U.S. patent number RE36,350 [Application Number 09/127,556] was granted by the patent office on 1999-10-26 for fully integrated miniaturized planar liquid sample handling and analysis device.
This patent grant is currently assigned to Hewlett-Packard Company. Invention is credited to Fritz Bek, Patrick Kaltenbach, Laurie S. Mittelstadt, Sally A. Swedberg, Klaus E. Witt.
United States Patent |
RE36,350 |
Swedberg , et al. |
October 26, 1999 |
Fully integrated miniaturized planar liquid sample handling and
analysis device
Abstract
A miniaturized total analysis system (".mu.-TAS") comprising a
miniaturized planar column device is described for use in liquid
phase analysis. The .mu.-TAS comprises microstructures fabricated
by laser ablation in a variety of novel support substrates. The
.mu.-TAS includes associated laser-ablated features required for
integrated sample analysis, such as analyte detection means and
fluid communication means. .mu.-TAS constructed according to the
invention is useful in any analysis system for detecting and
analyzing small and/or macromolecular solutes in the liquid phase
and may employ chromatographic separation means, electrophoretic
separation means, electrochromatographic separation means, or
combinations thereof.
Inventors: |
Swedberg; Sally A. (Los Altos,
CA), Kaltenbach; Patrick (Bischweier, DE), Witt;
Klaus E. (Keltern, DE), Bek; Fritz (Waldbronn,
DE), Mittelstadt; Laurie S. (Belmont, CA) |
Assignee: |
Hewlett-Packard Company (Palo
Alto, CA)
|
Family
ID: |
26985248 |
Appl.
No.: |
09/127,556 |
Filed: |
July 30, 1998 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
|
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326111 |
Oct 19, 1994 |
5500071 |
|
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Reissue of: |
486024 |
Jun 7, 1995 |
05571410 |
Nov 5, 1996 |
|
|
Current U.S.
Class: |
210/198.2;
204/451; 204/601; 210/656; 422/69; 422/70 |
Current CPC
Class: |
B01L
3/502707 (20130101); B01L 7/54 (20130101); G01N
27/44708 (20130101); G01N 27/44773 (20130101); G01N
27/44791 (20130101); G01N 30/6095 (20130101); B01L
3/0268 (20130101); G01N 2030/303 (20130101); B01L
3/502715 (20130101); B01L 3/5055 (20130101); B01L
2200/025 (20130101); B01L 2200/027 (20130101); B01L
2200/0689 (20130101); B01L 2200/10 (20130101); B01L
2200/12 (20130101); B01L 2300/0816 (20130101); B01L
2300/087 (20130101); B01L 2300/0874 (20130101); B01L
2300/0887 (20130101); B01L 2300/1822 (20130101); B01L
2400/0415 (20130101); B01L 2400/0421 (20130101); B01L
2400/0442 (20130101); B01L 2400/0487 (20130101); B29C
65/02 (20130101); B29C 66/54 (20130101); B29C
66/549 (20130101); G01N 27/44721 (20130101); G01N
30/02 (20130101); G01N 30/60 (20130101); G01N
30/6047 (20130101); G01N 30/6052 (20130101); G01N
30/606 (20130101); G01N 2030/285 (20130101); G01N
2030/3007 (20130101); G01N 2030/3015 (20130101); G01N
30/02 (20130101); G01N 2030/0035 (20130101) |
Current International
Class: |
B01L
7/00 (20060101); B81C 1/00 (20060101); G01N
27/447 (20060101); G01N 30/00 (20060101); G01N
30/60 (20060101); B81B 1/00 (20060101); G01N
30/02 (20060101); G01N 30/28 (20060101); B01D
015/08 () |
Field of
Search: |
;204/601,602,603,604,605,451,452,453,454,455,456
;210/635,656,659,198.2 ;422/68.1,69,70 |
References Cited
[Referenced By]
U.S. Patent Documents
Other References
Becker et al. (1986) "Fabrication of Microstructures with High
Aspect Ratios and Great Structural Heights by Synchrotron Radiation
Lithography, Galvanoforming, and Plastic Moulding (LIGA Process)"
Microelectric Engineering 4:35-56. .
Beckers et al. (1988) J. Chromatogr. 452:591-600. .
Burggraf et al. (1994) "A Novel Approach to Ion Separations in
Solutions: Sychronized Cyclic Capillary Electrophoresis (SCCE)"
Sensors and Actuators B20:103-110. .
Edmonds (1985) Trends Anal. Chem. 4:220. .
Effenhauser et al. (1993) "Glass Chips for High-Speed Capillary
electrophoresis Separations with Submicrometer Plate Heights" Anal.
Chem. 65:2637-2642. .
Fan et al. (1994) "Micromachining of Capillary Electrophoresis
Injectors and Separators on Glass Chips and Evaluation of Flow at
Capillary Intersections" Anal. Chem. 66(1):177-184. .
Frazier et al. (1994) "Development of Micromachined Devices Using
Polyimide-Based Processes" Sensors and Actuators. A45:47-55. .
Fillipini et al. (1991) J. Biotechnol. 18:153. .
Garn et al. (1989) Biotechnol. Bioeng. 34:423. .
Guibault (1983) Anal. Chem. Symp. Ser. 17:637. .
Ghowsi et al. (1990) "Micellar Electrokinetic Capillary
Chromatography theory Based on Electrochemical Parameters:
Optimization for Three Modes of Operation" Anal. Chem.
62:2714-2721. .
Harrison et al. (1993) "Micromachining a Miniaturized Capillary
Electrophoresis-Based Chemical Analysis System on a Chip" Science
261:895-897. .
Harrison et al. (1993) "Towards Miniaturized electrophoresis and
Chemical Analysis Systems on Silicon; an Alternative to Chemical
Sensors" Sens. Actuators. B10(2):107-116. .
Jorgenson et al. (1983) J. Chromtogr. 255:335. .
Knox et al. (1979) J. Chromtogr. 186:405. .
Manz et al. (1990) "Design of an Open-Tubular Column Liquid
Chromatograph Using Silicon Chip Technology" Sensors and Actuators
B (Chemical) B1(1-6):249-255. .
Manz et al. (1991) "Micromachining of Monocrystalline Silicon and
Glass for Chemical Analysis Systems--A Look into Next Century's
Technology or Just a Fashionable Craze?" Trends. Anal. Chem. 10(5);
144-149. .
Manz et al. (1992) "Planar chips technology for miniaturization and
integration of separation techniques into monitoring systems" J.
Chromatogr. 593:253-258. .
Manz et al. (1993) "Planar Chips Technology for Miniaturization of
Separation Systems; A Developing Perspective in Chemical
Monitoring" Adv. Chrom. 33:1-66. .
Muller et al. (1991) J.High Resolut. Chromatogr. 14:174. .
Olefirowicz et al. (1990) "Capillary Electrophoresis in 2 and 5
.mu.m Diameter Capillaries: Application to Cytoplasmic Analysis"
Anal. Chem. 62:1872-1876. .
Second Int'l Symp. High-Perf. Capillary Electrophoresis (1990) J.
Chromatogr. 516. .
Stinshoff et al. (1985) "Clinical Chemistry" Anal. Chem.
57:114R-130R. .
Tshulena (1988) Phys. Scr. T23:293. .
Tsuda et al. (1978) Anal. Chem. 50:632. .
Widmer (1983) Trends Anal. Chem. 2:8. .
Widmer et al. (1984) Int. J. Environ. Anal. Chem. 18:1. .
Znotkins. T. A. et al., Laser Focus Electro Optics pp. 54-70
(1987)..
|
Primary Examiner: Therkorn; Ernest G.
Parent Case Text
CROSS-REFERENCE TO RELATED APPLICATION
This application is a continuation-in-part of U.S. patent
application Ser. No. 08/326,111 filed Oct. 19, 1994, now U.S. Pat.
No. 5,500,071, from which priority is claimed pursuant to 35 U.S.C.
.sctn.120, and which disclosure is hereby incorporated by reference
in its entirety.
Claims
We claim:
1. A miniaturized total analysis system (.mu.-TAS) comprising a
miniaturized column device comprising:
(a) a substrate having first and second substantially planar
opposing surfaces wherein said substrate is comprised of a material
other than silicon or silicon dioxide, said substrate having a
first microchannel laser-ablated in the first planar surface,
wherein said first microchannel comprises more than one sample
handling region;
(b) a cover plate arranged over the first planar surface, said
cover plate in combination with the first microchannel forming a
first sample processing compartment, wherein the sample handling
regions define a sample flow component in fluid communication with
a sample treatment component; and
(c) at least one inlet port and at least one outlet port
communicating with the first sample processing compartment, said
inlet and outlet ports enabling the passage of fluid from an
external source through the sample processing compartment.
