full range," implying that control at the low end of
pressure is characterized by a larger percentage of variability. In
some applications this can translate into low accuracy or fidelity
in pressure control towards the lower end of the usable range. In
one embodiment, either or both of these challenges are addressed by
a form of "pulse width modulation" included in a method for
pressure actuation.
[0207] In this regard, reference is made to FIG. 6. In one
embodiment, the culture module (30) comprises a removable tray (32)
for positioning the assembly-chip combinations, a pressure surface
(33), and pressure controllers (34). In one embodiment, the tray
(32) is positioned on the culture module (30) and the tray (32) is
moved up via a tray mechanism (35) to engage the pressure surface
(33) of the culture module, i.e. the cover or lid (11) of the
perfusion manifold assembly engages the pressure surface of the
culture module. Rather than having the pressure controllers "on"
all of the time, they are switched "on" and "off" (or between two
or more setpoints) in a pattern. Accordingly, the switching pattern
may be selected such that the average value of pressure acting
liquid in one or more reservoirs corresponds to a desired value.
Such approaches are analogous to the techniques of pulse-width
modulation (PWM), pulse-density modulation (PDM), delta-sigma
modulation (DSM) and similar techniques that are known in the field
of electrical engineering. In the case of pulse-width modulation,
for example, a regular switching period is selected. Within each
period the pressure regular may be turned on for a set pressure for
a desired duration and turned off for the remainder of the
switching period. The longer the switch is on compared to the off
periods, the higher the total average pressure supplied. The term
"duty cycle" describes the proportion of "on" time to switching
period; a low duty cycle corresponds to low pressure, because the
pressure is off for most of the time. Duty cycle is expressed in
percent, 100% being fully "on." By using this type of "pulse width
modulation" with the pressure controllers, it has been found that
the average gas pressure can be reliably maintained below 1 kPa,
using a regulator that does not offer linear control in that range.
In a particular embodiment, the pressure regulator is used in its
typical "linear" mode for pressure between 1 kPa and 100 kPa, and
switched to pulse-width modulation using an "on pressure" of 2 kPa
and an "off pressure" of 0 kPa for average-pressure setpoints
between 0 kPa and 1 kPa. In other examples, pulse-width,
pulse-density or delta-sigma modulation may be used for controlling
the average pressure between 0.3 and 0.8 kPa.
[0208] Although the disclosed method can involve applying a
pulsatile pressure pattern to the pressure lid, it has been
empirically found that the filters aid in smoothing the pressure
incident on the liquid with the reservoir. Without being bound by
theory, the degree of smoothing increases with the resistance of
the filter to gas flow and with the volume of gas within the
reservoir (which typically decreases the more liquid is present).
Similarly, analogy to electrical circuits indicates that smoothing
increases with shorter switching periods. Accordingly, one skilled
in the art may select a degree of smoothing by selecting the
resistance of the gas filter, setting a lower bound on the gas
volume, and selecting a switching period or modulation pattern. It
is important to ensure that the pressure regulator is able to
controllably regulate pressure at a sufficient rate to reproduce
the designed pressure modulation pattern. In some embodiments, 0.2
um filters (Porex filter membrane) and a switching period of 10
seconds provide desired smoothing. In other embodiments, 0.4 um
filters may be used.
Detailed Description of the Preferred Embodiments
[0209] A. Drop-to-Drop Connections
[0210] A drop-to-drop connection scheme is contemplated as one
embodiment for putting a microfluidic device in fluidic
communication with another microfluidic device, including but not
limited to, putting a microfluidic device in fluidic communication
with the perfusion manifold assembly. Putting devices in fluidic
communication with each other can result in the formation of
bubbles (40), as shown in FIGS. 14A and 14B, where a first surface
(87) comprising a first fluidic port (89) is aligned with a second
surface (88) and a second fluidic port (90). In one embodiment, a
drop-to-drop connection is used to reduce the chance of bubbles
becoming trapped during connection. Air bubbles are particularly
challenging in microfluidic geometries because they get pinned to
surfaces and are hard to flush away with just fluid flow. They pose
additional challenges in cell culture devices because they can
damage cells through various means.
[0211] In one embodiment, droplets are formed on the surfaces of
the devices in the areas around and on top of the fluidic vias or
ports as shown in FIGS. 15A, 16A, 16B, 16D and 17-21. When the
surfaces come near each other during a connection, the droplet
surfaces join without introducing any air bubbles. In practice,
maintaining alignment and stability of the droplets during manual
device manipulation is challenging. Additionally, in situations
where the Bond number is high liquid tends to drain from devices
quickly and in an unstable manner. A number of solutions are herein
described to address the problems of both maintaining a stable
droplet on a device surface and guiding the drop-to-drop engagement
of two primed devices in a controlled and robust manner.
[0212] FIG. 16A shows one embodiment for bringing a microfluidic
device into contact with a fluid source or another microfluidic
device, wherein the microfluidic device approaches from the side so
as to engage a side track with a portion configured to fit into
said side track. FIG. 16B shows one embodiment for bringing a
microfluidic device into contact with a fluid source or another
microfluidic device, wherein the microfluidic device approaches
from the side and underneath so as to engage a side track with a
portion configured to fit into said side track, the side track
comprising an initial linear portion and a subsequent angled
portion, resulting in both a sideways and upward movement of the
microfluidic device when engaging and traversing the side track, so
as to cause a drop-to-drop connection establishing fluidic
communication (FIG. 16C). FIG. 16D shows yet another approach for
bringing a microfluidic device into contact with a fluid source or
another microfluidic device, wherein the microfluidic device pivots
on a hinge, joint, socket or other pivot point on the fluid source
or other microfluidic device (with an arrow showing the general
direction of movement).
