U.S. patent application number 17/684920 was filed with the patent office on 2022-06-16 for fluid diversion mechanism for bodily-fluid sampling.
This patent application is currently assigned to Magnolia Medical Technologies, Inc.. The applicant listed for this patent is Magnolia Medical Technologies, Inc.. Invention is credited to Gregory J. BULLINGTON, Shan E. GAW, Jay M. MIAZGA, Richard G. PATTON.
Application Number | 20220183600 17/684920 |
Document ID | / |
Family ID | |
Filed Date | 2022-06-16 |
United States Patent
Application |
20220183600 |
Kind Code |
A1 |
BULLINGTON; Gregory J. ; et
al. |
June 16, 2022 |
FLUID DIVERSION MECHANISM FOR BODILY-FLUID SAMPLING
Abstract
An apparatus includes a housing, a flow control mechanism, and
an actuator. At least a portion of the flow control mechanism is
movably disposed within the housing. The apparatus further includes
an inlet port and an outlet port, and defines a fluid reservoir.
The outlet port is fluidically coupled to a second fluid reservoir
and is fluidically isolated from the first fluid reservoir. The
actuator is configured to move the flow control mechanism between a
first configuration, in which the inlet port is placed in fluid
communication with the fluid reservoir such that the fluid
reservoir receives a first flow of bodily-fluid, and a second
configuration, in which the inlet port is placed in fluid
communication with the outlet port.
Inventors: |
BULLINGTON; Gregory J.;
(Seattle, WA) ; PATTON; Richard G.; (Seattle,
WA) ; MIAZGA; Jay M.; (Langley, WA) ; GAW;
Shan E.; (Seattle, WA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Magnolia Medical Technologies, Inc. |
Seattle |
WA |
US |
|
|
Assignee: |
Magnolia Medical Technologies,
Inc.
Seattle
WA
|
Appl. No.: |
17/684920 |
Filed: |
March 2, 2022 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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16299962 |
Mar 12, 2019 |
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17684920 |
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14712431 |
May 14, 2015 |
10265007 |
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16299962 |
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14455263 |
Aug 8, 2014 |
9060725 |
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14712431 |
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13954528 |
Jul 30, 2013 |
8864684 |
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14455263 |
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13650554 |
Oct 12, 2012 |
8535241 |
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13954528 |
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61546954 |
Oct 13, 2011 |
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International
Class: |
A61B 5/15 20060101
A61B005/15; A61B 10/00 20060101 A61B010/00; A61B 5/155 20060101
A61B005/155 |
Claims
1-30. (canceled)
31. A blood sampling system, comprising: a blood sampling pathway
having a lumen-containing device coupleable to a patient on a
distal end and a sample needle on a proximal end; and a blood
transfer device attached on the blood sampling pathway between the
proximal end and the distal end of the blood sampling pathway, the
blood transfer device comprising: an inlet port coupled with the
blood sampling pathway toward the patient; an outlet port coupled
with the blood sampling pathway toward the sample needle; a
reservoir in fluid communication with the inlet port, the reservoir
having a vent allowing air to exit the blood transfer device as
blood enters the reservoir; and a sampling flow path having a
distal end in fluid communication with the outlet port and a
proximal end in fluid communication with the sample needle.
32. The blood sampling system of claim 31, wherein the blood
transfer device allows a first portion of blood to flow into the
reservoir.
33. The blood sampling system of claim 32, wherein the blood
transfer device allows a second portion of blood to bypass the
reservoir and flow toward the outlet port.
34. The blood sampling system of claim 33, wherein the blood
transfer device allows the second portion of blood to flow toward
the outlet port in response to the first portion of blood being
received in the reservoir.
35. The blood sampling system of claim 31, wherein the blood
transfer device has a first state in which a first portion of blood
flows into the reservoir toward the vent and a second state in
which the first portion of blood is sequestered in the reservoir
and a second portion of blood flows through the blood sampling
pathway while bypassing the reservoir.
36. The blood sampling system of claim 31, wherein the blood
transfer device further comprises: a seal member defining at least
a portion of the reservoir, the blood transfer device having a
first state in which the seal member allows blood to flow into the
reservoir toward the seal member and air to flow out of the vent
away from the seal member, the blood transfer device having a
second state in which the seal member separates the blood in the
reservoir from air outside the reservoir.
37. The blood sampling system of claim 31, wherein the blood
sampling pathway includes: a first sterile tubing having a distal
end coupleable to the lumen-containing device and a proximal end
coupleable to the inlet port of the blood transfer device; and a
second sterile tubing having a distal end coupleable to the outlet
port of the blood transfer device and a proximal end coupleable to
the sample needle.
38. The blood sampling system of claim 37, wherein the blood
transfer device automatically transitions from a first state to a
second state in response to a first portion of blood being received
in the reservoir, the sampling flow path allowing fluid
communication between the first sterile tubing and the second
sterile tubing when the blood transfer device is in the second
state such that a second portion of blood flows from the
lumen-containing device to the sample needle while bypassing the
reservoir.
39. A blood sampling system, comprising: a blood sampling pathway
having a lumen-containing device coupleable to a patient on a
distal end and a sample needle on a proximal end; and a blood
transfer device attached on the blood sampling pathway between the
proximal end and the distal end of the blood sampling pathway, the
blood transfer device comprising: an inlet port coupled with the
blood sampling pathway toward the patient; an outlet port coupled
with the blood sampling pathway toward the sample needle; a fluid
reservoir in fluid communication with the inlet port, the fluid
reservoir at least partially defined by a seal member, the seal
member allowing blood to flow from the patient into the fluid
reservoir and toward the seal member when the seal member
transitions from a first state to a second state; and a sampling
flow path having a distal end in fluid communication with the
outlet port and a proximal end in fluid communication with the
sample needle.
40. The blood sampling system of claim 39, wherein the blood
transfer device defines an inner volume, at least a portion of the
inner volume defining the reservoir, the blood transfer device
further comprising: a vent allowing air to exit the inner volume as
blood enters the reservoir.
41. The blood sampling system of claim 40, wherein the seal member
is configured to prevent the flow of air through the vent into the
reservoir.
42. The blood sampling system of claim 40, wherein the blood
transfer device has a first configuration in which the seal member
allows blood to flow into the reservoir toward the seal member and
air to flow out of the vent away from the seal member, the blood
transfer device has a second configuration in which the seal member
separates the blood in the reservoir from air outside the
reservoir.
43. The blood sampling system of claim 39, wherein the seal member
allows a first portion of blood to flow into the reservoir toward
the seal member and the sampling flow path allows a second portion
of blood to flow toward the outlet port in response to the first
portion of blood being received in the reservoir.
44. The blood sampling system of claim 39, wherein the blood
transfer device has a first configuration in which a first portion
of blood flows into the reservoir toward the seal member and a
second configuration in which the first portion of blood is
sequestered in the reservoir and a second portion of blood flows
through the blood sampling pathway while bypassing the
reservoir.
45. The blood sampling system of claim 39, wherein the blood
sampling pathway includes: a first sterile tubing having a distal
end coupleable to the lumen-containing device and a proximal end
coupleable to the inlet port of the blood transfer device; and a
second sterile tubing having a distal end coupleable to the outlet
port of the blood transfer device and a proximal end coupleable to
the sample needle.
46. The blood sampling system of claim 45, wherein the blood
transfer device automatically transitions from a first
configuration to a second configuration in response to a first
portion of blood being received in the reservoir, the sampling flow
path allowing fluid communication between the first sterile tubing
and the second sterile tubing when the blood transfer device is in
the second state such that a second portion of blood flows from the
lumen-containing device to the sample needle while bypassing the
reservoir.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the benefit of and priority to U.S.
Provisional Application Ser. No. 61/546,954, filed Oct. 13, 2011,
entitled, "Innovation for Reducing Blood Culture Contamination:
Initial Specimen Diversion Technique," the disclosure of which is
hereby incorporated by reference in its entirety.
BACKGROUND
[0002] Embodiments described herein relate generally to the
parenteral procurement of bodily-fluid samples, and more
particularly to devices and methods for parenterally-procuring
bodily-fluid samples with reduced contamination from microbes or
other contaminants exterior to the bodily-fluid source, such as
dermally-residing microbes.
[0003] Health care practitioners routinely perform various types of
microbial tests on patients using parenterally-obtained
bodily-fluids. Patient samples (e.g., bodily-fluids) are sometimes
tested for the presence of one or more potentially undesirable
microbes, such as bacteria, fungi, or yeast (e.g., Candida).