2. The .mu.-TAS of claim 1, wherein said first sample processing
compartment comprises a serial arrangement of sample handling
regions which define a serial arrangement of alternating sample
flow components and sample treatment components.
3. The .mu.-TAS of claim 2, further comprising detection means
laser ablated in the substrate, wherein said detection means is in
communication with the first sample processing compartment thereby
enabling the detection of a sample passing through the sample
processing compartment.
4. The .mu.-TAS of claim 3, further comprising detection means
laser ablated in the substrate, wherein said detection means is in
communication with the sample flow component thereby enabling the
detection of a sample passing through the sample processing
compartment.
5. The .mu.-TAS of claim 3, further comprising access ports in
fluid communication of the sample flow component, thereby enabling
the passage of fluid between an external source and the sample flow
component.
6. The .mu.-TAS of claim 2, further comprising access ports in
fluid communication with the sample flow component, thereby
enabling the passage of fluid between an external source and the
sample flow component.
7. The .mu.-TAS of claim 2, further comprising:
(a) a reservoir microstructure laser-ablated in the first planar
surface, wherein the cover plate in combination with said
microstructure define a reservoir compartment having an inlet means
and an outlet means;
(b) a conducting microchannel laser-ablated in the first planar
surface, wherein the cover plate in combination with said
conducting microchannel defines a sample flow component having
first and second ends respectively in fluid communication with the
sample processing compartment and the reservoir compartment outlet
means;
(c) an orifice in divertable fluid communication with the reservoir
compartment inlet means, said orifice enabling the passage of fluid
from an external source into the reservoir compartment; and
(d) a motive means enabling the displacement of a fluid from the
reservoir compartment through the sample flow component and into
the first sample processing compartment.
8. The .mu.-TAS of claim 7, further comprising:
(a) a sample delivery means in fluid communication with the first
sample processing compartment outlet port, said sample delivery
means comprising a mixing chamber in fluid communication and in
axial alignment with a fluid communication means and an outlet
nozzle;
(b) a fluid source in divertable fluid communication with the fluid
communication means; and
(c) a post-column collection device comprising a sample receiving
means positioned relative to the outlet nozzle to receive eluent
from the nozzle means.
9. The .mu.-TAS of claim 2, further comprising:
(a) a sample delivery means in fluid communication with the first
sample processing compartment outlet port, said sample delivery
means comprising a mixing chamber in fluid communication and in
axial alignment with a fluid communication means and an outlet
nozzle;
(b) a fluid source in divertable fluid communication with the fluid
communication means; and
(c) a post-column collection device comprising a sample receiving
means positioned relative to the outlet nozzle to receive eluent
from the nozzle means.
10. The .mu.-TAS of claim 2, further comprising:
(a) a second microchannel having an inlet port and an outlet port
laser ablated in the second planar surface;
(b) a second cover plate disposed over the second planar surface,
said cover plate in combination with the second microchannel
defining a second sample processing compartment;
(c) conduit means for communicating the outlet port of the first
sample processing compartment and the inlet port of the second
sample processing compartment with each other thereby forming a
single continuous sample processing compartment, said conduit means
comprising a laser-ablated aperture in the substrate, said aperture
having an axis which is orthogonal to the planar surfaces.
11. The .mu.-TAS of claim 10, further comprising detection means
comprising apertures laser-ablated respectively in the first and
second cover plates and arranged in co-axial communication with the
conduit means.
12. The .mu.-TAS of claim 11, further comprising access ports in
fluid communication of the sample flow component, thereby enabling
the passage of fluid between an external source and the sample flow
component.
13. The .mu.-TAS of claim 10, further comprising access ports in
fluid communication with the sample flow component, thereby
enabling the passage of fluid between an external source and the
sample flow component.
14. The .mu.-TAS of claim 10, further comprising:
(a) a reservoir microstructure laser-ablated in the first planar
surface, wherein the cover plate in combination with said
microstructure define a reservoir compartment having an inlet means
and an outlet means;
(b) a conducting microchannel laser-ablated in the first planar
surface, wherein the cover plate in combination with said
conducting microchannel defines a sample flow component having
first and second ends respectively in fluid communication with the
sample processing compartment and the reservoir compartment outlet
means;
(c) an orifice in divertable fluid communication with the reservoir
compartment inlet means, said orifice enabling the passage of fluid
from an external source into the reservoir compartment; and
(d) a motive means enabling the displacement of a fluid from the
reservoir compartment through the sample flow component and into
the first sample processing compartment.
15. The .mu.-TAS of claim 14, further comprising:
(a) a sample delivery means in fluid communication with the first
sample processing compartment outlet port, said sample delivery
means comprising a mixing chamber in fluid communication and in
axial alignment with a fluid communication means and an outlet
nozzle;
(b) a fluid source in divertable fluid communication with the fluid
communication means; and
(c) a post-column collection device comprising a sample receiving
means positioned relative to the outlet nozzle to receive eluent
from the nozzle means.
16. The .mu.-TAS of claim 10, further comprising:
(a) a sample delivery means in fluid communication with the first
sample processing compartment outlet port, said sample delivery
means comprising a mixing chamber in fluid communication and in
axial alignment with a fluid communication means and an outlet
nozzle;
(b) a fluid source in divertable fluid communication with the fluid
communication means; and
(c) a post-column collection device comprising a sample receiving
means positioned relative to the outlet nozzle to receive eluent
from the nozzle means.
17. A .mu.-TAS device comprising:
(a) a support body formed from a substrate comprised of a material
other than silicon or silicon dioxide, said support body having
first and second component halves each having substantially planar
interior surfaces;
(b) a first microchannel laser-ablated in the interior surface of
the first support body half and a second microchannel laser-ablated
in the interior surface of the second support body half, wherein
said first and second microchannels are arranged so as to provide
the mirror image of the other;
(c) a sample processing compartment formed by aligning the interior
surfaces of the support body halves in facing abutment with each
other whereby the microchannels define said sample processing
compartment and wherein said sample processing compartment
comprises sample handling regions which define a sample flow
component in fluid communication with a sample treatment component;
and
(d) at least one inlet port and at least one outlet port
communicating with the sample processing compartment, said ports
enabling the passage of fluid from an external source through the
sample processing compartment.
18. The .mu.-TAS of claim 17, wherein said sample processing
compartment comprises a serial arrangement of sample handling
regions which define a serial arrangement of alternating sample
flow components and sample treatment components.
19. The .mu.-TAS of claim 18, further comprising detection means
laser ablated in the substrate, wherein said detection means is in
communication with the sample processing compartment thereby
enabling the detection of a sample passing through the sample
processing compartment.
20. The .mu.-TAS of claim 19, further comprising detection means
laser ablated in the substrate, wherein said detection means is in
communication with the sample flow component thereby enabling the
detection of a sample passing through the sample processing
compartment.
21. The .mu.-TAS of claim 19, further comprising access ports in
fluid communication of the sample flow component, thereby enabling
the passage of fluid between an external source and the sample flow
component.
22. The .mu.-TAS of claim 18, further comprising access ports in
fluid communication with the sample flow component, thereby
enabling the passage of fluid between an external source and the
sample flow component.
23. The .mu.-TAS of claim 18, further comprising:
(a) a reservoir microstructure laser-ablated in the first planar
surface, wherein the cover plate in combination with said
microstructure define a reservoir compartment having an inlet means
and an outlet means;
(b) a conducting microchannel laser-ablated in the first planar
surface, wherein the cover plate in combination with said
conducting microchannel defines a sample flow component having
first and second ends respectively in fluid communication with the
sample processing compartment and the reservoir compartment outlet
means;
(c) an orifice in divertable fluid communication with the reservoir
compartment inlet means, said orifice enabling the passage of fluid
from an external source into the reservoir compartment; and
(d) a motive means enabling the displacement of a fluid from the
reservoir compartment through the sample flow component and into
the sample processing compartment.
24. The .mu.-TAS of claim 23, further comprising:
(a) a sample delivery means in fluid communication with the sample
processing compartment outlet port, said sample delivery means
comprising a mixing chamber in fluid communication and in axial
alignment with a fluid communication means and an outlet
nozzle;
(b) a fluid source in divertable fluid communication with the fluid
communication means; and
(c) a post-column collection device comprising a sample receiving
means positioned relative to the outlet nozzle to receive eluent
from the nozzle means.