[0213] FIG. 17 is a schematic showing a confined droplet (22) on
the surface (21) of a microfluidic device (16) in the via or port,
wherein the droplet covers the mouth of the port and protrudes
above the port, and where the port is in fluidic communication with
a microchannel.
[0214] FIG. 18 is a schematic showing a confined droplet (22) above
the surface (21) of a microfluidic device (16) in the area of the
via or port, wherein the droplet sits on a molded-in pedestal or
mount (42) and covers the mouth of the port and protrudes above the
port, and where the port is in fluidic communication with a
microchannel.
[0215] FIG. 19 is a schematic showing a confined droplet (22) above
the surface (21) of a microfluidic device (16) in the area of the
via or port, wherein the droplet sits on a gasket (43), covers the
mouth of the port, and protrudes above the port, and where the port
is in fluidic communication with a microchannel.
[0216] FIG. 20 is a schematic showing a confined droplet (22), a
portion of the droplet positioned below the surface (21) of a
microfluidic device (16) in the area of the via or port, wherein
the droplet sits on a molded-in depression or recess (44) and
covers the mouth of the port, with a portion protruding above the
surface, and where the port is in fluidic communication with a
microchannel
[0217] FIG. 21 is a schematic showing a confined droplet (22), a
portion of the droplet positioned below the surface (21) of a
microfluidic device (16) in the area of the via or port, wherein
the droplet sits in a surrounding gasket and covers the mouth of
the port, with a portion protruding above the gasket.
[0218] FIGS. 22A-22B is a schematic showing a surface modification
embodiment employing stickers for confining droplets on the surface
of a microfluidic device (16) at a port, and where the port is in
fluidic communication with a microchannel. FIG. 22A employs a
hydrophilic adhesive layer or sticker (45) upon which the droplet
(22) spreads out to the edges of the sticker, constrained by a
surrounding hydrophobic surface. FIG. 22B shows a droplet (22)
spreading out on a hydrophilic surface of the device, constrained
by a surrounding hydrophobic surface (45) created by one or more
adhesive layers or stickers on each side of the port, and where the
port is in fluidic communication with a microchannel.
[0219] FIG. 23 is a schematic showing a surface modification
embodiment employing surface treatment (e.g. chemical vapor
deposition, plasma oxidation, Corona, etc.--indicated by downward
projecting arrows) in conjunction with a mask (41); in one
embodiment, the microfluidic device (16) is made of a naturally
hydrophobic material which becomes hydrophilic upon such surface
treatment where there is no mask, but remains hydrophobic where
there is a mask. After the surface treatment, the mask can be
removed and the channel can be filled with fluid so as to generate
a droplet protruding above the surface, but constrained by the
regions that remained hydrophobic (see FIG. 17).
[0220] FIGS. 24A-24D is a schematic of one embodiment of a
drop-to-drop connection scheme whereby a combination of geometric
shapes and surface treatments are used to control the droplet. FIG.
24A shows an embodiment of the microfluidic device or "chip"
comprising a fluid channel and ports, having an elevated region at
each port (e.g. a pedestal or gasket). When other portions of the
device (i.e. portions other than the pedestal or gasket) are
treated (e.g. plasma treatment) to make them hydrophilic, the
naturally hydrophobic pedestal or gasket can be protected with a
mask (shown in FIG. 24A on top of the pedestal or gasket as element
41) during plasma treatment to keep it from becoming hydrophilic.
After plasma treatment, the mask is removed (e.g. peeled off the
surface of the pedestal or gasket). FIG. 24B shows the hydrophilic
channel filled with fluid where the droplet radius is balanced at
each end (i.e. at the port openings); the droplet (22) is
constrained by the hydrophobic gasket surface. FIG. 24C shows one
portion of the microfluidic device of FIG. 24B with an upward
projecting droplet (22) approaching (but not yet in contact with)
one portion of the mating surface of the perfusion manifold
assembly, which also has a projecting droplet (in this case, the
droplet (23) is projecting downward). FIG. 24D shows the same
portion of the microfluidic device of FIG. 24C with the upward
projecting droplet (22) of the microfluidic device making contact
with (and merging with) the downwardly projecting droplet (23) of
the perfusion manifold assembly. The droplets coalesce in a
controlled manner when they are on hydrophilic surfaces but
constrained by hydrophobic surfaces. As noted previously,
embodiments where the microfluidic device approaches from above
(with a downwardly projecting droplet) the perfusion manifold
assembly (with an upwardly projecting droplet) are also
contemplated.
[0221] FIGS. 25A-25B shows an embodiment of drop-to-drop connecting
using surface treatments alone (i.e. without geometric shapes such
as pedestals or gaskets). FIG. 25A shows an embodiment of the
perfusion manifold assembly comprising a fluid channel and a port.
When other portions of the naturally hydrophobic mating surface
(i.e. portions other than the region around the port) are treated
(e.g. plasma treatment) to make them hydrophilic, the region around
the port protected with a mask (shown in FIG. 25A as element 41
covering the port and a small region of the mating surface around
the port) during plasma treatment to keep it from becoming
hydrophilic After plasma treatment, the mask is removed (e.g.
peeled off the mating surface around the port). FIG. 25B shows the
hydrophilic channel filled with fluid to a level (e.g. height of
the column of fluid). In some embodiments, the formed droplet is
able to resist the pressure (gravitational head) exerted by the
fluid volume. This is advantageous, as it can enable drop-to-drop
connection while minimizing the dripping of the top droplet and
stabilizing its size. Without being bound by theory, the drop
resists the exerted pressure of the fluid volume because that
pressure is balanced out by the surface tension of the droplet;
this surface tension is determined in part by the droplet radius,
which in turn can be controlled using designs and methods disclosed
herein; for example, when the droplet is constrained by the
hydrophobic region around the port, the radius of its surface is
similarly constrained.