Microbial testing may include incubating patient samples in one or
more sterile vessels containing culture media that is conducive to
microbial growth. Generally, when microbes tested for are present
in the patient sample, the microbes flourish over time in the
culture medium. After a pre-determined amount of time (e.g., a few
hours to several days), the culture medium can be tested for the
presence of the microbes. The presence of microbes in the culture
medium suggests the presence of the same microbes in the patient
sample which, in turn, suggests the presence of the same microbes
in the bodily-fluid of the patient from which the sample was
obtained. Accordingly, when microbes are determined to be present
in the culture medium, the patient may be prescribed one or more
antibiotics or other treatments specifically designed to treat or
otherwise remove the undesired microbes from the patient.
[0004] Patient samples, however, can sometimes become contaminated
during procurement. One way in which contamination of a patient
sample may occur is by the transfer of microbes from a bodily
surface (e.g., dermally-residing microbes) dislodged during needle
insertion into a patient and subsequently transferred to a culture
medium with the patient sample. The bodily surface microbes may be
dislodged either directly or via dislodged tissue fragments, hair
follicles, sweat glands and other adnexal structures. The
transferred microbes may thrive in the culture medium and
eventually yield a positive microbial test result, thereby falsely
indicating the presence of such microbes in vivo. Such inaccurate
results are a concern when attempting to diagnose or treat a
suspected illness or condition. For example, false positive results
from microbial tests may result in the patient being unnecessarily
subjected to one or more anti-microbial therapies, which may cause
serious side effects to the patient including, for example, death,
as well as produce an unnecessary burden and expense to the health
care system.
[0005] As such, a need exists for improved bodily-fluid transfer
devices and methods that reduce microbial contamination in
bodily-fluid test samples.
SUMMARY
[0006] Devices for parenterally-procuring bodily-fluid samples with
reduced contamination from microbes exterior to the bodily-fluid
source, such as dermally-residing microbes, are described herein.
In some embodiments, an apparatus includes a housing, a flow
control mechanism, and an actuator. At least a portion of the flow
control mechanism is movably disposed within the housing. The
apparatus further includes an inlet port and an outlet port, and
defines a fluid reservoir. The outlet port is fluidically coupled
to a second fluid reservoir and is fluidically isolated from the
first fluid reservoir. The actuator is configured to move the flow
control mechanism between a first configuration, in which the inlet
port is placed in fluid communication with the fluid reservoir such
that the fluid reservoir receives a first flow of bodily-fluid, and
a second configuration, in which the inlet port is placed in fluid
communication with the outlet port.
BRIEF DESCRIPTION OF THE DRAWINGS
[0007] FIG. 1 is a schematic illustration of a bodily-fluid
transfer device according to an embodiment.
[0008] FIG. 2 is a perspective view of a bodily-fluid transfer
device according to an embodiment.
[0009] FIG. 3 is an exploded view of the bodily-fluid transfer
device of FIG. 2.
[0010] FIG. 4 is a perspective view of a housing included in the
bodily-fluid transfer device illustrated in FIG. 2.
[0011] FIG. 5 is a cross-sectional view of the housing illustrated
in FIG. 4 taken along the line X.sub.2-X.sub.2.
[0012] FIG. 6 is a perspective view of an actuator included in the
bodily-fluid transfer device of FIG. 2.
[0013] FIG. 7 is an exploded perspective view of a flow control
mechanism included in the bodily-fluid transfer device of FIG.
2.
[0014] FIG. 8 is a cross-sectional view of the bodily-fluid
transfer device of FIG. 2 taken along the line X.sub.1-X.sub.1, in
a first configuration.
[0015] FIG. 9 is an enlarged view of the region labeled Z in FIG.
8.
[0016] FIGS. 10 and 11 are cross-sectional views of the
bodily-fluid transfer device of FIG. 2 taken along the line
X.sub.1-X.sub.1, in a second and third configuration,
respectively.
[0017] FIG. 12 is a perspective view of the bodily-fluid transfer
device of FIG. 3, in the third configuration.
[0018] FIG. 13 is a perspective view of a bodily-fluid transfer
device according to an embodiment.
[0019] FIG. 14 is an exploded view of the bodily-fluid transfer
device of FIG. 13.
[0020] FIG. 15 is a perspective view of a first control member
included in the bodily-fluid transfer device of FIG. 13.
[0021] FIGS. 16-18 are cross-sectional views of the bodily-fluid
transfer device taken along the line X.sub.3-X.sub.3 in FIG. 12, in
a first, second, and third configuration, respectively.
DETAILED DESCRIPTION
[0022] Devices for parenterally-procuring bodily-fluid samples with
reduced contamination from microbes exterior to the bodily-fluid
source, such as dermally-residing microbes, are described herein.
In some embodiments, an apparatus includes a housing, a flow
control mechanism, and an actuator. At least a portion of the flow
control mechanism is movably disposed within the housing. The
apparatus further includes an inlet port and an outlet port, and
defines a first fluid reservoir. The outlet port is fluidically
coupleable to a second fluid reservoir, fluidically isolated from
the first fluid reservoir. The actuator is configured to move the
flow control mechanism between a first configuration, in which the
inlet port is placed in fluid communication with the first fluid
reservoir such that the first fluid reservoir receives a flow of
bodily-fluid, and a second configuration, in which the inlet port
is placed in fluid communication with the outlet port such that the
second fluid reservoir can receive a flow of bodily-fluid.
[0023] In some embodiments, a bodily-fluid transfer device can be
configured to selectively divert a first, predetermined amount of a
flow of a bodily-fluid to a first fluid reservoir before permitting
the flow of a second amount of the bodily-fluid into a second fluid
reservoir. In this manner, the second amount of bodily-fluid can be
used for diagnostic or other testing, while the first amount of
bodily-fluid, which may contain microbes from a bodily surface, is
isolated from the bodily-fluid to be tested.
[0024] In some embodiments, a bodily-fluid transfer device is
configured to automatically move from a first configuration to a
second configuration, for example, without requiring an input or
other action by a health care practitioner. In some embodiments,
the bodily-fluid transfer device prevents bodily-fluid from flowing
or otherwise being introduced into a second fluid reservoir before
at least a first amount of bodily-fluid (e.g., a predetermined
amount) is first introduced into a first fluid reservoir.
[0025] As referred to herein, "bodily-fluid" can include any fluid
obtained from a body of a patient, including, but not limited to,
blood, cerebrospinal fluid, urine, bile, lymph, saliva, synovial
fluid, serous fluid, pleural fluid, amniotic fluid, and the like,
or any combination thereof.
[0026] As used herein, the term "set" can refer to multiple
features or a singular feature with multiple parts. For example,
when referring to set of walls, the set of walls can be considered
as one wall with distinct portions, or the set of walls can be
considered as multiple walls. Similarly stated, a monolithically
constructed item can include a set of walls. Such a set of walls
can include, for example, multiple portions that are in
discontinuous from each other. A set of walls can also be
fabricated from multiple items that are produced separately and are
later joined together (e.g., via a weld, an adhesive or any
suitable method).
[0027] As used in this specification, the words "proximal" and
"distal" refer to the direction closer to and away from,
respectively, a user who would place the device into contact with a
patient. Thus, for example, the end of a device being actuated by
the user would be the proximal end, while the opposite end of the
device would be the distal end of the device.
[0028] As used in this specification, the terms "first,
predetermined amount" and "first amount" describe a given amount of
bodily-fluid configured to be received or contained by a pre-sample
reservoir (also referred to herein as a "first reservoir"). While
the term "first amount" does not explicitly describe a
predetermined amount, it should be understood that the first amount
is the first, predetermined amount unless explicitly described
differently.
[0029] FIG. 1 is a schematic illustration of a portion of a
bodily-fluid transfer device 100, according to an embodiment.
Generally, the bodily-fluid transfer device 100 (also referred to
herein as "fluid transfer device" or "transfer device") is
configured to permit the withdrawal of bodily-fluid from a patient
such that a first portion or amount of the withdrawn fluid is
diverted away from a second portion or amount of the withdrawn
fluid that is to be used as a biological sample, such as for
testing for the purpose of medical diagnosis and/or treatment. In
other words, the transfer device 100 is configured to transfer a
first, predetermined amount of a bodily-fluid to a first collection
reservoir and a second amount of bodily-fluid to one or more
bodily-fluid collection reservoirs fluidically isolated from the
first collection reservoir, as described in more detail herein.
[0030] The transfer device 100 includes a housing 101, an inlet
port 107, an outlet port 110, a flow control mechanism 130, an
actuator 170, a first fluid reservoir 180 (also referred to herein
as "first reservoir"), and optionally a second fluid reservoir 190
(also referred to herein as "second reservoir"), different than the
first reservoir 180. The housing 101 can house at least a portion
of the flow control mechanism 130 and the first reservoir 180. In
some embodiments, the housing 101 can also house at least a portion
of the actuator 170 and/or at least a portion of the second
reservoir 190. The housing 101 can be any suitable shape, size, or
configuration and is described in further detail herein with
respect to specific embodiments.