25. The .mu.-TAS of claim 18, further comprising:
(a) a sample delivery means in fluid communication with the first
sample processing compartment outlet port, said sample delivery
means comprising a mixing chamber in fluid communication and in
axial alignment with a fluid communication means and an outlet
nozzle;
(b) a fluid source in divertable fluid communication with the fluid
communication means; and
(c) a post-column collection device comprising a sample receiving
means positioned relative to the outlet nozzle to receive eluent
from the nozzle means. .Iadd.
26. The .mu.-TAS device of claim 17, wherein the support body
further comprises a fold means separating said first and second
component halves..Iaddend..Iadd.27. The .mu.-TAS device of claim
18, wherein the support body further comprises a fold means
separating said first and second component
halves..Iaddend..Iadd.28. The .mu.-TAS device of claim 23, wherein
the support body further comprises a fold means separating said
first and second component halves..Iaddend..Iadd.29. The .mu.-TAS
device of claim 25, wherein the support body further comprises a
fold means separating said first and second component
halves..Iaddend..Iadd.30. The .mu.-TAS device of claim 26, wherein
said first and second component halves further comprise
micro-alignment means..Iaddend..Iadd.31. The .mu.-TAS device of
claim 27, wherein said first and second component halves further
comprise micro-alignment means..Iaddend..Iadd.32. The .mu.-TAS
device of claim 28, wherein said first and second component halves
further comprise micro-alignment means..Iaddend..Iadd.33. The
.mu.-TAS device of claim 29, wherein said first and second
component halves further comprise micro-alignment
means..Iaddend..Iadd.34. The .mu.-TAS device of claim 30, wherein
said micro-alignment means comprises a plurality of holes
laser-ablated in said component halves, wherein the holes are
arranged such that alignment of corresponding holes in said first
and second component halves enables the precise alignment of said
first and second microchannels to form said sample processing
compartment..Iaddend..Iadd.35. The .mu.-TAS device of claim 31,
wherein said micro-alignment means comprises a plurality of holes
laser-ablated in said component halves, wherein the holes are
arranged such that alignment of corresponding holes in said first
and second component halves enables the precise alignment of said
first and second microchannels to form said sample processing
compartment..Iaddend..Iadd.36. The .mu.-TAS device of claim 32,
wherein said micro-alignment means comprises a plurality of holes
laser-ablated in said component halves, wherein the holes are
arranged such that alignment of corresponding holes in said first
and second component halves enables the precise alignment of said
first and second microchannels to form said sample processing
compartment..Iaddend..Iadd.37. The .mu.-TAS device of claim 33,
wherein said micro-alignment means comprises a plurality of holes
laser-ablated in said component halves, wherein the holes are
arranged such that alignment of corresponding holes in said first
and second component halves enables the precise alignment of said
first and second microchannels to form said sample processing
compartment..Iaddend..Iadd.38. The .mu.-TAS device of claim 30,
wherein said micro-alignment means comprises corresponding
structures formed in said component halves, said structures
comprising a plurality of depressions arranged on one of said
component halves and a plurality of projections arranged on the
other of said component halves, said projections configured to mate
with said depressions such that alignment of the corresponding
structures enables the precise alignment of said first and second
microchannels to form said sample processing
compartment..Iaddend..Iadd.39. The .mu.-TAS device of claim 31,
wherein said micro-alignment means comprises corresponding
structures formed in said component halves, said structures
comprising a plurality of depressions arranged on one of said
component halves and a plurality of projections arranged on the
other of said component halves, said projections configured to mate
with said depressions such that alignment of the corresponding
structures enables the precise alignment of said first and second
microchannels to form said sample processing
compartment..Iaddend..Iadd.40. The .mu.-TAS device of claim 32,
wherein said micro-alignment means comprises corresponding
structures formed in said component halves, said structures
comprising a plurality of depressions arranged on one of said
component halves and a plurality of projections arranged on the
other of said component halves, said projections configured to mate
with said depressions such that alignment of the corresponding
structures enables the precise alignment of said first and second
microchannels to form said sample processing
compartment..Iaddend..Iadd.41. The .mu.-TAS device of claim 33,
wherein said micro-alignment means comprises corresponding
structures formed in said component halves, said structures
comprising a plurality of depressions arranged on one of said
component halves and a plurality of projections arranged on the
other of said component halves, said projections configured to mate
with said depressions such that alignment of the corresponding
structures enables the precise alignment of said first and second
microchannels to form said sample processing
compartment..Iaddend..Iadd.42. The .mu.-TAS device comprising:
(a) a substrate formed from a substrate comprised of a material
other than silicon or silicon dioxide, said substrate having a
column portion and first and second cover plate portions,
said column portion having first and second substantially planar
opposing surfaces,
said first and second cover plate portions each having at least one
substantially planar surface,
said first cover plate portion separated from said column portion
by at least one fold means such that said planar surface of said
first cover plate portion can be folded to overlie said first
planar surface of said column portion,
said second cover plate portion separated from said column portion
by at least one fold means such that said planar surface of said
second cover plate portion can be folded to overlie said second
planar surface of said column portion;
(b) a first microchannel laser-ablated in said first surface of
said column portion and a second microchannel laser-ablated in said
second surface of said column portion;
(c) a conduit means laser ablated through said column portion
communicating with a distal portion of said first microchannel and
a first portion of said second microchannel;
(d) a separation compartment formed by aligning said planar surface
of said first cover plate portion with said first surface of said
column portion by folding said first fold means, and by further
aligning said planar surface of said second cover plate portion
with said second surface of said column portion by folding said
second fold means; and
(e) a first aperture laser ablated in said first cover plate
portion allowing fluid communication with said first microchannel
and a second aperture laser ablated in said second cover plate
portion allowing fluid communication with said second
microchannel..Iaddend.
Description
TECHNICAL FIELD
The present invention relates generally to miniaturized planar
column technology for liquid phase analysis. More particularly the
invention relates to a miniaturized total analysis system
(.mu.-TAS) fabricated in novel separation support media using laser
ablation techniques. The .mu.-TAS disclosed herein finds use in the
liquid phase analysis of either small and/or macromolecular
solutes.
BACKGROUND
In sample analysis instrumentation, and especially in separation
systems such as liquid chromatography and capillary electrophoresis
systems, smaller dimensions will generally result in improved
performance characteristics and at the same time result in reduced
production and analysis costs. In this regard, miniaturized
separation systems provide more effective system design, result in
lower overhead due to decreased instrumentation sizing and
additionally enable increased speed of analysis, decreased sample
and solvent consumption and the possibility of increased detection
efficiency.
Accordingly, several approaches towards miniaturization for liquid
phase analysis have developed in the art; the conventional approach
using drawn fused-silica capillary, and an evolving approach using
silicon micromachining. What is currently thought of as
conventional in miniaturization technology is generally any step
toward reduction in size of the analysis system.
In conventional miniaturized technology the instrumentation has not
been reduced in size; rather, it is the separation compartment size
which has been significantly reduced. As an example, micro-column
liquid chromatography (.mu.LC) has been described wherein columns
with diameters of 100-200 .mu.m are employed as compared to prior
column diameters of around 4.6 mm.
Another approach towards miniaturization has been the use of
capillary electrophoresis (CE) which entails a separation technique
carried out in capillaries 25-100 .mu.m in diameter. CE has been
demonstrated to be useful as a method for the separation of small
solutes. J. Chromatogr. 218:209 (1981); Analytical Chemistry
53:1298 (1981). In contrast, polyacrylamide gel electrophoresis was
originally carried out in tubes 1 mm in diameter. Both of the above
described "conventional" miniaturization technologies (.mu.LC and
CE) represent a first significant step toward reducing the size of
the chemical portion of a liquid phase analytical system. However,
even though experimentation with such conventional miniaturized
devices has helped to verify the advantages of miniaturization in
principal, there nevertheless remain several major problems
inherent in those technologies.
For example, there remains substantial detection limitations in
conventional capillary electrophoresis technology. For example, in
CE, optical detection is generally performed on-column by a
single-pass detection technique wherein electromagnetic energy is
passed through the sample, the light beam travelling normal to the
capillary axis and crossing the capillary only a single time.