[0222] FIG. 26 is a chart showing (without being bound by theory)
the relationship between the port diameter (in millimeters) and the
maximum hydrostatic head (in millimeters) that the stabilized
droplet can support, assuming that the fluid has the same surface
tension as water (the model does not include the reservoir
meniscus). This shows that one can work with a variety of port
diameters, selecting those that can support substantial volumes of
the water column in the channel (and in general support substantial
back pressures), thereby providing a significant process window and
tolerance for user manipulation. In yet another embodiment, by
adjusting the pressure on the fluid, a projecting or protruding
droplet of a desired size is achieved.
[0223] It is not intended that the present invention be limited to
a particular method for controlling the droplet size, orientation,
or direction. In one embodiment, the present invention contemplates
using (or making) engineered surfaces to form stable drops. Such
surfaces can be inherently hydrophilic or hydrophobic, or can be
treated to be hydrophilic or hydrophobic. It is not intended that
the present invention be limited to any one technique. However,
among the various methods of hydrophilic treatment (e.g.
low-pressure oxygen plasma treatment, corona treatment, etc.), a
cleaner technology is preferred to treat Poly(dimethylsiloxane)
(PDMS) microfluidic devices. In one embodiment, the present
invention contemplates using atmospheric RF plasma, so that
hydrophilic surfaces can be created (on what is normally
hydrophobic material). See Hong et al., "Hydrophilic Surface
Modification of PDMS Using Atmospheric RF Plasma," Journal of
Physics: Conference Series 34 (2006) 656-661 (Institute of Physics
Publishing). In one embodiment, masks (41) are used together with
such plasma treatments, as shown in FIG. 23. For example, a mask
can be adhered to regions of the surface (e.g. made of PDMS or
other polymer) of the microfluidic device (16) prior to plasma
treatment in order to prevent such regions from becoming
hydrophilic (and thereby controlling what part of the PDMS chip
become hydrophilic and what portions remain hydrophobic). After
plasma treatment, the mask (41) can be removed (FIGS. 24A-24D)
(typically by simply peeling the mask off the surface). In yet
another embodiment, the present invention contemplates the use of
plasma surface treatment in a fluorinated environment to increase
the hydrophobicity of the surface. See Avram et al., "Plasma
Surface Modification for Selective Hydrophobic Control," Romanian
J. Information Science and Technology, Vol. 11, Number 4, 2008,
409-422.
[0224] Alternatively, such surfaces can have geometric features or
shapes that cause the droplet to form or behave in a desired
manner. For example, a mating surface might have a projection,
platform or pedestal (42) with a geometry that allows for a droplet
of particular dimensions, as shown in FIG. 18. A surface might also
be topped with a structure surrounding the port from which the
droplet projects, such as a gasket (43) or other mechanical seal,
as shown in FIG. 19, which fills the space between the two mating
surfaces (i.e. one surface from the microfluidic device and one
from the perfusion assembly), to prevent leakage while under
compression.
[0225] Alternatively (FIG. 20), a portion of the droplet can be
positioned in a depression or recess (44), such that a portion of
the droplet is below the mating surface (21) of the microfluidic
device, as shown in FIG. 20 and FIG. 21. In still another
embodiment, adhesive patches or stickers (45) can be placed on the
surface to create hydrophilic or hydrophobic regions on the mating
surface of the microfluidic device, as shown in FIGS. 22A and
22B.
[0226] In yet another embodiment, a combination of geometric
features and surface treatments can be applied. For example, a
hydrophobic pedestal or gasket might be used (or made) to permit
smaller droplet sizes. Most elastomeric polymers used to make
gaskets are hydrophobic. Such gaskets are commercially available,
e.g. from Stockwell Elastomerics, Inc. (Philadelphia Pa., USA). On
the other hand, M&P Sealing machines high-quality products made
from materials such as Polytetrafluoroethylene ("PTFE"),
Perfluorolkoxy ("PFA"), or fluorinated Ethylene ("FEP"), including
soft hydrophobic gaskets (Orange, Tex., USA). These are also
contemplated in some embodiments. When other portions of the device
(i.e. portions other than the pedestal or gasket) are treated (e.g.
plasma treatment) to make them hydrophilic, a naturally hydrophobic
pedestal or gasket can be protected with a mask during plasma
treatment to keep it from becoming hydrophilic.
[0227] In one embodiment, the walls of the port (or at least a
portion thereof leading up to the mating surface of the
microfluidic device) are hydrophilic or made hydrophilic. In one
embodiment, the walls of the corresponding port (or at least a
portion thereof leading up to the mating surface of the perfusion
assembly) are hydrophilic or made hydrophilic. In one embodiment,
both the walls of the port of the microfluidic device and the
corresponding port of the perfusion assembly (or portions thereof)
are hydrophilic or made hydrophilic.
[0228] In one embodiment, the present invention contemplates that
the surface is designed to retain a droplet that resists the weight
of liquid in the reservoir (as shown in FIGS. 25A-25B). This is
especially important in practice, since it allows the droplets that
go on the top device (i.e. where a first device approaches a second
device from above) to be easily created. This embodiment allows one
to simply put a measured amount of liquid into the reservoir (e.g.