[0031] in some embodiments, the inlet port 107 and the outlet port
110 can be included in (e.g., monolithically formed with) or
coupled to the housing 101. In other embodiments, the inlet port
107 and the outlet port 110 can be included in or coupled to the
flow control mechanism 130 and can extend through a portion of the
housing 101. As shown in FIG. 1, the inlet port 107 can be, at
least temporarily, physically and fluidically coupled to a medical
device defining a pathway P for withdrawing and/or conveying the
bodily-fluid from the patient to the transfer device 100. For
example, the inlet port 107 can be a Luer-Lok.RTM. or the like
configured to be physically and fluidically coupled to a needle, a
cannula, or other lumen-containing device. In other embodiments,
the inlet port 107 can be monolithically formed with at least a
portion of the lumen-containing device. In this manner, the inlet
port 107 can receive the bodily-fluid from the patient via the
pathway P. The outlet port 110 is configured to be fluidically
coupled to the second fluid reservoir 190 as further described
herein.
[0032] The first reservoir 180 can be any suitable reservoir for
containing a bodily-fluid. For example, in some embodiments, the
first reservoir 180 can be formed by a portion of the flow control
mechanism 130 (e.g., defined by a set of walls of the flow control
mechanism 130). In some embodiments, the first reservoir 180 can be
formed or defined by a portion of the flow control mechanism 130
and a portion of the housing 101. In other embodiments, the first
reservoir 180 can be self-contained (e.g., such as a bladder or the
like) and be disposed within a portion of the housing 101 and/or
the flow control mechanism 130. In some embodiments, the first
reservoir 180 can be a pre-sample reservoir such as those described
in detail in U.S. Pat. No. 8,197,420 ("the '420 Patent"), the
disclosure of which is incorporated herein by reference in its
entirety. In this manner, the first reservoir 180 can be, at least
temporarily, placed in fluid communication with the inlet port 107
such that the first reservoir 180 can receive and contain the
first, predetermined amount of the bodily-fluid. In some
embodiments, the first reservoir 180 is configured to contain the
first amount of the bodily-fluid such that the first amount is
fluidically isolated from a second amount of the bodily-fluid
(different than the first amount of bodily-fluid) that is
subsequently withdrawn from the patient.
[0033] The second reservoir 190 can be any suitable reservoir for
containing a bodily-fluid, including, for example, a sample
reservoir as described in the '420 Patent incorporated by reference
above. In some embodiments, the second reservoir 190 can be
substantially similar to or the same as known sample containers
such as, for example, a Vacutainer.RTM. or the like. The second
reservoir 190 is configured to be fluidically coupled to the outlet
port 110 of the transfer device 100. For example, in some
embodiments, the second reservoir 190 is physically (either
directly or via an intervening structure such as sterile flexible
tubing) and fluidically coupled to the outlet port 110. In other
embodiments, the second reservoir 190 can be moved relative to the
outlet port 110 to place the second reservoir 190 in fluid
communication with the outlet port 110, as described herein with
respect to specific embodiments,
[0034] The second reservoir 190 is configured to receive and
contain the second amount of the bodily-fluid. For example, the
second amount of bodily-fluid can be an amount withdrawn from the
patient subsequent to withdrawal of the first amount. In some
embodiments, the second reservoir 190 is configured to contain the
second amount of the bodily-fluid such that the second amount is
fluidically isolated from the first amount of the bodily-fluid. As
used in this specification, the term "second amount" describes an
amount of bodily-fluid configured to be received or contained by
the second reservoir 190. In some embodiments, the second amount
can be any suitable amount of bodily-fluid and need not be
predetermined. In other embodiments, the second amount received and
contained by the second reservoir 190 is a second predetermined
amount.
[0035] The flow control mechanism 130 of the transfer device 100 is
movably disposed within the housing 101 between a first
configuration and a second configuration and defines, at least
partially, a first fluid flow path 181 and a second fluid flow path
191, as described in further detail herein. The flow control
mechanism 130 can be any suitable shape, size, or configuration.
For example, in some embodiments, the flow control mechanism 130
can include multiple components. In such embodiments, a first set
of one or more components can move together with and/or relative to
a second set of one or more components such that the flow control
mechanism 130 is moved between the first configuration and the
second configuration,
[0036] The actuator 170 of the transfer device 100 can be operably
coupled to the flow control mechanism 130 (e.g., either directly or
indirectly via an intervening structure). In this manner, the
actuator 170 can be configured to move the flow control mechanism
130 relative to the housing 101 between the first configuration and
the second configuration. For example, the actuator 170 can be
movable between a first position corresponding to the first
configuration of the flow control mechanism 130, and a second
position, different than the first position, corresponding to the
second configuration of the flow control mechanism 130. In some
embodiments, the actuator 170 is configured for unidirectional
movement. For example, the actuator 170 can be moved from its first
position to its second position, but cannot be moved from its
second position to its first position. In this manner, the flow
control mechanism 130 is prevented from being moved to its second
configuration before its first configuration, thus requiring that
the first amount of the bodily-fluid be directed to the first
reservoir 180 and not the second reservoir 190, as further
described herein.
[0037] In some embodiments, the actuator 170 can move the flow
control mechanism 130 in a translational motion between the first
configuration and the second configuration. For example, in some
embodiments, the flow control mechanism 130 can be in the first
configuration when the flow control mechanism 130 (or components
included therein) is in a proximal position relative to the housing
101. In such embodiments, the actuator 170 can be actuated to move
the flow control device 130 in the distal direction to a distal
position relative to the housing 101, thereby placing the flow
control mechanism 130 in the second configuration. In other
embodiments, the actuator 170 can be actuated to move the flow
control mechanism 130 in any suitable motion between the first
configuration and the second configuration (e.g., rotational).
Examples of suitable actuators are described in more detail herein
with reference to specific embodiments.
[0038] As described above, when the actuator 170 is in the first
position and the flow control mechanism 130 is in the first
configuration, the inlet port 107 is placed in fluid communication
with the first fluid reservoir 180 and the outlet port 110 is
fluidically isolated from the inlet port 107. More specifically,
the bodily-fluid can flow within the first fluid flow path 181
between the inlet port 107 and the first reservoir 180 such that
the first reservoir 180 receives the first amount of the
bodily-fluid. Similarly, when the actuator 170 is moved to the
second position to place the flow control mechanism 130 in the
second configuration, the first reservoir 180 is fluidically
isolated from the inlet port 107 and the outlet port 110 is placed
in fluid communication with the inlet port 107. More specifically,
the bodily-fluid can flow within the second fluid flow path 191
between the inlet port 107 and the outlet port 110 such that the
second reservoir 190 receives the second amount of the bodily
fluid.
[0039] In some embodiments, the transfer device 100 is configured
such that the first amount of bodily-fluid need be conveyed to the
first reservoir 180 before the transfer device 100 will permit the
flow of the second amount of bodily-fluid to be conveyed through
the outlet port 110 to the second reservoir 190. In this manner,
the transfer device 100 can be characterized as requiring
compliance by a health care practitioner regarding the collection
of the first, predetermined amount (e.g., a pre-sample) prior to a
collection of the second amount (e.g., a sample) of bodily-fluid.
Similarly stated, the transfer device 100 can be configured to
prevent a health care practitioner from collecting the second
amount, or the sample, of bodily-fluid into the second reservoir
190 without first diverting the first amount, or pre-sample, of
bodily-fluid to the first reservoir 180. In this manner, the health
care practitioner is prevented from including (whether
intentionally or unintentionally) the first amount of bodily-fluid,
which is more likely to contain bodily surface microbes, in the
bodily-fluid sample to be used for analysis.
[0040] In some embodiments, the actuator 170 can have a third
position and/or a fourth position, different than the first and
second positions, which corresponds to a third configuration of the
flow control mechanism 130. When in the third configuration, the
flow control mechanism 130 can fluidically isolate the inlet port
107 from both the first reservoir 180 and the outlet port 110
simultaneously. Therefore, when the flow control mechanism 130 is
in its third configuration, flow of bodily-fluid from the inlet
port 107 to either the first reservoir 180 or the second reservoir
190 is prevented. For example, the actuator 170 can be actuated to
place the flow control mechanism 130 in the first configuration
such that a bodily-fluid can flow from the inlet port 107 to the
first reservoir 180, then moved to the second configuration such
that the bodily-fluid can flow from the inlet port 107 to the
second reservoir 190, then moved to the third configuration to stop
the flow of bodily-fluid into and/or through the outlet port 110.