Accordingly, in conventional CE systems, the detection path length
is inherently limited by the diameter of the capillary.
Given Beer's law, which relates absorbance to the path length
through the following relationship:
where:
A=the absorbance
.epsilon.=the molar absorptivity, (1/m*cm)
b=path length (cm)
C=concentration (m/1)
it can be readily understood that the absorbance (A) of a sample in
a 25 .mu.m capillary would be a factor of 400.times. less than it
would be in a conventional 1 cm path length cell as typically used
in UV/V is spectroscopy.
In light of this significant detection limitation, there have been
a number of attempts employed in the prior art to extend detection
path lengths, and hence the sensitivity of the analysis in CE
systems. In U.S. Pat. No. 5,061,361 to Gordon, there has been
described an approach entailing micro-manipulation of the capillary
flow-cell to form a bubble at the point of detection. In U.S. Pat.
No. 5,141,548 to Chervet, the use of the Z-shaped configuration in
the capillary, with detection performed across the extended portion
of the Z has been described. Yet another approach has sought to
increase the detection path length by detecting along the major
axis of the capillary (axial-beam detection). Xi et al., Analytical
Chemistry 62:1580 (1990).
In U.S. Pat. No. 5,273,633 to Wang, a further approach to increased
detection path lengths in CE has been described where a reflecting
surface exterior of the capillary is provided, the subject system
further including an incident window and an exit window downstream
of the incident window. Under Wang, light entering the incident
window passes through a section of the capillary by multiple
internal reflections before passing through the exit window where
it is detected, the subject multiple internal reflections yielding
an effective increase in path length. While each of the
aforementioned approaches has addressed the issue of extending the
path length, each approach is limited in that it entails
engineering the capillary after-the-fact or otherwise increasing
the cost of the analysis.
A second major drawback in the current approach to miniaturization
involves the chemical activity and chemical instability of silicon
dioxide (SiO.sub.2) substrates, such as silica, quartz or glass,
which are commonly used in both CE and .mu.LC systems. More
particularly, silicon dioxide substrates are characterized as high
energy surfaces and strongly adsorb many compounds, most notably
bases. The use of silicon dioxide materials in separation systems
is further restricted due to the chemical instability of those
substrates, as the dissolution of SiO.sub.2 materials increases in
basic conditions (at pHs greater than 7.0).
To avoid the problems arising from the inherent chemical activity
of silicon dioxide materials, prior separation systems have
attempted chemical modifications to the inner silica surface of
capillary walls. In general, such post-formation modifications are
difficult as they require the provision of an interfacial layer to
bond a desired surface treatment to the capillary surface, using,
for example, silylating agents to create Si--O--Si--C bonds.
Although such modifications may decrease the irreversible
adsorption of solute molecules by the capillary surfaces, these
systems still suffer from the chemical instability of Si--O--Si
bonds at pHs above 7.0. Accordingly, chemical instability in
SiO.sub.2 materials remains a major problem.
However, despite the recognized shortcomings with the chemistry of
SiO.sub.2 substrates, those materials are still used in separation
systems due to their desirable optical properties. In this regard,
potential substitute materials which exhibit superior chemical
properties compared to silicon dioxide materials are generally
limited in that they are also highly adsorbing in the UV region,
where detection is important.
In order to avoid some of the substantial limitations present in
conventional .mu.LC and CE techniques, and in order to enable even
greater reduction in separation system sizes, there has been a
trend towards providing planarized systems having capillary
separation microstructures. In this regard, production of
miniaturized separation systems involving fabrication of
microstructures in silicon by micromachining or microlithographic
techniques has been described. See, e.g. Fan et al., Anal. Chem.
66(1):177-184 (1994); Manz et al., Adv. Chrom. 33:1-66 (1993);
Harrison et al., Sens. Actuators, B10 (2): 107-116 (1993); Manz et
al., Trends Anal. Chem. 10 (5); 144-149 (1991); and Manz et al.,
Sensors and Actuators B (Chemical) B1 (1-6): 259-255 (1990).
State-of-the-art chemical analysis systems for use in chemical
production, environmental analysis, medical diagnostics and basic
laboratory analysis must be capable of complete automation. Such a
total analysis system (TAS) (Fillipini et al (1991) J. Biotechnol.
18:153; Garn et al (1989) Biotechnol. Bioeng. 34:423; Tshulena
(1988) Phys. Ser. T23:293; Edmonds (1985) Trends Anal. Chem. 4:220;
Stinshoff et al. (1985) Anal. Chem. 57:114R; Guibault (1983) Anal.
Chem Symp. Ser. 17:637; Widmer (1983) Trends Anal. Chem. 2:8)
automatically performs functions ranging from introduction of
sample into the system, transport of the sample through the system,
sample preparation, separation, purification and detection,
including data acquisition and evaluation. Miniaturized total
analysis systems have been referred to as ".mu.-TAS."
Recently, sample preparation technologies have been successfully
reduced to miniaturized formats. Gas chromatography (Widner et al.
(1984) Int. J. Environ. Anal. Chem. 18:1), high pressure liquid
chromatography (Muller et al. (1991) J. High Resolut. Chromatogr.
14:174; Manz et al., (1990) Sensors & Actuators B1:249; Novotny
et al., eds. (1985) Microcolumn Separations: Columns,
Instrumentation and Ancillary Techniques (J. Chromatogr. Library,
Vol. 30); Kucera, ed. (1984) Micro-Column High Performance Liquid
Chromatography, Elsevier, Amsterdam; Scott, ed. (1984) Small Bore
Liquid Chromatography Columns: Their Properties and Uses, Wiley,
N.Y.; Jorgenson et al., (1983) J. Chromatogr. 255:335; Knox et al.
(1979) J. Chromatogr. 186:405; Tsuda et al. (1978) Anal. Chem.
50:632) and capillary electrophoresis (Manz et al. (1992) J.
Chromatogr. 593:253; Manz et al. Trends Anal. Chem. 10:144;
Olefirowicz et al. (1990) Anal. Chem. 62:1872; Second Int'l Symp.
High-Perf. Capillary Electrophoresis (1990) J. Chromatogr. 516;
Ghowsi et al. (1990) Anal. Chem. 62:2714) have been reduced to
miniaturized formats.
Capillary electrophoresis has been particularly amenable to
miniaturization because the separation efficiency is proportional
to the applied voltage regardless of the length of the capillary
Harrison et al. (1993) Science 261:895-897. A capillary
electrophoresis device using electroosmotic fluid pumping and laser
fluorescence detection has been prepared on a planar glass
microstructure. Effenhauser et al. (1993) Anal. Chem. 65:2637-2642;
Burggraf et al. (1994) Sensors and Actuators B20:103-110. In
contrast to silicon materials (see, Harrison et al. (1993) Sensors
and Actuators B10:107-116), polyimide has a very high breakdown
voltage, thereby allowing the use of significantly higher
voltages.
The use of micromachining techniques to fabricate separation
systems in silicon provides the practical benefit of enabling mass
production of such systems. In this regard, a number of established
techniques developed by the microelectronics industry involving
micromachining of planar materials, such as silicon, exist and
provide a useful and well accepted approach to miniaturization.
Examples of the use of such micromachining techniques to produce
miniaturized separation devices on silicon or borosilicate glass
chips can be found in U.S. Pat. No. 5,194,133 to Clark et al.; U.S.
Pat. No. 5,132,012 to Miura et al.; in U.S. Pat. No. 4,908,112 to
Pace; and in U.S. Pat. No. 4,891,120 to Sethi et al.
Micromachining silicon substrates to form miniaturized separation
systems generally involves a combination of film deposition,
photolithography, etching and bonding techniques to fabricate a
wide array of three dimensional structures. Silicon provides a
useful substrate in this regard since it exhibits high strength and
hardness characteristics and can be micromachined to provide
structures having dimensions in the order of a few micrometers.
Although silicon micromachining has been useful in the fabrication
of miniaturized systems on a single surface, there are significant
disadvantages to the use of this approach in creating the analysis
device portion of a miniaturized separation system.
Initially, silicon micromachining is not amenable to producing a
high degree of alignment between two etched or machined pieces.
This has a negative impact on the symmetry and shape of a
separation channel formed by micromachining, which in turn may
impact separation efficiency. Secondly, sealing of micromachined
silicon surfaces is generally carried out using adhesives which may
be prone to attack by separation conditions imposed by liquid phase
analyses. Furthermore, under oxidizing conditions, a silica surface
is formed on the silicon chip substrate. In this regard, silicon
micromachining is also fundamentally limited by the chemistry of
SiO.sub.2. Accordingly, there has remained a need for an improved
miniaturized total analysis system which is able to avoid the
inherent shortcomings of conventional miniaturization and silicon
micromachining techniques.