100 uL, 75 uL, 50 uL or some other amount), leading that liquid to
flow to the port, form a droplet and stop on its own Importantly,
it is not intended that this embodiment be limited to any
particular amount of liquid; indeed, one does not need a precisely
measured amount of liquid. It is sufficient to aim for a certain
amount, as long as that amount is below a certain threshold (where
the weight of the water overwhelms the droplet's surface tension
and breaks through) in order to form a droplet by this method. It
might be more or less convex depending on how much liquid is
pushing down on it, but the spatial extent of the droplet should be
the same.
[0229] It is not intended that the present invention be limited to
only one manner for drop-to-drop connecting of microfluidic
devices. In one embodiment, a first microfluidic device, such as an
organ on a chip microfluidic device comprising cells that mimic one
or more functions of cells in an organ in the body (i.e. mimic one
or more functions of cells in an organ in the body such as
cell-cell interaction, cytokine expression, etc.), has a droplet
projecting upward, while the corresponding droplet on a second
microfluidic device projects downward, as shown in FIG. 15A. In
another embodiment, the first microfluidic device, such as an organ
on a chip microfluidic device comprising cells that mimic cells in
an organ in the body or at least one function of an organ, has a
droplet projecting downward, while the corresponding droplet on the
second microfluidic device projects upward.
[0230] Gravity alone, aside from momentum arguments, also plays a
role in stable droplet formation. For example, a chip that is laid
flat on a table does not experience significant forces due to
gravity. If that device is tipped, as part of the engagement
procedure for example, fluid will flow from the higher to lower
point. Therefore, orientation of the device might be considered
another way to aide in the confinement of droplets, including which
device has vias pointing upwards vs downwards.
[0231] An additional aspect of controlling droplet volume is the
fluidic resistance of the device channels. If a device has small
channels, for example, the fluidic resistance might be high enough
to maintain a nearly constant droplet volume over time despite
there being forces driving fluid flow out of the device (e.g.
gravity or capillary force). This is true even in the case of high
Bond number. Tuning fluidic resistance might be utilized as a
singular method to "confine droplets" or in combination with other
methods like controlling liquid pinning geometry or controlling the
wetting properties of the surfaces; fluidic resistance would be
used to control droplet volume, while controlling the wetting
properties of the surface would help control droplet placement.
[0232] B. Microfluidic Devices
[0233] It is not intended that the present invention be limited by
the nature of the microfluidic device. However, preferred
microfluidic devices are described in U.S. Pat. No. 8,647,861,
hereby incorporated by reference, and they are microfluidic
"organ-on-chip" devices comprising living cells in microchannels,
e.g. cells on membranes in microchannels exposed to culture fluid
at a flow rate. The surfaces of the microchannels and/or the
membrane can be coated with cell adhesive molecules to support the
attachment of cells and promote their organization into tissues.
Where a membrane is used, tissues can form on either the upper
surface, the lower surface or both. In one embodiment, different
cells are living on the upper and lower surfaces, thereby creating
one or more tissue-tissue interfaces separated by the membrane. The
membrane may be porous, flexible, elastic, or a combination thereof
with pores large enough to only permit exchange of gases and small
chemicals, or large enough to permit migration and transchannel
passage of large proteins, as well as whole living cells. In one
embodiment, the membrane can selectively expand and retract in
response to pressure or mechanical forces, thereby further
physiologically simulating the mechanical force of a living
tissue-tissue interface.
[0234] FIGS. 33A-33B shows a schematic of an illustrative
microfluidic device or "organ-on-chip" device. The assembled device
is schematically shown in FIG. 33A, which includes a plurality of
ports. FIG. 33B shows an exploded view of the device of FIG. 33A,
showing a bottom piece (97) having channels (98) in a parallel
configuration, and a top piece (99) with a plurality of ports (2),
with a tissue-tissue interface simulation region comprising a
membrane (101) between the top (99) and bottom (97) pieces, where
cell behavior and/or passage of gases, chemicals, molecules,
particulates and cells are monitored. In an embodiment, an inlet
fluid port and an outlet fluid port are in communication with the
first central microchannel such that fluid can dynamically travel
from the inlet fluid port to the outlet fluid port via the first
central microchannel, independently of the second central
microchannel. It is also contemplated that the fluid passing
between the inlet and outlet fluid ports may be shared between the
central microchannels. In either embodiment, characteristics of the
fluid flow, such as flow rate and the like, passing through the
first central microchannel is controllable independently of fluid
flow characteristics through the second central microchannel and
vice versa.
[0235] FIG. 34 is a schematic showing an embodiment with two
membranes (101 and 102) with cells (103) inside the device in a
first channel, but also in contact with fluid channels (104 and
105) with arrows showing the direction of flow. This three channel
device allows one to follow the migration or movement of cells,
e.g. lymphoid cells, vascular cells, nerve cells, etc. In one
embodiment, membrane 101 is coated with a lymphatic endothelium on
its upper surface and with stromal cells on its lower surface, and
stromal cells are also coated on the upper surface of the second
porous membrane 102 and a vascular endothelium on its bottom
surface. The movement of these vascular and stromal cells can be
monitored. Alternatively, a third type of cell can be placed in the
middle (103) and the migration through the membranes can be
monitored (e.g. by imaging or by detection of cells in the channels
or channel fluid). The membranes may be porous or have grooves to
allow cells to pass through the membranes.