In some embodiments, the flow control mechanism 130 can be moved to
the third configuration between the first configuration and the
second configuration. In some embodiments, the flow control
mechanism 130 can be in the third configuration before being moved
to either of the first configuration or the second
configuration.
[0041] 110411 The transfer device 100 is one example of a device
that can be used to implement the Initial Specimen Diversion
Technique ("ISDT") described in U.S. Provisional Application Ser.
No. 61/546,954 incorporated by reference above. For example, in
some embodiments, the transfer device 100 can be used by a
phlebotomist (or technician otherwise trained in withdrawing a
bodily fluid from a patient) for the collection of a sample blood
culture. In some embodiments, phlebotomist or technician can use an
alternative transfer device or other medical equipment to implement
the ISDT as described herein. For example, the phlebotomist can
prepare a venipuncture site with a skin antisepsis (e.g., 2%
chlorhexidine, 70% alcohol) and insert a needle into the vein of
the patient such that a flow of blood is transferred away from the
patient. The phlebotomist can divert a first, predetermined amount
of blood to a first reservoir, as described herein. The first
amount of blood can, for example, be sufficiently large such that
dermally-residing microbes which may have been dislodged into the
needle during the insertion of the needle into the vein may be
washed into the first reservoir, thereby reducing the microbial
contamination in the blood that is subsequently used as one or more
samples for cultured microbial tests.
[0042] In some embodiments, the first amount of blood disposed
within the first reservoir (e.g., a pre-sample reservoir) can be
associated with a size of a second reservoir and/or can be based on
the desired volume of sample blood. For example, in some
embodiments, the first amount can be approximately 0.5 mL to
approximately 5 mL. In other embodiments, the first amount can be
approximately 0.5 mL to approximately 2.0 mL of the bodily fluid.
In still other embodiments, such as those used on pediatric
patients, the first amount can be approximately 0.1 mL to
approximately 0.5 mL of the bodily fluid. Thus, the first amount
can be sufficiently large to adequately collect undesirable
microbes while maintaining a substantially low risk of inducing
nosocomial anemia in, for example, fragile patients.
[0043] With the first amount of blood disposed within the first
reservoir, the phlebotomist can fluidically isolate the first
reservoir and place the second reservoir in fluid communication
with the needle. In this manner, the phlebotomist can transfer a
second amount of blood to the second reservoir that can be
substantially free from, for example, dermally-residing microbes.
Thus, the second amount of blood can be used in any suitable test,
such as a blood culture test, with a reduced likelihood of false
positives caused by undesirable microbes.
[0044] In some embodiments, with the second amount of blood
collected the phlebotomist can remove the needle from the patient
and discard the first amount of blood disposed within the first
reservoir. In other embodiments, the blood collected in the first
reservoir can be used for conducting one or more non-culture tests,
such as one or more biochemical tests, blood counts,
immunodiagnostic tests, cancer-cell detection tests, or the
like.
[0045] In some embodiments, the ISDT can be used to reduce
contamination without impacting the specimen volume for blood
culture. For example, the "diversion volume" or "pre-sample" can be
collected without reducing the volume collected for blood culture
sampling. Thus, the ISDT reduces contamination without impacting
blood culture sensitivity (e.g., false-negatives) by, for example,
minimizing the diversion volume. As described above, the ISDT can
also be used to reduce contamination without inducing nosocomial
anemia in fragile patients, Said another way, the ISDT and/or
transfer devices can be customized for different applications to
balance the many competing factors (e.g., contamination,
false-negatives nosocomial anemia, etc.) associated with bodily
fluid sampling. Thus, sample contamination can be sufficiently
reduced with out introducing other adverse consequences.
[0046] In some embodiments, higher diversion volumes can be used to
further reduce the risk of sample contamination. For example,
depending on the sensitivity of the test for which the sample is
being collected, larger volumes of bodily-fluid can be diverted to
further reduce the likelihood of contamination where the test is
highly sensitive to dermally-residing microbes and/or other
contaminants.
[0047] In some embodiments, the diversion volume can be optimized
for the needle size being use to obtain the bodily-fluid sample.
For example, smaller gauge needles tend to dislodge fewer dermally
residing microbes, therefore, smaller diversion volumes can yield a
similar contamination reduction (e.g., number of false positives).
Thus, smaller needles can be used for smaller, difficult, or
compromised veins/patients to reduce the diversion volume required
for the IDST.
[0048] Referring now to FIGS. 2-12, a transfer device 200 includes
a housing 201, a flow control mechanism 230, an actuator 270, and a
fluid reservoir 280 (also referred to herein as "first fluid
reservoir" or "first reservoir"). As further described herein, the
transfer device 200 can be moved between a first, a second, and a
third configuration to deliver a flow of a bodily-fluid that is
substantially free from microbes exterior to the body, such as, for
example, dermally residing microbes. The transfer device 200 can be
any suitable shape, size, or configuration. For example, while
shown in FIG, 2 as being substantially cylindrical, the transfer
device 200 can be polygonal (rectangular, hexagonal, etc.), oval
(elliptical, egg-shaped, etc.), and/or any other non-cylindrical
shape.
[0049] The housing 201 includes a proximal end portion 202 and a
distal end portion 203. The distal end portion 203 is a
substantially closed portion of the housing 201 and includes one or
more vents 214, as further described in detail herein. Moreover, a
set of annular walls 205 are configured to extend from the distal
end portion 203 towards the proximal end portion 202 to define an
inner volume 207 therebetween. The proximal end portion 202 of the
housing 201 is substantially open such that the inner volume 207
can receive at least a portion of the flow control mechanism 230
(see e.g., FIG. 3).
[0050] As shown in FIGS. 4 and 5, the housing 201 further includes
an inlet port 208, an outlet port 210, and an engagement portion
212. The engagement portion 212 extends from. opposite sides of an
outer surface of the walls 205, as shown in FIG. 4. The engagement
portion 212 includes one or more retention tabs 213 that can be
placed in contact with a portion of the actuator 270 to selectively
limit a movement of the actuator 270 relative to the housing 201,
as further described in detail herein. In addition, the engagement
portion 212 can be engaged by a user during operation to facilitate
the movement of the transfer device 200 between the first, second,
and third configurations, as further described herein.
[0051] The inlet port 208 included in the housing 201 is in fluid
communication with the inner volume 207. More specifically, the
inlet port 208 defines an inlet lumen 209 that is in fluid
communication with the inner volume 207. In this manner, the inlet
port 208 extends from a portion of the wall 205 defining the inner
volume 207 such that the inner volume 207 can be placed in fluid
communication with a volume substantially outside the housing 201,
via the inlet lumen 209. The inlet port 208 can be fluidically
coupled to a medical device (not shown) that defines a fluid flow
pathway for withdrawing and/or conveying the bodily-fluid from a
patient to the transfer device 200. For example, the inlet port 208
can be fluidically coupled to a needle or other lumen-containing
device (e.g., flexible sterile tubing). Similarly stated, the inlet
lumen 209 defined by the inlet port 208 is placed in fluid
communication with a lumen defined by a lumen-containing device,
when the lumen-containing device is coupled to the inlet port 208.
Expanding further, when the lumen-containing device is disposed
within a portion of a body of the patient (e.g., within a vein of
the patient), the inner volume 207 of the housing 201 is placed in
fluid communication with the portion of the body of the
patient.
[0052] The outlet port 210 included in the housing 201 defines an
outlet lumen 211. As shown in FIG. 5, the outlet lumen 211 is
configured to be in fluid communication with the inner volume 207
of the housing 201 (e.g., the outlet lumen 211 extends through the
wall 205 defining the inner volume 207). While not shown in FIGS.
2-12, the outlet port 210 can be fluidically coupled to an external
fluid reservoir (also referred to herein as "second fluid
reservoir" or "second reservoir"), as further described in detail
herein.
[0053] As shown in FIG. 6, the actuator 270 includes a proximal end
portion 271 and a distal end portion 272. The proximal end portion
271 is a substantially closed portion of the actuator 270 from
which a set of annular walls 273 extend. The annular walls 273
define an inner volume 279 that can receive a portion of the
housing 201 and a portion of the flow control mechanism 230. More
specifically, the distal end portion 272 of the actuator 270 is
substantially open such that the portion of the housing 201 and the
portion of the flow control mechanism 230 can be disposed within
the inner volume 279 of the actuator 270. In this manner, the
actuator 270 can be moved between a first position (e.g., a
proximal position) and a second position (e.g., a distal position),
relative to the housing 201, to move the transfer device 200
between the first, second, and third configuration.