SUMMARY OF THE INVENTION
The present invention relates to a miniaturized planar column
device for use in a liquid phase analysis system. It is a primary
object of the present invention to provide a miniaturized column
device laser-ablated in a substantially planar substrate, wherein
said substrate is comprised of a material selected to avoid the
inherent chemical activity and pH instability encountered with
silicon and prior silicon dioxide-based device substrates.
The present invention is also related to the provision of detection
means engineered into a miniaturized planar column device whereby
enhanced on-column analysis or detection of components in a liquid
sample is enabled. It is further contemplated to provide a column
device for liquid phase analysis having detection means designed
into the device in significantly compact form as compared to
conventional technology. In one particular aspect of the present
invention, it is contemplated to provide optical detection means
ablated in a miniaturized planar column device and having a
substantially enhanced detection path length.
It is a further related object of the present invention to provide
a device featuring improved means for liquid handling, including
sample injection, and to provide a miniaturized column device with
means to interface with a variety of external liquid reservoirs.
Specifically contemplated herein is a system design which allows a
variety of injection methods to be readily adapted to the planar
structure, such as pressure injection, hydrodynamic injection or
electrokinetic injection.
It is yet a further related object of the present invention to
provide a miniaturized total chemical analysis system (.mu.-TAS)
fully contained on a single, planar surface. In this regard, a
miniaturized system according to the present invention is capable
of performing complex sample handling, separation, and detection
methods with reduced technician manipulation or interaction.
Accordingly, the subject invention finds potential application in
monitoring and/or analysis of components in industrial chemical,
biological, biochemical and medical processes and the like.
A particular advantage of the present invention is the use of
processes other than silicon micromachining techniques or etching
techniques to create miniaturized columns in a wide variety of
polymeric and ceramic substrates having desirable attributes for an
analysis portion of a separation system. More specifically, it is
contemplated herein to provide a miniaturized planar column device
by ablating component microstructures in a substrate using laser
radiation. In one preferred embodiment, a miniaturized column
device is formed by providing two substantially planar halves
having microstructures laser-ablated thereon, which, when the two
halves are folded upon each other, define a sample processing
compartment featuring enhanced symmetry and axial alignment.
Use of laser ablation techniques to form miniaturized devices
according to the present invention affords several advantages over
prior etching and micromachining techniques used to form systems in
silicon or silicon dioxide materials. Initially, the capability of
applying rigid computerized control over laser ablation processes
allows microstructure formation to be executed with great
precision, thereby enabling a heightened degree of alignment in
structures formed by component parts. The laser ablation process
also avoids problems encountered with microlithographic isotropic
etching techniques which may undercut masking during etching,
giving rise to asymmetrical structures having curved side walls and
flat bottoms.
Laser ablation further enables the creation of microstructures with
greatly reduced component size. In this regard, microstructures
formed according to the invention are capable of having aspect
ratios several orders of magnitude higher than possible using prior
etching techniques, thereby providing enhanced sample processing
capabilities in such devices. The use of laser-ablation processes
to form microstructures in substrates such as polymers increases
ease of fabrication and lowers per-unit manufacturing costs in the
subject devices as compared to prior approaches such as
micromachining devices in silicon. In this regard, devices formed
according to the invention in low-cost polymer substrates have the
added feature of being capable of use as substantially disposable
miniaturized column units.
In another aspect of the instant invention, laser-ablation in
planar substrates allows for the formation of microstructures of
almost any geometry or shape. This feature not only enables the
formation of complex device configurations, but further allows for
integration of sample preparation, sample injection, post-column
reaction and detection means in a miniaturized total analysis
system of greatly reduced overall dimensions.
The compactness of the analysis portion in a device produced under
to the present invention, in conjunction with the feature that
integral functions such as injection, sample handling and detection
may be specifically engineered into the subject device to provide a
.mu.-TAS device, further allows for integrated design of system
hardware to achieve a greatly reduced system footprint.
By the present invention, inherent weaknesses existing in prior
approaches to liquid phase separation device miniaturization, and
problems in using silicon micromachining techniques to form
miniaturized column devices have been addressed. Accordingly, the
present invention discloses a miniaturized total analysis system
capable of performing a variety of liquid phase analyses on a wide
array of liquid samples.
BRIEF DESCRIPTION OF THE FIGURES
FIG. 1 is an exploded view of a miniaturized column device
constructed in accordance with the present invention.
FIG. 2 is a plan view of the interior surface of the miniaturized
column device of FIG. 1.
FIG. 3 is a plan view of the exterior surface of the device of FIG.
1.
FIG. 4 is a cross-sectional side view of the miniaturized column
device of FIG. 1, taken along lines IV--IV and showing formation of
a sample processing compartment according to the invention.
FIG. 5 is an exploded view of a preferred embodiment of the present
invention including optical detection means.
FIG. 6 is a cross-sectional axial view of the intersection of the
sample processing compartment and the optical detection means in
the miniaturized column device of FIG. 5.
FIG. 7A is an exploded view of a first side of a miniaturized
column device having microchannels formed on two opposing planar
surfaces of a support substrate.
FIG. 7B is an exploded view of a second side of the column device
of FIG. 7A.
FIG. 8A is a pictorial representation of a first side of a
preferred embodiment of the miniaturized column device of FIG. 7A
which is constructed from a single flexible substrate.
FIG. 8B is a pictorial representation of a second side of the
column device of FIG. 8A.
FIG. 9 is a cross-sectional trans-axial view of the extended
optical detection path length in the miniaturized column of FIG. 8
taken along lines IX--IX.
FIG. 10 is plan view of a miniaturized column device constructed
according to the invention having first and second component
halves.
FIG. 11 is a pictorial representation of the column device of FIG.
10 showing the folding alignment of the component halves to form a
single device.
FIG. 12 is a cross-sectional axial view of the sample processing
compartment formed by the alignment of the component halves in the
device of FIG. 10.
FIG. 13 is a plan view of a further preferred embodiment of the
present invention having optional micro-alignment means on first
and second component halves.
FIG. 14 is a pictorial representation of the column device of FIG.
13 showing the micro-alignment of the component halves.
FIG. 15 is a diagram of an exemplary .mu.-TAS.
FIGS. 16A, 16B, and 16C are illustrations of a .mu.-TAS having a
laser-ablated reservoir compartment as an integral microstructure
on the substrate.
FIG. 17A is a cross-section of the .mu.-TAS of FIG. 15 showing
laser-ablated microstructures for communicating a sample droplet
formed by a pressure pulse to a post-column sample collection
device having a laser-ablated sample droplet receiving microwells.
FIG. 17B is a cross-section of the .mu.-TAS of FIG. 15 showing
laser-ablated microstructures for communicating a sample droplet
formed by a generating steam bubbles to a post-column sample
collection device having laser-ablated sample droplet receiving
microwells and a cover plate. FIG. 17C is a cross-section of the
.mu.-TAS of FIG. 15 showing laser-ablated microstructures for
communicating a sample droplet formed by a generating steam bubbles
in a makeup fluid stream to a post-column sample collection device
having a sample droplet receiving bibulous sheet means.
FIG. 18A is a pictorial representation of the .mu.-TAS of FIG. 15
interfaced with a post-column collection device having sample
droplet receiving wells. FIG. 18B is a pictorial representation of
the .mu.-TAS of FIG. 15 interfaced with a post-column collection
device having sample droplet receiving wells and a cover plate.
DETAILED DESCRIPTION OF THE INVENTION
Before the invention is described in detail, it is to be understood
that this invention is not limited to the particular component
parts of the devices described or process steps of the methods
described as such devices and methods may vary. It is also to be
understood that the terminology used herein is for purposes of
describing particular embodiments only, and is not intended to be
limiting. It must be noted that, as used in the specification and
the appended claims, the singular forms "a," "an" and "the" include
plural referents unless the context clearly dictates otherwise.
Thus, for example, reference to "an analyte" includes mixtures of
analytes, reference to "a detection means" includes two or more
such detection means, reference to "a sample flow component"
includes more than one such component, reference to "an on-device
fluid reservoir compartment" includes two or more such
compartments, and the like.