[0236] In one embodiment this three channel device is used to
determine cell behavior of cancer cells. Tumor cells are placed,
for example, in the central microchannel surrounded on top and
bottom by layers of stromal cells on the surfaces of the upper and
lower membranes. Fluid such as cell culture medium or blood enters
the vascular channel. Fluid such as cell culture medium or lymph
enters the lymphatic channel. This configuration allows researchers
to mimic and study tumor growth and invasion into blood and
lymphatic vessels during cancer metastasis. The membranes may be
porous or have grooves to allow cells to pass through the
membranes.
[0237] C. Seeding Devices With Cells
[0238] In many of the embodiments described above, the microfluidic
chip or other device comprises cells. In some embodiments, cells
are seeded directly into the chip. However, in other embodiments,
the chip is contained in a carrier, which in turn is mounted on a
stand to facilitate cell seeding. FIGS. 35A-C show one embodiment
of a "seeding guide" and stand. In one embodiment, the seeding
guide engages the carrier which contains the microfluidic chip, and
holds the chip right side up (e.g. for top channel seeding) and
upside down (e.g. for bottom channel seeding) in the various stages
of seeding and/or coating (e.g. ECM coating), so as to improve
aseptic technique. FIG. 35A shows how one embodiment of a stand
(100) is assembled, i.e. by engaging two end caps (106, 107) with
side panels (108, 109). FIG. 35B shows a chip (16) and a carrier
(17) engaged by the seeding guide, the seeding guide approaching
the stand (100). FIG. 35C shows six carriers (17) with chips, each
engaged with a seeding guide, each seeding guide mounted on the
stand (100). The seeding guide is adapted to accept a chip carrier
(e.g. in a manner similar to how the skirt engages the chip
carrier); after coating and/or seeding the same chip carrier can be
(after disengaging from the seeding guide) linked to a perfusion
manifold assembly. The seeding guide is designed to allow the chip
to be held (whether right side up or upside down) such that its
ports do not contact the tabletop or any other surface. This is in
order to avoid the contamination of the chip through such contact.
Additionally, the seeding guide or holder facilitates access to the
chip through pipettes and/or needles and may optionally assist
their insertion into chip ports using guide features.
[0239] In one embodiment, the present invention contemplates a
method of seeding, comprising a) providing i) a chip at least
partially contained in a carrier, ii) cells, iii) a seeding guide
and iv) a stand with portions configured to accept at least one
seeding guide in a stable mounted position; b) engaging said
seeding guide with said carrier to create an engaged seeding guide,
c) mounting said engaged seeding guide on said stand, and d)
seeding said cells into said chip (e.g. with pipette tips) while
said seeding guide (along with the carrier and chip) is in a stable
mounted position. In one embodiment, the microfluidic device or
chip comprises a top channel, a bottom channel, and a membrane
separating at least a portion of said top and bottom channels. In
one embodiment, the microfluidic device or chip, after the seeding
of step c) comprises cells on the membrane and/or in (or on) one or
more of the channels (e.g. the top channel is seeded). In one
embodiment of this method, a plurality of seeding guide are mounted
on the stand, permitting a plurality of chips to be seeded with
cells. The guide has a number of functions, including a) keeping
the surface of a chip sterile during handling, b) guiding pipette
tips properly into ports during seeding, c) clearly labeling the
channels of the chip (e.g. differentiating between the top and
bottom channels), and d) permitting the shipping of the chips with
liquid in the channels (as well as shipping of chips with cells
already seeded or functionalized with ECM). The stand also has a
number of functions, including a) keeping the chip level to allow
cells to distribute evenly across the membrane, b) allowing the
guide to be flipped upside down for seeding of the bottom channel,
and c) enabling users to carry and store many seeded chips at one
time. Thus, in one embodiment, after the seeding of step c), the
method continues with the steps of flipping the chip upside down
and seeding the bottom channel.
Experimental
EXAMPLE 1
[0240] Conditions for bonding the capping layer (FIGS. 2A-2E-2,
element 13) to the backplane (14) were examined. Extruded SEBS
sheets were bonded to a hot embossed plate. The SEBS sheets were
designed to act as the capping layer to the channels that are
formed in the COP via the hot embossing process and as a fluid and
gas gasketing to mating parts. The testing showed that the 1 mm
thick SEBS was better as a fluid seal between the reservoirs and
the backplane. The hot embossed plates were fabricated from Zeonor
1420R. The SEBS materials used were:
[0241] A. Thickness: 1 mm, Material: Kraton G1643, Mfg Process:
extrusion
[0242] B. Thickness: 0.2 mm, Material: Kraton G1643+5%
Polypropylene, Mfg Process: extrusion An oven process was used in
comparison to a laminator. The laminator produced marginal to not
adequate bonding. However, the oven process revealed the
following:
TABLE-US-00001 Material Thickness 0.2 mm SEBS 1 mm SEBS Bonding
Temp (C.) 80 80 Bonding Time 1 hr-24 hr Clamping Pressure None 0.5
kg Applied through a silicone coated acrylic plate Necessary for
conformal lamination/good bond production Bond Quality 1 hr: good
bond Good bond 24 hr: excellent bond Anisotropic Effects None
noticeable Yes. Requires clamping pressure to be held for ~30 min
during cooling
[0243] In some embodiments, the fluidic layer is sealed with a
film. This film may be polymeric, metallic, biological or a
combination thereof (e.g. A laminate of multiple materials).