[0054] The walls 273 of the actuator 270 define a first channel 274
and a second channel 276. Expanding further, when the portion of
the housing 201 is disposed within the inner volume 279 of the
actuator 270, the outlet port 210 of the housing 201 extends
through the first channel 274 and the inlet port 208 of the housing
201 extends through the second channel 276. In this manner, the
outlet port 210 and the inlet port 208 of the housing 201 can move
within the first channel 274 and the second channel 276,
respectively, when the actuator 270 is moved between its first
position and its second position, relative to the housing 201.
[0055] The actuator 270 further includes a tab 277 that can
selectively engage the inlet port 208 when the inlet port 208 is
disposed within the second channel 276. Expanding further, the tab
277 extends from a surface of the wall 273 of the actuator 270 and
includes a defounable portion 278 that can be deformed to move the
tab 277 from a first configuration to a second configuration, as
indicated by the arrow AA in FIG. 6. In this manner, the tab 277
can selectively limit the movement of the actuator 270 from its
first position to its second position, relative to the housing 201.
Similarly, the wall 273 of the actuator 270 defining the first
channel 274 is configured to form a shoulder 275 that can engage
the retention tabs 213 (described above) of the housing 201. The
arrangement of the shoulder 275 and the retention tabs 213 is such
that the when in contact, the shoulder 275 and the retention tabs
213 collectively limit the movement of the actuator 270 from its
second position to its first position, relative to the housing 201,
as described in further detail herein.
[0056] As shown in FIGS. 7-9, the flow control mechanism 230
includes a first control member 231, a second control member 245, a
first plunger 255, and a second plunger 260. At least a portion of
the flow control mechanism 230 is movably disposed within the inner
volume 207 of the housing 201. More specifically, the flow control
mechanism 230 can be disposed within the inner volume 207 of the
housing 201 such that as the actuator 270 is moved from its first
position to its second position, the flow control mechanism 230 is
moved between a first, a second, and a third configuration, as
further described herein.
[0057] As shown in FIG. 7, the first control member 231 is a
substantially cylindrical elongate member and includes a proximal
end portion 232 and a distal end portion 233. The distal end
portion 233 is disposed within a portion of the first plunger 255.
The proximal end portion 232 includes a set of protrusions 234 that
extend outward from a surface of the proximal end portion 232. The
protrusions 234 include a proximal surface 235, which can be placed
in contact with a portion of the actuator 270, and a distal surface
236, which can be placed in contact with a portion of the second
control member 245. Therefore, when the actuator 270 is moved from
its first position to its second position relative to the housing
201, the actuator 270 can move the first control member 231 within
the inner volume 207. Moreover, the movement of the first control
member 231 within the inner volume 207 can be such that the flow
control mechanism 230 is moved between its first, second, and third
configurations, as further described herein. While shown in FIG, 7
as including four protrusions 234, in other embodiments, the first
control member 232 can include any suitable number of protrusions
234. For example, in some embodiments, a first control member can
include more than four protrusions. In other embodiments, a first
control member can include fewer than four protrusions.
[0058] The second control member 245 includes a proximal end
portion 246 and a distal end portion 247, and defines a void 248
therethrough. The proximal end portion 246 of the second control
member 245 includes a collar 249 that is configured to circumscribe
the proximal end portion 246. Similarly stated, the collar 249 has
a diameter that is substantially larger than the diameter of the
proximal end portion 246 of the second control member 245. The
proximal end portion 246 and the distal end portion 247 are
substantially open such that the second control member 245 is
substantially annular. In this manner, the second control member
245 is configured to be movably disposed about a portion of the
first control member 231 (see e.g., FIGS. 8 and 9).
[0059] As shown in FIG. 7, the first plunger 255 includes a seal
element 257 and defines a recess 258. The recess 258 is configured
to receive the distal end portion 233 of the first control member
231, as shown in FIG. 8. The first plunger 255 can be any suitable
shape, size, or configuration. For example, in some embodiments,
the first plunger 255 can have a diameter that substantially
corresponds to an inner diameter of the walls 205 of the housing
201. More specifically, the diameter of the first plunger 255 can
be substantially larger than the inner diameter of the walls 205
such that when the first plunger 255 is disposed within the inner
volume 207 of the housing 201, the seal element 257 forms a
substantially fluid tight seal with an inner surface of the walls
205. In this manner, the first plunger 255 can fluidically isolate
a portion of the inner volume 207 that is distal to the first
plunger 255 from a portion of the inner volume 207 that is proximal
to the first plunger 255.
[0060] The second plunger 260 includes a proximal end portion 261
and a distal end portion 262, and defines an inner volume 268
therethrough. In this manner, the second plunger 260 can be
disposed about the second control member 245. Similarly stated, the
second plunger 260 can be substantially annular and can
substantially circumscribe the second control member 245 such that
the second control member 245 is disposed within the inner volume
268. The proximal end portion 261 includes a first seal element 263
that forms a shoulder 264 configured to be placed in contact with
the collar 249 (described above) when the second plunger 260 is
disposed about the second control member 245. Similarly, the distal
end portion 262 includes a second seal element 265 and a third seal
element 266 configured to form an inner shoulder 267. The inner
shoulder 267 can be placed in contact with the distal end portion
247 of the second control member 245 when the second plunger 260 is
disposed about the second control member 245.
[0061] As shown in FIG. 9, the first seal element 263 and the
second seal element 265 are configured to extend beyond an outer
surface of the second plunger 260. Similarly stated, the first seal
element 263 and the second seal element 265 have a diameter that is
at least slightly larger than a diameter of a portion of the second
plunger 260 that is disposed between the first seal element 263 and
the second seal element 265. Moreover, the diameter of the first
seal element 263 and the second seal element 265 is configured to
be at least slightly larger than the inner diameter of the walls
205 defining the inner volume 207. Thus, the first seal element 263
and the second seal element 265 form a substantially fluid tight
seal with the inner surface of the walls 205. In addition, the
diameter of the portion of the second plunger 260 that is disposed
between the first seal element 263 and the second seal element 265
can be at least slightly smaller than the inner diameter of the
walls 205. Therefore, the portion of the second plunger 260
(between the first and second seal elements 263 and 265) and the
inner surface of the walls 205 define a void 269 that substantially
circumscribes the portion of the second plunger 260. Furthermore,
the first seal element 263 fluidically isolates the void 269 from a
volume that is distal to the first seal element 263 and the second
seal element 265 fluidically isolates the void 269 from a volume
that is proximal to the second seal element 265.
[0062] The third seal element 266 is configured to extend beyond an
inner surface of the second control member 245 such that when the
first control member 231 is disposed within the void 248 of the
second control member 245 (described above), the third seal element
266 forms a substantially fluid tight seal with an outer surface of
the first control member 231. In this manner, the first control
member 231 can be moved relative to the second control member 245
while fluidically isolating a volume that is proximal to the third
seal element 266 from a volume that is distal to the third seal
element 266, as further described herein.
[0063] The arrangement of the second plunger 260 and the second
control member 245 can be such that the second control member 245
provides structural rigidity for the second plunger 260. In this
manner, the flow control mechanism 230 can move within the inner
volume 207 of the housing 201 without the first seal element 263,
the second seal element 265, and/or the third seal element 266
deforming a sufficient amount to disrupt the substantially fluid
tight seal or seals. While shown in FIGS. 2-12 as including a
second control member 245 that is independent of the second plunger
260 (e.g., not monolithically formed), in other embodiments, the
second plunger 260 and the second control member 245 can be
monolithically formed while maintaining a desired structural
rigidity.
[0064] Referring back to FIG. 8, the first reservoir 280 can be
defined between a proximal surface of the first plunger 255 and the
distal surface of the second plunger 260. More specifically, the
first reservoir 280 is formed by a portion of the inner volume 207
of the housing 201 that is fluidically isolated between the first
plunger 255 (e.g., the seal element 257) and the second plunger 260
(e.g., the second and third seal elements 265 and 266). In this
manner, the first reservoir 280 can be an annular volume between
the outer surface of the first control member 231 of the flow
control mechanism 230 and the inner surface of the walls 205
defining the inner volume 207. Thus, the first reservoir 280 can be
in fluid communication with the inlet port 208 of the housing 201
to receive an amount of a bodily-fluid and fluidically isolate the
amount of the bodily-fluid from a volume substantially outside the
first reservoir 280, as further described below.
[0065] As shown in FIG. 8, the transfer device 200 is in the first
configuration when the actuator 270 is in its first position and
the flow control mechanism 230 is in its first configuration. In
this manner, a user can engage the transfer device 200 to couple
the inlet port 208 to a proximal end portion of a lumen-defining
device (not shown) such as, for example, a butterfly needle. With
the inlet port 208 coupled to the lumen-defining device the inlet
lumen 209 is placed in fluid communication with the lumen defined
by the lumen-defining device. Furthermore, the distal end portion
of the lumen-defining device can be disposed within a portion of
the body of a patient (e.g., a vein), thus, the inlet lumen 209 is
in fluid communication with the portion of the body of the patient.