In this specification and in the claims which follow, reference
will be made to a number of terms which shall be defined to have
the following meanings:
The term "substrate" is used herein to refer to any material which
is UV-adsorbing, capable of being laser-ablated and which is not
silicon or a silicon dioxide material such as quartz, fused silica
or glass (borosilicates). Accordingly, miniaturized column devices
are formed herein using suitable substrates, such as laser
ablatable polymers (including polyimides and the like) and ceramics
(including aluminum oxides and the like). Further, miniaturized
column devices are formed herein using composite substrates such as
laminates. A "laminate" refers to a composite material formed from
several different bonded layers of same or different materials. One
particularly preferred composite substrate comprises a polyimide
laminate formed from a first layer of polyimide, such as
Kapton.RTM. (DuPont; Wilmington, Del.), that has been co-extruded
with a second, thin layer of a thermal adhesive form of polyimide
known as KJ.RTM. (DuPont). This thermoplastic adhesive can be
applied to one or both sides of the first polyimide layer, thereby
providing a means for producing a laminate of desired
thickness.
The term "sample handling region" refers to a portion of a
microchannel, or to a portion of a "sample processing compartment"
that is formed upon enclosure of the microchannel by a cover plate
or substrate in which a mirror image of the microchannel has been
laser ablated as described in detail below, that includes a "sample
flow component" or a "sample treatment component." By the term
"sample flow component" is intended a portion of the sample
processing compartment that interconnects sample treatment
components.
A "sample treatment component" is a portion of the sample
processing compartment in which particular sample preparation
chemistries are done. In particular, an analyte of interest is
generally obtained in a matrix containing other species which may
potentially interfere with the detection and analysis of the
analyte. Accordingly, a sample treatment component is a portion of
the sample processing compartment in which analyte separation from
the matrix is effected. Examples of functions which may be served
by the sample treatment component include chromatographic
separations, electrophoretic separations, electrochromatographic
separations, and the like.
As used herein, the term "detection means" refers to any means,
structure or configuration which allows one to interrogate a sample
within the sample processing compartment using analytical detection
techniques well known in the art. Thus, a detection means includes
one or more apertures, elongated apertures or grooves which
communicate with the sample processing compartment and allow an
external detection apparatus or device to be interfaced with the
sample processing compartment to detect an analyte passing through
the compartment.
Changes in the electrochemical properties of a liquid sample
passing through the sample processing compartment can be detected
using detection means which physically contact the sample passing
through the sample processing compartment. In one embodiment, an
electrode may be placed within, or butt-coupled to a detection
means such as an aperture or a groove, thereby enabling the
electrode to directly contact the sample stream. By arranging two
dissimilar electrodes (which are connected through an external
conducting circuit) opposite each other relative to the sample
processing compartment, an electric field can be generated in the
sample processing compartment--transverse to the direction of
sample flow--thereby providing a ready means of electrochemical
detection of analytes passing through the compartment.
Changes in the electrical properties of a liquid sample passing
through the sample processing compartment can be detected using
detection means which do not physically contact the sample passing
through the sample processing compartment. Thus, "changes in the
electrical properties" of a sample passing through the sample
processing compartment refers to detectable changes in the
conductivity, permittivity, or both of a particular sample due to
the presence of an analyte in the sample. The "conductivity" of a
sample refers to the ratio of the electric current density to the
electric field in that sample. The "permittivity" of a sample
refers to the dielectric constant of a sample multiplied by the
permittivity of empty space, where the permittivity of empty space
(.epsilon..sub.0) is a constant appearing in Coulomn's law having
the value of 1 in centimeter-gram-second electrostatic units.
Changes in the electrical properties of a sample passing through a
sample processing compartment are measured herein by detection of
the impedance of the liquid sample. The "impedance" or "electrical
impedance" of a circuit refers to the total opposition that the
circuit presents to an alternating current ("AC"), equal to the
complex ratio of the voltage to the current in complex notation.
Thus, the magnitude of the total opposition that a circuit presents
to an alternating current is equal to the ratio of the maximum
voltage in an AC circuit to the maximum current. An "electrical
impedance meter" refers to an instrument which measures the complex
ratio of voltage to current in a given circuit at a given
frequency.
A plurality of electrical "communication paths" capable of carrying
and/or transmitting electric current can be arranged adjacent to
the sample processing compartment such that the communication
paths, in combination, form a circuit. As used herein, a
communication path includes any conductive material which is
capable of transmitting or receiving an AC signal. A particularly
preferred conductive material is copper. Thus, in one embodiment, a
plurality of communication paths forming an antenna circuit (e.g.,
a pair of copper antennae) are arranged adjacent to the sample
processing compartment whereby a circuit is formed capable of
passing an oscillating voltage through the sample processing
compartment which is sensitive to changes in the impedance of a
liquid sample flowing therethrough. An "antenna" refers to a device
capable of radiating and/or receiving radio waves such as
alternating current (AC) signal. An "antenna circuit" intends a
complete electrical circuit which includes an antenna. An "antenna
coil" refers to a coil through which antenna current (e.g., an AC
signal) flows.
Further, by the arrangement of two detection means opposite each
other relative to the sample processing compartment, a "detection
path" is conveniently formed, thereby allowing detection of
analytes passing through the sample processing compartment using
detection techniques well known in the art.
An "optical detection path" refers to a configuration or
arrangement of detection means to form a path whereby radiation,
such as a ray of light, is able to travel from an external source
to a means for receiving radiation--wherein the radiation traverses
the sample processing compartment and can be influenced by the
sample or separated analytes in the sample flowing through the
sample processing compartment. An optical detection path is
generally formed according to the invention by positioning a pair
of detection means directly opposite each other relative to the
sample processing compartment. In this configuration, analytes
passing through the sample processing compartment can be detected
via transmission of radiation orthogonal to the major axis of the
sample processing compartment (and, accordingly, orthogonal to the
direction of electroosmotic flow in an electrophoretic separation).
A variety of external optical detection techniques can be readily
interfaced with the sample processing compartment using an optical
detection path including, but not limited to, UV/Vis, Near IR,
fluorescence, refractive index (RI) and Raman techniques.
As used herein, the term "transparent" refers to the ability of a
substrate to transmit light of different wavelengths, which ability
may be measured in a particular substance as the percent of
radiation which penetrates a distance of 1 meter. Thus, according
to the invention, a "transparent sheet" is defined as a sheet of a
substance which is transmissive to specific types of radiation or
particles of interest. Transparent sheets which are particularly
employed in the invention in the context of optical detection
configurations are formed from materials such as, but not limited
to, quartz, sapphire, diamond and fused silica.
In the context of UV-visible absorption detection of sample
analytes herein, the terms "path length," or "optical path length"
refer to an optical path length "b" derived from Beer's law, which
states that A=log(I.sub.i /I.sub.f)=.epsilon.*b*C, wherein A is the
absorbance, I.sub.i is the light intensity measured in the absence
of the analyte, I.sub.f is the light intensity transmitted through
the analyte, .epsilon. is the molar extinction coefficient of the
sample (1/m*cm), C is the analyte concentration (m/1), and b is the
optical path length (cm). Thus, in a detection configuration
wherein UV-Vis absorption of a sample analyte is measured via an
optical detection path by passing light through the sample
processing compartment along a path perpendicular to the sample
processing compartment major axis, the path length (b) of the
measurement is substantially defined by the dimensions of the
sample processing compartment.
A "detection intersection" refers to a configuration wherein a
plurality of detection means that communicate with the sample
processing compartment converge at a particular location in the
sample processing compartment. In this manner, a number of
detection techniques can be simultaneously performed on a sample or
separated analyte at the detection intersection. According to the
invention, a detection intersection is formed when a plurality of
detection paths cross, or when a detection means such as an
aperture communicates with the sample processing compartment at
substantially the same point as a detection path. The sample, or a
separated analyte, can thus be interrogated using a combination of
UV/Vis and fluorescence techniques, optical and electrochemical
techniques, optical and electrical techniques, or like combinations
to provide highly sensitive detection information. See, e.g.,
Beckers et al. (1988) J. Chromatogr. 452:591-600; and U.S. Pat. No.
4,927,265, to Brownlee.