Examples of materials include polypropylene, SEBS, COP, PET, PMMA,
aluminum, etc. Specifically, the film may be elastomeric. The film
may be affixed to the fluidic layer by means of an adhesive agent,
thermal lamination, laser welding, clamping, and other methods
known in the art. The film may further be used to affix and
potentially fluidically interconnect additional components to the
fluidic layer. For example, the film may be used to adhere one or
more reservoirs to the fluidic layer. In an example embodiment, the
film is a thermal lamination film that includes EVA or EMA. In the
example embodiment, the film may be first laminated against the
fluidic layer using a thermal treatment and then, using a second
thermal treatment, adheres one or more reservoirs to the fluidic
layer. In a different embodiment, the film includes SEBS, which is
known to be bondable to a variety of materials including
polystyrene, COP, polypropylene, etc., either using a thermal
treatment or with the help of one or more solvents. In this
example, the SEBS film may be laminated to a fluidic layer (using
thermal treatment or with the help of solvent) and using a second
treatment, bond one or more reservoirs to the fluidic layers. There
are multiple potential advantages to using a film that is
elastomeric, deformable, or pliable, or film that reflows during
the bonding process. These advantages include, for example:
potentially conforming to the fluidic layer or other bonded
component (e.g. reservoirs), thereby relaxing manufacturing
tolerance (e.g. on the flatness or planarity of the manufactured
parts), potentially simplifying the required parallelism or
alignment during bonding (e.g. because the said film may deform to
absorb errors in parallelism), and acting as a gasket to create a
fluidic seal, for example, between the fluidic backplane and
reservoirs. SEBS is especially advantageous as a bonding film,
since it can bond under moderate temperatures (typically under 100
C) while not significantly reflowing. Reflowing may be undesirable
as it poses a risk of filling in and blocking fluidic channels. By
not significantly reflowing, SEBS can better maintain the
dimensions and structure of fluidic channels and other features in
the fluidic layer compared to materials that reflow (e.g.
traditional thermal lamination films). Film thickness can range
from 10 um to 5 mm in different embodiments. The film may include
various fluidic ports or channels. The film need not be flat and
can take on a variety of three-dimensional shapes.
EXAMPLE 2
[0244] In this example, one embodiment of a protocol for chip
activation is discussed. The example assumes that all work is done
under a hood using aseptic techniques and all working spaces are
sterile (or made sterile).
[0245] Part I: Preparing The Chip [0246] A. Spray the exterior of
the chip package with 70% Ethanol and wipe it prior to bring it
inside hood. [0247] B. Open package inside hood and take chip in
chip carrier out (keep these together). [0248] C. Place chip in
chip carrier within large sterile dish [0249] i. Only handle the
chip carriers by their wings. Always use tweezer to handle chip,
The surface of chip is connected with cell culture area. Avoid
touching the surface of the chip with hands and keep the chip unit
flat [0250] D. Allow vial of Emulate Reagent 1 (ER1) powder
(containing a cross-linker) to fully equilibrate to ambient
temperature before opening to prevent condensation inside the
storage container--ER1 is moisture and light sensitive [0251] E.
Turn the light in the biosafety hood off [0252] F. Reconstitute the
powder with Reagent 2 [0253] i. Add 1 ml of Emulate Reagent 2 (ER2)
(containing a buffer) directly into the ER1 storage container and
invert 3 times to mix thoroughly [0254] ii. Cover the ER1 solution
with tin foil to prevent light degradation [0255] G. Wash chip
[0256] i. Orient the chip horizontally within the hood [0257] ii.
Pipette up 100 ul of ER2 solution using tip [0258] iii. Place the
pipette in a completely vertical position and insert into the
bottom channel--If it is hard to find the port, navigate touching
the surface near the port [0259] iv. After finding the port, inject
the tip into the port (make tight connection) [0260] v. Wash 100 ul
of ER2 solution and keep the pipette plunger depressed (if you see
outlet fluid coming out, washing is done successfully, if you see
fluid coming out from the same port of injection, tip is not
injected properly, repeat step iv) [0261] vi. To take out the tip,
gently press the chip body using sterile tweezer and tip out, keep
the pipette plunger depressed [0262] vii. Aspirate outlet flow
[0263] viii. Repeat the same procedure for top channel washing
[0264] ix. After washing, empty top channel first and bottom
channel with aspirator [0265] H. Inject ER1 Solution to both
channels [0266] i. Pipette up 30 ul of ER1 solution using tip
[0267] ii. Navigate the port of inlet of bottom channel using
pipette tip on top of the chip surface near the port [0268] iii.