In a similar manner, the outlet port 210 can be coupled to an
external fluid reservoir (not shown). The external fluid reservoir
(i.e., the second reservoir) can be any suitable reservoir. For
example, in some embodiments, the external fluid reservoir can be a
BacT/ALERT.RTM. SN or a BacT/ALERT.RTM. FA, manufactured by
BIOMERIEUX, INC. The outlet port 210 can be coupled to a needle and
the transfer device 200 can include a container shroud (not shown)
disposed about the needle and configured to receive a portion of
the external fluid reservoir and protect the user from inadvertent
needle sticks.
[0066] With the inlet port 208 coupled to the lumen-defining device
and the outlet port 210 coupled to the external fluid reservoir, a
user can place the transfer device 200 in the second configuration
by moving the tab 277 of the actuator 270 to the second
configuration. More specifically, the user can apply a force to
bend the tab 277 about an axis defined by the deformable portion
278, thus, the tab 277 bends at the deformable portion 278, as
indicated by the arrow AA in FIG. 6. In this manner, the tab 277 is
moved relative to the inlet port 208 such that the tab 277 no
longer limits the movement of the actuator 270 relative to the
housing 201.
[0067] With the tab 277 no longer limiting the movement of the
actuator 270, the user can engage the actuator and the engagement
portion 212 of the housing 201 to apply an activation force on the
actuator 270. In this manner, the actuator 270 and a portion of the
flow control mechanism 230 are moved in the distal direction
towards the second position, as shown by the arrow BB in FIG. 10,
placing the transfer device in the second configuration. More
specifically, in its first configuration, the first control
mechanism 231 is arranged such that the proximal surfaces 235 of
the protrusions 234 (described above) are in contact with the
actuator 270 while the distal surfaces 236 of the protrusions 234
are spaced apart from the collar 249 of the second control member
245 (see FIG. 8). In this manner, a portion of the activation force
is transferred to the first control member 231 to move the first
control member 231 in the distal direction relative to the second
control member 245 and the second plunger 260. Furthermore, with
the distal end portion 233 of the first control member 231 disposed
within the recess 258 of the first plunger 255, the first control
member 231 moves the first plunger 255 in the direction of the
arrow BB.
[0068] With the first plunger 255 forming a substantially fluid
tight seal with the inner surface of the walls 205, the movement of
the first plunger 255 relative to the housing 201 compresses air
disposed within a portion of the inner volume 207 that is distal to
the first plunger 255. In this manner, the vents 214 defined by the
housing 201 (described above) can allow the air to exit the portion
of the inner volume 207. Thus, the likelihood of the pressurized
air within the portion of the inner volume 207 to disrupt the
substantially fluid tight seal formed between the first plunger 255
and the inner surface of the walls 205 is reduced. Furthermore, the
distal movement of the first control member 231 and the first
plunger 255 relative to the second control member 245 and the
second plunger 260 such that the height of the first reservoir 280
is increased (i.e., the volume of the first reservoir 280 is
increased). With the first reservoir 280 fluidically isolated (as
described above) the increase in the volume produces a negative
pressure (i.e., vacuum) within the fluid reservoir 280.
[0069] As shown by the arrow CC, the inlet lumen 209 of the inlet
port 208 defines a fluid flow path such that the fluid reservoir
280 is in fluid communication with the inlet port 208. Furthermore,
with the inlet port 208 coupled to the lumen-defining device the
fluid reservoir 280 is placed in fluid communication with the
portion of the patient (e.g., the vein). The negative pressure
within the fluid reservoir 280 is such that the negative pressure
differential introduces a suction force within the portion of the
patient. In this manner, a bodily-fluid is drawn into the fluid
reservoir 280. In some embodiments, the bodily-fluid can contain
undesirable microbes such as, for example, dermally-residing
microbes. In some embodiments, the bodily-fluid can contain, for
example, microbes dislodged from the keratin layer of the skin
during the venipuncture. Moreover, the volume of the bodily-fluid
drawn into the fluid reservoir 280 can be sufficiently large to
collect at least a portion of the dermally-residing microbes while
being sufficiently small such as to not compromise culture
sensitively (e.g., blood culture sensitivity).
[0070] In some embodiments, the magnitude of the suction force can
be modulated by increasing or decreasing the amount of activation
force applied to the actuator 270. For example, in some
embodiments, it can be desirable to limit the amount of suction
force introduced to a vein. In such embodiments, the user can
reduce the amount of force applied to the actuator 270 to reduce
the rate at which the volume of the first reservoir 280 increases.
In this manner, the suction force is reduced within the vein of the
patient.
[0071] With the desired amount of bodily-fluid transferred to the
fluid reservoir 280, a user can engage the transfer device 200 to
move the transfer device 200 from the second configuration to the
third configuration, wherein a flow of bodily-fluid is transferred
to the external reservoir (e.g., such as those described above). In
some embodiments, the desired amount of bodily-fluid transferred to
the first reservoir 280 is a predetermined amount of fluid. For
example, in some embodiments, the transfer device 200 can be
configured to transfer bodily-fluid until the pressure within the
first reservoir 280 is in equilibrium with the pressure of the
portion of the body in which the lumen-defining device is disposed
(e.g., the vein). In such embodiments, the equalizing of the
pressure between the first reservoir 280 and the portion of the
body stops the flow of the bodily-fluid into the first reservoir
280. In some embodiments, the predetermined amount of bodily-fluid
(e.g., volume) is at least equal to the combined volume of the
inlet lumen 209 and the lumen-defining device. In some embodiments,
the predetermined amount of bodily-fluid can be, for example,
approximately 2.25 mL. In other embodiments, the predetermined
amount of bodily-fluid can be between approximately 0.5 mL and
approximately 5 mL. Still in other embodiments, the predetermined
amount of bodily-fluid can be as little as a single or few drops of
fluid to between approximately 0.1 mL and 0.5 mL.
[0072] As shown in FIG. 11, the transfer device 200 can be moved
from the second configuration to the third configuration by further
moving the actuator 270 in the distal direction to a third
position, as indicated by the arrow DD. Expanding further, the user
can apply an activation force to the actuator 270 and the
engagement portion 212 of the housing 201 such that the actuator
270 and the first control member 231 move in the distal direction.
Moreover, as the actuator 270 is moved from the second
configuration, the distal surfaces 236 of the protrusions 234
included in the first control mechanism 231 are brought into
contact with the collar 249 of the second control member 245.
Therefore, the first control member 231 transfers a portion of the
activation force to the second control member 245 such that the
second control member 245 and the second plunger 260 move
concurrently with the first control member 231 and the first
plunger 255 (i.e., the flow control mechanism 230 moves in the
distal direction, relative to the housing 201). With the desired
amount of the bodily-fluid disposed within the first reservoir 280
the volume of the first reservoir 280 is configured to remain
constant as the flow control mechanism 230 moves relative to the
housing 201. Similarly stated, the pressure within the fluid
reservoir is configured to remain substantially unchanged as the
transfer device 200 is moved from the second configuration to the
third configuration.
[0073] The actuator 270 is configured to move the flow control
mechanism 230 within the inner volume 207 of the housing 201 such
that the first reservoir 280 is fluidically isolated from the inlet
port 208. Moreover, the flow control mechanism 230 can be moved in
the distal direction a sufficient amount such that the second seal
element 265 of the second plunger 260 is moved to a distal position
relative to the inlet lumen 209 defined by the inlet port 208. In
addition, the distal movement of the flow control mechanism 230 is
such that the first seal element 263 of the second plunger 260 is
maintained in a proximal position relative to the outlet lumen 211
defined by the outlet port 210. In this manner, the void 269
(described above) is in fluid communication with the inlet lumen
209 and the outlet lumen 211.
[0074] As shown by the arrow EE, the inlet lumen 209 of the inlet
port 208, the void 269, and the outlet lumen 211 of the outlet port
210 define a fluid flow path such that the external reservoir (not
shown in FIG. 11) is in fluid communication with the inlet port 208
and, therefore, the portion of the patient (e.g., the vein).