As used herein, a "lightguide means" refers to a substantially
long, thin thread of a transparent substance which can be used to
transmit light. Lightguide means useful in the practice of the
invention include optical fibers, integrated lens configurations
and the like. In particularly preferred embodiments, optical fibers
are interfaced with detection means to enable optical detection
techniques known in the art. The terms "optical fiber," "fiber
optic waveguide" or "optical fiber means" are used herein to refer
to a single optical fiber or a bundle optical fibers, optionally
encased in a protective cladding material. Examples of suitable
optical fiber substrate materials include glass, plastic,
glass/glass composite and glass/plastic composite fibers. A
critical characteristic of optical fibers is attenuation of an
optical signal. Further, a chemical sensor can be incorporated into
a fiber optic waveguide in a manner such that the chemical sensor
will interact with the liquid sample analyte. Structures,
properties, functions and operational details of such fiber optic
chemical sensors can be found in U.S. Pat. No. 4,577,109 to
Hirschfeld, U.S. Pat. No. 4,785,814 to Kane, and U.S. Pat. No.
4,842,783 to Blaylock.
The use of laser ablation techniques in the practice of the
invention allows for a high degree of precision in the alignment of
micro-scale components and structures, which alignment has either
been difficult or not possible in prior silicon or glass
substrate-based devices. Thus, the term "microalignment" as used
herein refers to the precise and accurate alignment of
laser-ablated features, including the enhanced alignment of
complementary microchannels or microcompartments with each other,
inlet and/or outlet ports with microchannels or separation
compartments, detection means with microchannels or separation
compartments, detection means with other detection means, and the
like.
The term "microalignment means" is defined herein to refer to any
means for ensuring the precise microalignment of laser-ablated
features in a miniaturized column device. Microalignment means can
be formed in the column devices either by laser ablation or by
other methods of fabricating shaped pieces well known in the art.
Representative microalignment means that can be employed herein
include a plurality of co-axially arranged apertures laser-ablated
in component parts and/or a plurality of corresponding features in
column device substrates, e.g., projections and mating depressions,
grooves and mating ridges or the like. Further, the accurate
microalignment of component parts can be effected by forming the
miniaturized columns in flexible substrates having at least one
fold means laser-ablated therein, such that sections of the
substrate can be folded to overlie other sections thereby forming
composite micro-scale compartments, aligning features such as
apertures or detection means with separation compartments, or
forming micro-scale separation compartments from microchannels.
Such fold means can be embodied by a row of spaced-apart
perforations ablated in a particular substrate, spaced-apart
slot-like depressions or apertures ablated so as to extend only
part way through the substrate, or the like. The perforations or
depressions can have circular, diamond, hexagonal or other shapes
that promote hinge formation along a predetermined straight
line.
The term "liquid phase analysis" is used to refer to any analysis
which is done on either small and/or macromolecular solutes in the
liquid phase. Accordingly, "liquid phase analysis" as used herein
includes chromatographic separations, electrophoretic separations,
and electrochromatographic separations.
In this regard, "chromatographic" processes generally comprise
preferential separations of components, and include reverse-phase,
hydrophobic interaction, ion exchange, molecular sieve
chromatography and like methods.
"Electrophoretic" separations refers to the migration of particles
or macromolecules having a net electric charge where said migration
is influenced by an electric field. Accordingly electrophoretic
separations contemplated for use in the invention include
separations performed in columns packed with gels (such as
polyacrylamide, agarose and combinations thereof) as well as
separations performed in solution.
"Electrochromatographic" separation refers to combinations of
electrophoretic and chromatographic techniques. Exemplary
electrochromatographic separations include packed column
separations using electromotive force (Knox et al. (1987)
Chromatographia 24:135; Knox et al. (1989) J. Liq. Chromatogr
12:2435; Knox et al. (1991) Chromatographia 32:317), and micellar
electrophoretic separations (Terabe et al. (1985) Anal. Chem.
57:834-841).
The term "motive force" is used to refer to any means for inducing
movement of a sample along a column in a liquid phase analysis, and
includes application of an electric potential across any portion of
the column, application of a pressure differential across any
portion of the column or any combination thereof.
The term "surface treatment" is used to refer to preparation or
modification of the surface of a microchannel which will be in
contact with a sample during separation, whereby the separation
characteristics of the device are altered or otherwise enhanced.
Accordingly, "surface treatment" as used herein includes: physical
surface adsorptions; covalent bonding of selected moieties to
functional groups on the surface of microchannel substrates (such
as to amine, hydroxyl or carboxylic acid groups on condensation
polymers); methods of coating surfaces, including dynamic
deactivation of channel surfaces (such as by adding surfactants to
media), polymer grafting to the surface of channel substrates (such
as polystyrene or divinyl-benzene) and thin-film deposition of
materials such as diamond or sapphire to microchannel
substrates.
The term "laser ablation" is used to refer to a machining process
using a high-energy photon laser such as an excimer laser to ablate
features in a suitable substrate. The excimer laser can be, for
example, of the F.sub.2, ArF, KrCl, KrF, or XeCl type.
In general, any substrate which is UV absorbing provides a suitable
substrate in which one may laser ablate features. Accordingly,
under the present invention, microstructures of selected
configurations can be formed by imaging a lithographic mask onto a
suitable substrate, such as a polymer or ceramic material, and then
laser ablating the substrate with laser light in areas that are
unprotected by the lithographic mask.
In laser ablation, short pulses of intense ultraviolet light are
absorbed in a thin surface layer of material within about 1 .mu.m
or less of the surface. Preferred pulse energies are greater than
about 100 millijoules per square centimeter and pulse durations are
shorter than about 1 microsecond. Under these conditions, the
intense ultraviolet light photo-dissociates the chemical bonds in
the material. Furthermore, the absorbed ultraviolet energy is
concentrated in such a small volume of material that it rapidly
heats the dissociated fragments and ejects them away from the
surface of the material. Because these processes occur so quickly,
there is no time for heat to propagate to the surrounding material.
As a result, the surrounding region is not melted or otherwise
damaged, and the perimeter of ablated features can replicate the
shape of the incident optical beam with precision on the scale of
about one micrometer.
Although laser ablation has been described herein using an excimer
laser, it is to be understood that other ultraviolet light sources
with substantially the same optical wavelength and energy density
may be used to accomplish the ablation process. Preferably, the
wavelength of such an ultraviolet light source will lie in the 150
nm to 400 nm range to allow high absorption in the substrate to be
ablated. Furthermore, the energy density should be greater than
about 100 millijoules per square centimeter with a pulse length
shorter than about 1 microsecond to achieve rapid ejection of
ablated material with essentially no heating of the surrounding
remaining material. Laser ablation techniques, such as those
described above, have been described in the art. Znotins, T. A., et
al., Laser Focus Electro Optics, (1987) pp. 54-70; U.S. Pat. Nos.
5,291,226 and 5,305,015 to Schantz et al.
The term "injection molding" is used to refer to a process for
molding plastic or nonplastic ceramic shapes by injecting a
measured quantity of a molten plastic or ceramic substrate into
dies (or molds). In one embodiment of the present invention,
miniaturized column devices may be produced using injection
molding.
More particularly, it is contemplated to form a mold or die of a
miniaturized column device wherein excimer laser-ablation is used
to define an original microstructure pattern in a suitable polymer
substrate. The microstructure thus formed may then be coated by a
very thin metal layer and electroplated (such as by galvano
forming) with a metal such as nickel to provide a carrier. When the
metal carrier is separated from the original polymer, an mold
insert (or tooling) is provided having the negative structure of
the polymer. Accordingly, multiple replicas of the ablated
microstructure pattern may be made in suitable polymer or ceramic
substrates using injection molding techniques well known in the
art.
The term "LIGA process" is used to refer to a process for
fabricating microstructures having high aspect ratios and increased
structural precision using synchrotron radiation lithography,
galvanoforming, and plastic molding. In a LIGA process, radiation
sensitive plastics are lithographically irradiated at high energy
radiation using a synchrotron source to create desired
microstructures (such as channels, ports, apertures and
micro-alignment means), thereby forming a primary template.
The primary template is then filled with a metal by
electrodeposition techniques. The metal structure thus formed
comprises a mold insert for the fabrication of secondary plastic
templates which take the place of the primary template. In this
manner highly accurate replicas of the original microstructures may
be formed in a variety of substrates using injection or reactive
injection molding techniques. The LIGA process has been described
by Becker, E. W., et al., Microelectric Engineering (1986) 4:35-56.
Descriptions of numerous polymer substrates which may be injection
molded using LIGA templates, and which are suitable substrates in
the practice of the subject invention, may be found in
"Contemporary Polymer Chemistry", Allcock. H. R. and Lampe, F. W.