After finding the port, inject the tip into the port (make tight
connection) [0269] iv. Inject 30 ul of ER1 solution and keep the
pipette plunger depressed (if you see outlet fluid coming out,
injection is done successfully, if you see fluid coming out from
the same port of injection, tip is not injected properly, repeat
step ii) [0270] v. To take out the tip, gently press the chip body
using sterile tweezer and tip out, keep the pipette plunger
depressed [0271] vi. Aspirate excessive fluid from the surface of
chip (avoid to contact the port) [0272] vii. Repeat the same
procedure for the top channel using 50 ul of ER1 solution [0273]
viii. Avoid introduction of bubbles. Inspect channels under
microscope to be sure no bubbles are present, if bubbles are
present, inject with ER1 solution again [0274] I. Place chips
directly under UV lamps, ensure UV light unit is in hood, light
turns on, and adjust setting with button on back to "constant"
[0275] J. Treat UV light for 20 min [0276] K. After UV treatment,
gently aspirate ER1 from channels via same ports until channels are
free of solution [0277] L. Wash with 100 ul of ER2 solution to both
channels and then with 200 ul of dPBS
[0278] Part II: Coating [0279] A. Prepare ECM as directed by
manufacturer. It is recommended to aliquot ECM and freeze if
manufacturer instructed. Avoid multiple freeze-thaw cycles [0280]
B. Calculate total volume of ECM solution [0281] * Minimum volume
for Channels [0282] i. Top: 50 ul [0283] ii. Bottom: 20 ul [0284]
iii. ECM Diluent: User defined per ECM, prepare on ice. [0285] **if
using Matrigel, see Matrigel protocol** (make sure matrigel
protocol has "slushy ice, no touching, any warming will destroy
matrigel) [0286] C. Aspirate dPBS from channels [0287] D. Load
channels with ECM solution [0288] i. Pipette up 30 ul of cold ECM
solution using tip [0289] ii. Navigate the port of inlet of bottom
channel using pipette tip on top of the chip surface near the port
[0290] iii. After finding the port, inject the tip vertically into
the port (make tight connection) [0291] iv. Inject 30 ul of ECM
solution and keep the pipette plunger depressed (if you see outlet
fluid coming out, injection is done successfully, if you see fluid
coming out from the same port of injection, tip is not injected
properly, repeat step ii) [0292] v. To take out the tip, gently
press the chip body using sterile tweezer and tip out [0293] vi.
Aspirate excessive fluid from the surface of chip (avoid to contact
the port) [0294] vii. Repeat the same procedure for the top channel
using 50 ul of ECM solution [0295] E. Incubate at 4.degree. C.
overnight or for 2 hour at 37.degree. C. [0296] F. Seal the dish
containing coated chips using parafilm.
EXAMPLE 3
[0297] This example provides one embodiment of a protocol for
seeding cells inside the chip in the top channel (which is oriented
horizontally, unless otherwise indicated). The example assumes
aseptic techniques and a sterile environment.
[0298] It should be noted that, although some cells require very
specific seeding conditions, in general an optimal seeding density
is achieved when the cells are in a planar monolayer spaced
closely. From this spacing, most primary cells will attach and
spread into a confluent monolayer.
[0299] Reference is made below to "gravity washing." This involves
a) placing a (bolus) drop of media (100 uL) over a port on one side
of the channel, making sure not to introduce any air bubbles within
the port itself, and b) allowing this to flow through the chip,
constantly aspirating media excess from the outlet port. [0300] A.
Transfer the chips into the hood [0301] B. Place them inside of a
sterile dish (eg 15 mm culture dish) [0302] C. Gently wash chips
[0303] i. Pipette up 200 ul of cell culture medium using tip [0304]
ii. Navigate the port of inlet of bottom channel using pipette tip
on top of the chip surface near the port [0305] iii. After finding
the port, inject the tip vertically into the port (make tight
connection) [0306] iv. Wash 200 ul of medium and keep the pipette
plunger depressed (if you see outlet fluid coming out, washing is
done successfully, if you see fluid coming out from the same port
of injection, tip is not injected properly, repeat step iv) [0307]
v. To take out the tip, gently press the chip body using sterile
tweezer and tip out, keep the pipette plunger depressed [0308] vi.
Aspirate outlet fluid [0309] vii. Repeat the same procedure for top
channel washing [0310] viii. Repeat washing step for both channels
one more time [0311] ix. Add medium drop in inlet and outlet ports
(100 ul each) [0312] D. Cover dish, and place to the incubator
until cells are ready [0313] E. Prepare cell suspension and count
cell number [0314] F. Seeding density is specific to the top and
bottom channels, cell type, and to the user's defined needs [0315]
i. Top channel: e.g. Caco2 cells: 2.5 million cells/ml [0316] ii.
Bottom channel: e.g. HUVEC: confluent [0317] G. After counting
cells, adjust cell suspension to appropriate density [0318] H. For
top channel seeding, bring dish containing chips in the hood and
aspirate excess medium on the surface of chip (only handle the chip
carriers by their wings; keep the chip carrier flat--do not pick it
up! This will ensure an even distribution of cells across the chip
culture membrane) [0319] I. Agitate cell suspension gently before
seeding each chip [0320] J. Pipette 50 .mu.L of the cell suspension
and seed into the top channel (top channel is the lower right hand
port when the chip is in the horizontal position) (use one chip
first) [0321] i. Place the pipette in a completely vertical
position and insert into the top channel (vertical is a gentler
introduction into the chip and ensures a more even cell
distribution) [0322] ii. Inject 50 ul of cell suspension and keep
the pipette plunger depressed (if you see outlet fluid coming out,
injection is done successfully, if you see fluid coming out from
the same port of injection, tip is not injected properly, repeat
step ii) [0323] iii. To take pipette tip out, gently press the chip
body using sterile tweezer except cell culture area and tip out,
keep the plunger depressed. [0324] iv. Immediately aspirate outlet
fluid from chip surface using seeded tip (avoid to contact the
port) [0325] v. Use the pipette to immediately remove outflow from
chip surface using seeded tip [0326] * Remove the outflow so that
both inlet and outlet are even with surface of chip to prevent
hydrostatic pressure flow [0327] K. Cover the dish and transfer to
the microscope to check density [0328] L. After seeding, place the
chips it in the incubator until cells have attached [0329] i. Place
a small reservoir (15 ml or 50 ml conical tube cap) with PBS inside
of the dish to provide humidity to cells [0330] ii. Range of
attachment time is 1.about.3 hours depends on cell type [0331] M.