Furthermore, the external reservoir is configured to define a
negative pressure (e.g., the known external reservoirs referred to
herein are vessels defining a negative pressure). The negative
pressure within the external reservoir is such that the negative
pressure differential between the external reservoir and the
portion of the body of the patient introduces a suction force
within the portion of the patient. Therefore, a desired amount of
bodily-fluid is drawn into the external reservoir and is
fluidically isolated from the first, predetermined amount of
bodily-fluid contained within the first reservoir 280. In this
manner, the bodily-fluid contained in the external reservoir is
substantially free from microbes generally found outside of the
portion of the patient (e.g., dermally residing microbes, microbes
within a lumen defined by the transfer device 200, microbes within
the lumen defined by the lumen defining device, and/or any other
undesirable microbe). With the desired amount of bodily-fluid
contained in the external fluid reservoir, the external reservoir
can be decoupled from the transfer device 200.
[0075] As shown in FIG. 12, the movement of the transfer device 200
to the third configuration is such that the retention tabs 213
(described above) are placed in contact with the shoulder 275 of
the actuator 270 (described above). The retention tabs 213 and the
shoulder 275 collectively maintain the transfer device 200 in the
third configuration. Thus, the first amount of bodily-fluid
contained within the first reservoir 280 is maintained in fluidic
isolation from a volume outside of the fluid reservoir 280. In this
manner, the transfer device 200 can be safely discarded or the
volume of bodily fluid contained in the first reservoir 280 can be
used for other testing such as, for example, testing where dermally
residing microbes would not affect the test results.
[0076] While the transfer device 200 is shown and described in
FIGS. 2-12 as including a discrete actuator 270, in some
embodiments, a transfer device can include a fluid reservoir
configured to actuate the transfer device. For example, FIGS. 13-19
illustrate a transfer device 300 according to an embodiment. The
transfer device 300 includes a housing 301, a container shroud 320,
a flow control mechanism 330 defining a first fluid reservoir 380,
and a second fluid reservoir 390. The transfer device 300 can be
any suitable shape, size, or configuration. For example, while
shown in FIG. 13 as being substantially cylindrical, the transfer
device 300 can be polygonal (rectangular, hexagonal, etc.), oval
(elliptical, circular, etc.), and/or any other non-cylindrical
shape. As further described below, the transfer device 300 can be
moved between a first, a second, and a third configuration to
deliver a flow of a bodily-fluid that is substantially free from
microbes exterior the body, such as, for example, dermally residing
microbes.
[0077] As shown in FIGS. 13 and 14, the housing 301 includes a
proximal end portion 302, a distal end portion 303, and a tapered
portion 304, and defines an inner volume 307 and an aperture 306.
The distal end portion 303 is a substantially closed portion of the
housing 301 and extends in the proximal direction towards the
tapered portion 304. The proximal end portion 302 of the housing
301 is substantially open such that the inner volume 307 can
movably receive the flow control mechanism 330 and at least a
portion of the second fluid reservoir 390. As shown, the proximal
end portion 302 has a diameter that is substantially larger than a
diameter of the distal end portion 303 of the housing 301. In this
manner, the tapered portion 30.4 extends from the proximal end
portion 302 towards the distal end portion 303 at a given angle
such that the tapered portion 304 is a transitional portion between
the larger diameter of the proximal end portion 302 and the smaller
diameter of the distal end portion 303. The aperture 306 defined by
the housing 301 receives a portion of the flow control mechanism
330, as further described herein.
[0078] As shown in FIG. 14, the flow control mechanism 330 includes
a first control member 331, a second control member 345, a first
plunger 355, and a second plunger 360. As described above, the flow
control mechanism 330 is configured to be movably disposed within
the inner volume 307 of the housing 301. More specifically, the
flow control mechanism 330 can be moved within the housing 301
between a first, a second, and a third configuration.
[0079] The first control member 331 has a shape that substantially
corresponds to the shape of the housing 301 and includes a proximal
end portion 332, a distal end portion 333, and a tapered portion
337 disposed therebetween. The first control member 331 also
defines an inner volume 341 (see e.g., FIG. 15) and a channel 338.
The distal end portion 333 is a closed portion of the first control
member 331 and is coupled to the first plunger 355, as further
described herein. The proximal end portion 332 is substantially
open such that the inner volume 341 can receive the second control
member 345, the first plunger 355, and the second plunger 360. The
proximal end portion 332 further includes a set of extensions 339
that define a set of slots 340. The extensions 339 can be movably
disposed within a portion of the container shroud 32.0 and can be
placed in contact with a portion of the second fluid reservoir 390,
as further described herein. The channel 338 (FIG. 15) movably
receives a portion of the second control member 345, as further
described below.
[0080] The second control member 345 includes a proximal end
portion 346, a distal end portion 347, and defines an inner volume
348. The distal end portion 347 is substantially open such that the
inner volume 348 can receive at least a portion the first plunger
355 and the second plunger 360. The proximal end portion 346
includes an inlet port 350 and an outlet port 352. The inlet port
350 is in fluid communication with the inner volume 348 and extends
from a portion of the wall of the second control member 345
defining the inner volume 348. Moreover, the inlet port 350 can be
coupled to an adapter 354 (e.g., a Luer-Lokt or the like) such that
when the flow control mechanism 330 is disposed within the housing
301, the adapter 354 extends through the channel 338 in the first
control mechanism 331 and through the aperture 306 defined by the
housing 301. The adapter 354 can further be fluidically coupled to
a medical device (not shown) that defines a fluid flow pathway for
withdrawing and/or conveying the bodily-fluid from a patient to the
transfer device 300. For example, the adapter 354 can be
fluidically coupled to a needle or other lumen-containing device
(e.g., flexible sterile tubing) such that the inlet port 350 is in
fluid communication with the lumen-containing device. Expanding
further, when the lumen-containing device is disposed within a
portion of a body of the patient (e.g., within a vein of the
patient), the inner volume 348 of the second control member 345 is
placed in fluid communication with the portion of the body of the
patient. The outlet port 352 included in the second control member
345 is configured to be in fluid communication with the inner
volume 348 and can be fluidically coupled to a portion of the
container shroud 320, as further described herein.
[0081] As shown in FIG. 14, the first plunger 355 includes an
elongate portion 356 and seal element 357. More specifically, the
seal element 357 is disposed at a proximal end of the elongate
portion 356. The seal element 357 can be substantially similar to
the seal element 257 of the first plunger 255 described above with
reference to FIGS. 7 and 8. Thus, the seal element 357 is
configured to form a substantially fluid tight seal with an inner
surface of the second. control member 345. The seal element 357 can
fluidically isolate a portion of the inner volume 348 that is
distal to the first plunger 355 from a portion of the inner volume
348 that is proximal to the first plunger 355, as further described
herein. The elongate portion 356 is configured to be coupled to the
first control member 331 (e.g., via an adhesive, a mechanical
fastener, or any other suitable coupling method). More
specifically, the elongate portion 356 is configured to extend in
the proximal direction from a surface of the first control member
331 (see e.g., FIG. 16).
[0082] The second plunger 360 includes a seal portion 363. The
second plunger 360 is disposed within the inner volume 348 at a
proximal position relative to the first plunger 355 (see e.g., FIG.
16). The seal member 363 is configured to form a substantially
fluid tight seal with the inner surface of the second control
member 345, as described above. While not shown in FIGS. 13-18, the
second plunger 345 is configured to be coupled to the first plunger
355. For example, in some embodiments, the second plunger 345 can
be coupled to the first plunger 355 via one or more tethers. In
this manner, the first plunger 355 can be moved a first distance
relative to the second plunger 360 to place the tethers in tension
such that further movement of the first plunger 355 also moves the
second plunger 360, as further described herein.
[0083] As shown in FIG. 14, the container shroud 320 includes a
proximal end portion 321 and a distal end portion 322. The proximal
end portion 321 is configured to receive a portion of the second
fluid reservoir 390, as further described herein. The distal end
portion 322 includes a port 323 that is coupled to the outlet port
352 of the second control member 345. In this manner, the port 323
included in the container shroud 320 can be placed in fluid
communication with the inner volume 348 of the second control
member 345. As shown in FIG. 16, the port 323 can be configured to
include a needle 326 configured to pierce a portion of the second
fluid reservoir 390, as described in further detail herein. The
container shroud 320 is further configured to define a set of
apertures 324 that movably receive the extensions 329 of the first
control member 331. Similarly stated, at least a portion of the
extensions 339 of the first control member 331 can be inserted into
the apertures 324 defined by the container shroud 320.
[0084] As shown in FIGS. 16-18, the first reservoir 380 can be
defined between a proximal surface of the first plunger 355 and the
distal surface of the second plunger 360. More specifically, the
first reservoir 380 is formed by a portion of the inner volume 348
of the second control member 345 that is fluidically isolated
between the first plunger 355 (e.g., the seal element 357) and the
second plunger 360 (e.g., the seal elements 363). In this manner,
the first reservoir 380 can be placed in fluid communication with
the inlet port 350 of the second control member 345 to receive an
amount of a bodily-fluid and can fluidically isolate the amount of
the bodily-fluid from a volume substantially outside the first
reservoir 380, as further described below.
[0085] At least a portion of the second reservoir 390 is disposed
within the housing 301. More specifically, a portion of the second
reservoir 390 is movably disposed within the container shroud 320
housed by the housing 301. The second reservoir 390 can be any
suitable reservoir. For example, in some embodiments, the second
fluid reservoir 390 can be a BacT/ALERT.RTM. SN or a
BacT/ALERT.RTM. FA, manufactured by BIOMERIEUX, INC. The second
reservoir 390 includes a piercable septum 393 that can be pierced
by, for example, the needle 326 included in the port 323 of the
container shroud 320 such that an inner volume 392 defined by the
second reservoir 390 can receive a flow of the bodily-fluid.
Moreover, the second reservoir 390 can be moved relative to the
housing 301 to actuate the transfer device 300. Similarly stated,
the second reservoir 390 can be moved relative to the housing 301
to move the transfer device 300 between the first, second, and
third configurations, as described below.
[0086] As shown in FIG, 16, the transfer device 300 is in the first
configuration when the second fluid reservoir 390 is in a first
position (e.g., a proximal position) relative to the housing 301
and when the flow control mechanism 330 is in its first
configuration. In this manner, a user can engage the transfer
device 300 to couple the adapter 354 to a proximal end portion of a
lumen-defining device (not shown) such as, for example, a butterfly
needle. With the adapter 354 coupled to the lumen-defining device,
the inlet port 350 is placed in fluid communication with the lumen
defined by the lumen-defining device. Furthermore, the distal end
portion of the lumen-defining device can be disposed within a
portion of the body of a patient (e.g., a vein), thus, the inlet
port 350 is in fluid communication with the portion of the body of
the patient.
[0087] With the inlet port 350 coupled to the lumen-defining
device, a user can place the transfer device 300 in the second
configuration by moving the second reservoir 390 in the distal
direction relative to the housing 301, as indicated by the arrow FF
in FIG. 17. More specifically, the distal movement places a portion
of the second reservoir 390 in contact with the extensions 339 of
the first control member 331 such that the extensions 339 move
within the apertures 324 defined by the container shroud 320. In
this manner, the second reservoir 390 moves the first control
member 331 within the inner volume 307 relative to the second
control member 345.
[0088] With the first plunger 355 coupled to the first control
member 331, the second reservoir 390 also urges the first plunger
355 to move within the inner volume 348 of the second control
member 345 such that the flow control mechanism 330 is placed in
its second configuration, as shown in FIG, 17. The distal movement
of the first control member 331 and the first plunger 355 relative
to the second control member 345 and the second plunger 360 is such
that the height of the first reservoir 380 is increased (i.e., the
volume of the first reservoir 380 is increased). With the first
reservoir 380 fluidically isolated (as described above), the
increase in the volume produces a negative pressure within the
fluid reservoir 380.
[0089] As shown by the arrow GC, the inlet port 350 defines a fluid
flow path such that the fluid reservoir 380 is in fluid
communication with the inlet port 350. Furthermore, with the inlet
port 350 coupled to the lumen-defining device (e.g., via the
adapter 354) the fluid reservoir 380 is placed in fluid
communication with the portion of the patient (e.g., the vein). The
negative pressure within the fluid reservoir 380 is such that the
negative pressure differential introduces a suction force within
the portion of the patient. In this manner, a bodily-fluid is drawn
into the fluid reservoir 380. In some embodiments, the bodily-fluid
can contain undesirable microbes such as, for example,
dermally-residing microbes.
[0090] With the desired amount of bodily-fluid transferred to the
fluid reservoir 380, a user can move the transfer device 300 from
the second configuration to the third configuration, wherein a flow
of bodily-fluid is transferred to the second reservoir 390. In some
embodiments, the desired amount of bodily-fluid transferred to the
first reservoir 380 is a predetermined amount of fluid. For
example, in some embodiments, the transfer device 300 can be
configured to transfer bodily-fluid until the pressure within the
first reservoir 380 is in equilibrium with the pressure of the
portion of the body in which the lumen-defining device is disposed
(e.g., the vein). In such embodiments, the equalizing of the
pressure between the first reservoir 380 and the portion of the
body stops the flow of the bodily-fluid into the first reservoir
380. In some embodiments, the predetermined amount of bodily-fluid
(e.g., volume) is at least equal to the combined volume of the
inlet port 350 and the lumen-defining device.
[0091] As shown in FIG. 18, the transfer device 300 can be moved
from the second configuration to the third configuration by further
moving the second reservoir 390 in the distal direction, as
indicated by the arrow MI. The additional movement of the second
reservoir 390 in the distal direction is such that the port 323 of
the container shroud 320 is brought into contact with the second
reservoir 390. More specifically, the needle 326 of the port 323
pierces the piercable septum 393 of the second reservoir 390 to
place the port :323 in fluid communication with the inner volume
392 of the second reservoir 390.
[0092] In addition, as the second reservoir 390 is moved from the
second configuration, the tethers (not shown) between the first
plunger 355 and the second plunger 360 are placed in tension.
Therefore, the first plunger 355 transfers a portion of the
activation force (e.g., applied on the second reservoir 390 by the
user) to the second plunger 360. In this manner, the second plunger
360 is moved concurrently with the first control member 331 and the
first plunger 355 (e.g., the flow control mechanism 330 is moved to
its third configuration). With the desired amount of the
bodily-fluid disposed within the first reservoir 380 the volume of
the first reservoir 380 is configured to remain constant as the
flow control mechanism 330 moves relative to the housing 301.
Similarly stated, the pressure within the fluid reservoir is
configured to remain substantially unchanged as the transfer device
300 is moved from the second configuration to the third
configuration.
[0093] When the flow control mechanism 330 is moved toward its
third configuration, the first control member 331 is configured to
move the first plunger 355, and the second plunger 360 within the
inner volume 348 of the second control member 345 such that the
first reservoir 380 is fluidically isolated from the inlet port
350. Moreover, the second plunger 360 can be moved in the distal
direction a sufficient amount such that the second plunger 360 is
moved to a distal position relative to the inlet port 350.
[0094] With the second plunger 360 in the distal position relative
to the inlet port 350, the inlet port 350, a portion of the inner
volume 348, the outlet port 350, and the port 323 define a fluid
flow path, as indicated by the arrow IL. In this manner, the inner
volume 392 of the second reservoir is placed in fluid communication
with the inlet port 350 and, therefore, the portion of the patient
(e.g., the vein). Furthermore, the second reservoir 390 is
configured to define a negative pressure (e.g., the known
reservoirs referred to herein are vessels defining a negative
pressure) such that the negative pressure differential between the
second reservoir 390 and the portion of the body of the patient
introduces a suction force within the portion of the patient.
Therefore, a desired amount of bodily-fluid is drawn into the inner
volume 392 of the second reservoir 390 and is fluidically isolated
from the first, predetermined amount of bodily-fluid contained
within the first reservoir 380. In this manner, the bodily-fluid
contained in the second reservoir 390 is substantially free from
microbes generally found outside of the portion of the patient
(e.g., dermally residing microbes, microbes within a lumen defined
by the transfer device 300, microbes within the lumen defined by
the lumen defining device, and/or any other undesirable microbe).
With the desired amount of bodily-fluid contained in the second
reservoir 390, the second reservoir 390 can be decoupled from the
transfer device 300. Furthermore, the first amount of bodily-fluid
contained within the first reservoir 380 is maintained in fluidic
isolation from a volume outside of the fluid reservoir 380. In this
inarmer, the transfer device 300 can be safely discarded.
[0095] 119951 While various embodiments have been described above,
it should be understood that they have been presented by way of
example only, and not limitation. Where methods and steps described
above indicate certain events occurring in certain order, those of
ordinal), skill in the art having the benefit of this disclosure
would recognize that the ordering of certain steps may be modified
and that such modifications are in accordance with the variations
of the invention. Additionally, certain of the steps may be
performed concurrently in a parallel process when possible, as well
as performed sequentially as described above. Additionally, certain
steps may be partially completed and/or omitted before proceeding
to subsequent steps.
[0096] While various embodiments have been particularly shown and
described, various changes in form and details may be made. For
example, although various embodiments have been described as having
particular features and/or combinations of components, other
embodiments are possible having any combination or sub-combination
of any features and/or components from any of the embodiments
described herein.
[0097] The specific configurations of the various components can
also be varied. For example, the size and specific shape of the
various components can be different than the embodiments shown,
while still providing the functions as described herein. More
specifically, the size and shape of the various components can be
specifically selected for a desired rate of bodily-fluid flow into
a fluid reservoir.
* * * * *