After cells have attached, gravity wash the chips with warm medium
by gently washing media through the channels. [0332] N. Return
chips to incubator until ready to move on to next step
EXAMPLE 4
[0333] This example provides one embodiment of a protocol for
seeding cells inside the chip in the bottom channel (which is
oriented horizontally, unless otherwise indicated). The example
assumes aseptic techniques and a sterile environment.
[0334] It should be noted that, although some cells require very
specific seeding conditions, in general an optimal seeding density
is achieved when the cells are in a planar monolayer spaced
closely. From this spacing, most primary cells will attach and
spread into a confluent monolayer.
[0335] Reference is made below to "gravity washing." This involves
a) placing a (bolus) drop of media (100 uL) over a port on one side
of the channel, making sure not to introduce any air bubbles within
the port itself, and b) allowing this to flow through the chip,
constantly aspirating media excess from the outlet port. [0336] A.
Bring dish containing chips in the hood and aspirate excess medium
on the surface of chip (only handle the chip carriers by their
wings; keep the chip carrier flat--do not pick it up! This will
ensure an even distribution of cells across the chip culture
membrane) [0337] B. Agitate cell suspension gently before seeding
each chip [0338] C. Pipette 20 .mu.L of the cell suspension and
seed into the bottom channel (the bottom channel is the upper right
hand port when the chip is in the horizontal position) (use one
chip first) [0339] i. Inject 20 ul of cell suspension and keep the
pipette plunger depressed (if you see outlet fluid coming out,
injection is done successfully, if you see fluid coming out from
the same port of injection, tip is not injected properly, repeat
step ii) [0340] ii. To take pipette tip out, gently press the chip
body using sterile tweezer except cell culture area and tip out,
keep the plunger depressed. [0341] iii. Immediately aspirate outlet
fluid from chip surface using seeded tip (avoid to contact the
port) [0342] iv. Remove the outflow so that both inlet and outlet
are even with surface of chip to prevent hydrostatic pressure flow
[0343] D. Cover the dish and transfer to the microscope to check
density [0344] E. After seeding, flip the chip inside of dish and
place the chips it in the incubator until cells have attached
underneath the membrane [0345] i. Range of attachment time is
1.about.3 hours depends on cell type [0346] ii. Place a small
reservoir (15 ml or 50 ml conical tube cap) with PBS inside of the
dish to provide humidity to cells [0347] F. After cells have
attached, flip chips back, gravity wash the chips with warm medium
by gently injecting media through the channels. [0348] G. Return
chips to incubator until ready to move on to next step (cells can
be cultured in the chip under static conditions until ready to
connect to the perfusion manifold for flow conditions) [0349] i.
Aspirate old medium from the chip surface [0350] ii. Gravity rinse
the chips with warm medium by gently injecting media through the
channels every day: 200 ul each for top and bottom channel, drop
the medium in inlet port [0351] iii. Place a small reservoir (15 ml
or 50 ml conical tube cap) with PBS inside of the dish to provide
humidity to cells
EXAMPLE 5
[0352] In this example, one embodiment of a protocol for preparing
the perfusion disposable or "pod" is provided. This assumes aseptic
techniques and a sterile environment. [0353] A. Warm media to
37.degree. C. ahead of time [0354] B. Transfer warmed media into
the biohood [0355] C. Aliquot required amount +5% into 50 mL
conical tubes [0356] D. Sanitize and transfer one steriflip vacuum
filter into hood for each tube of media [0357] i. Take steriflip
out of packaging and connect to 50 mL tube of media [0358] ii.
Connect to vacuum inside of hood and invert [0359] iii. Use a timer
to vacuum degas for a minimum of 15 min [0360] E. Prepare correct
number of PODs (based on # of viable chips) [0361] F. Sanitize the
Emulate nests and trays with ethanol and transfer them into the
hood [0362] G. Sanitize one packaged Pod for each of the viable
Chips with ethanol and transfer into the hood (always hold only
edges of POD with thumb and long finger; keep lid of POD on and
flat using index finger while simultaneously holding POD) [0363] H.
Remove the reservoir lid and add media. This should create droplets
suitable for drop-to-drop engagement of the POD and the Chip.
[0364] i. Input Reservoir: Fill 1-3 ml (1 ml minimum) [0365] ii.
Output Reservoir: 300 ul [0366] I. Transfer Seeded Chips from the
incubator and bring to hood [0367] i. Remove the pipette tips with
a gentle twisting motion and dispose of them [0368] ii. Use a 200
.mu.L pipette to add 10-50 .mu.L of media over each port (avoid
creating a bubble inside the port). This should create droplets
suitable for drop-to-drop engagement of the POD and the Chip.
[0369] J. Connect Chip+Carrier to POD. This connection process
should result in drop-to-drop engagement of the POD and the Chip
using the droplets formed in Steps H and I. [0370] i. In one hand,
hold a chip carrier with the index finger and thumb pinching the
carrier, with the thumb on the locking mechanism [0371] ii. With
the other hand grasp the Pod with the thumb and long finger around
the reservoir and place the index finger on the top of the lid to
secure it [0372] iii. Orient the Pod so that you are looking "into"
it, along the tracks inside it [0373] iv. Continuing to pinch the
carrier, align the feet of the carrier with the tracks within the
Pod [0374] v. Slide the chip carrier into the Pod [0375] vi. Use
your thumb against the chip carrier to gently depress the locking
mechanism until it slides into place, capturing the chip within the
Pod [0376] vii. Confirm that each reservoir lid is correctly on
each Pod
* * * * *