(Prentice-Hall, Inc.) New Jersey (1981).
"Optional" or "optionally" means that the subsequently described
feature or structure may or may not be present in the .mu.-TAS or
that the subsequently described event or circumstance may or may
not occur, and that the description includes instances where said
feature or structure is present and instances where the feature or
structure is absent, or instances where the event or circumstance
occurs and instances where it does not. For example, the phrase "a
.mu.-TAS optionally having detection means" intends that access
ports may or may not be present on the device and that the
description includes both circumstances where access ports are
present and absent.
Accordingly, the invention concerns formation of miniaturized
column devices including .mu.-TAS, using laser ablation in a
suitable substrate. It is also contemplated to form column devices
and .mu.-TASs according to the invention using injection molding
techniques wherein the original microstructure has been formed by
an excimer laser ablation process, or where the original
microstructure has been formed using a LIGA process.
More particularly, microstructures such as sample processing
compartments, injection means, detection means and micro-alignment
means may be formed in a planar substrate by excimer laser
ablation. A frequency multiplied YAG laser may also be used in
place of the excimer laser. In such a case, a complex
microstructure pattern useful for practicing the invention may be
formed on a suitable polymeric or ceramic substrate by combining a
masking process with a laser ablation means, such as in a
step-and-repeat process, where such processes would be readily
understood by one of ordinary skill in the art.
In the practice of the invention, a preferred substrate comprises a
polyimide material such as those available under the trademarks
Kapton.RTM. or Upilex.RTM. from DuPont (Wilmington, Del.), although
the particular substrate selected may comprise any other suitable
polymer or ceramic substrate. Polymer materials particularly
contemplated herein include materials selected from the following
classes: polyimide, polycarbonate, polyester, polyamide, polyether,
polyolefin, or mixtures thereof. Further, the polymer material
selected may be produced in long strips on a reel, and, optional
sprocket holes along the sides of the material may be provided to
accurately and securely transport the substrate through a
step-and-repeat process.
According to the invention, the selected polymer material is
transported to a laser processing chamber and laser-ablated in a
pattern defined by one or more masks using laser radiation. In a
preferred embodiment, such masks define all of the ablated features
for an extended area of the material, for example encompassing
multiple apertures (including inlet and outlet ports),
micro-alignment means and sample processing chambers.
Alternatively, patterns such as the aperture pattern, the sample
processing channel pattern, etc., may be placed side by side on a
common mask substrate which is substantially larger than the laser
beam. Such patterns may then be moved sequentially into the beam.
In other contemplated production methods, one or more masks may be
used to form apertures through the substrate, and another mask and
laser energy level (and/or number of laser shots) may be used to
define sample processing channels which are only formed through a
portion of the thickness of the substrate. The masking material
used in such masks will preferably be highly reflecting at the
laser wavelength, consisting of, for example, a multilayer
dielectric material or a metal such as aluminum.
The laser ablation system employed in the invention generally
includes beam delivery optics, alignment optics, a high precision
and high speed mask shuttle system, and a processing chamber
including mechanism for handling and positioning the material. In a
preferred embodiment, the laser system uses a projection mask
configuration wherein a precision lens interposed between the mask
and the substrate projects the excimer laser light onto the
substrate in the image of the pattern defined on the mask.
It will be readily apparent to one of ordinary skill in the art
that laser ablation may be used to form miniaturized sample
processing channels and apertures in a wide variety of geometries.
Any geometry which does not include undercutting may be provided
using ablation techniques, such as modulation of laser light
intensity across the substrate, stepping the beam across the
surface or stepping the fluence and number of pulses applied to
each location to control corresponding depth. Further,
laser-ablated channels or chambers produced according to the
invention are easily fabricated having ratios of channel depth to
channel width which are much greater than previously possible using
etching techniques such as silicon micromachining. Such aspect
ratios can easily exceed unity, and may even reach to 10.
Furthermore, the aspect ratio of laser-ablated channels and
chambers can be less than one, i.e., the width of the channel or
chamber can be greater than the depth.
In a preferred embodiment of the invention, channels of a
semi-circular cross section are laser ablated by controlling
exposure intensity or by making multiple exposures with the beam
being reoriented between each exposure. Accordingly, when a
corresponding semi-circular channel is aligned with a channel thus
formed, a sample processing chamber of highly symmetrical circular
cross-section is defined which may be desirable for enhanced fluid
flow through the sample processing device.
As a final step in laser ablation processes contemplated by the
invention, a cleaning step is performed wherein the laser-ablated
portion of the substrate is positioned under a cleaning station. At
the cleaning station, debris from the laser ablation are removed
according to standard industry practice.
As will be appreciated by those working in the field of liquid
phase analysis devices, the above-described method may be used to
produce a wide variety of miniaturized devices. One such device is
represented in FIG. 1 where a particular embodiment of a
miniaturized column device is generally indicated at 2. Generally,
miniaturized column 2 is formed in a selected substrate 4 using
laser ablation techniques. The substrate 4 generally comprises
first and second substantially planar opposing surfaces indicated
at 6 and 8 respectively, and is selected from a material other than
silicon which is UV absorbing and, accordingly,
laser-ablatable.
In a particular embodiment of the invention, the miniaturized
column device 2 comprises a column structure ablated on a chip,
which, in the practice of the invention may be a machinable form of
the plastic polyimide such as Vespel.RTM.. It is particularly
contemplated in the invention to use such a polyimide substrate as,
based on considerable experience with the shortcomings of fused
silica and research into alternatives thereof, polyimides have
proved to be a highly desirable substrate material for the analysis
portion of a liquid phase sample processing system.
In this regard, it has been demonstrated that polyimides exhibit
low sorptive properties towards proteins, which are known to be
particularly difficult to analyze in prior silicon dioxide-based
separation systems. Successful demonstrations of separations with
this difficult class of solutes typically ensures that separation
of other classes of solutes will be not be problematic. Further,
since polyimide is a condensation polymer, it is possible to
chemically bond groups to the surface which may provide a variety
of desirable surface properties, depending on the target analysis.
Unlike prior silicon dioxide based systems, these bonds to the
polymeric substrate demonstrate pH stability in the basic region
(pH 9-10).
Referring now to FIGS. 1-3, the substrate 4 has a microchannel 10
laser-ablated in a first planar surface 6. It will be readily
appreciated that, although the microchannel 10 has been represented
in a generally extended form, microchannels formed according to the
invention may be ablated in a large variety of configurations, such
as in a straight, serpentine, spiral, or any tortuous path desired.
Further, as described in greater detail above, the microchannel 10
may be formed in a wide variety of channel geometries including
semi-circular, rectangular, rhomboid, and the like, and the
channels may be formed in a wide range of aspect ratios. It is also
noted that a device having a plurality of microchannels
laser-ablated thereon falls within the spirit of the present
invention.
Referring particularly to FIGS. 1 and 4, a cover plate 12 is
arranged over said first planar surface 6 and, in combination with
the laser-ablated microchannel 10, forms an elongate sample
processing compartment 14. Cover plate 12 may be formed from any
suitable substrate such as polyimide, the selection of the
substrate only being limited by avoidance of undesirable separation
surfaces such as silicon or silicon dioxide materials.
According to the invention, cover plate 12 may be fixably aligned
over the first planar surface 6 to form a liquid-tight sample
processing compartment by using pressure sealing techniques, by
using external means to urge the pieces together (such as clips,
tension springs or associated clamping apparatus) or by using
adhesives well known in the art of bonding polymers, ceramics and
the like.
Referring to FIGS. 1-4, a particular embodiment of the invention is
shown wherein cover plate 12 further comprises apertures ablated
therein. In this regard, a first aperture communicates with the
sample processing compartment 14 at a first end 16 thereof to form
an inlet port 18 enabling the passage of fluid from an external
source into said sample processing compartment. A second aperture
communicates with the sample processing compartment 14 at a second
end 20 thereof to form an outlet port 22 enabling passage of fluid
from the sample processing compartment to an external receptacle.
Accordingly, a miniaturized column device is formed having a flow
path extending from the first end 16 of the sample processing
compartment and passing to the second end 20 thereof, whereby
liquid phase analysis of samples may be carried out using
techniques well known in the art.
Referring still to FIGS. 1-4, a particular embodiment of the
invention is shown comprising sample introduction means
laser-ablated into both the substrate 4 and cover plate 12. An
internally ablated by-pass channel 24 is formed in substrate 4,
said channel 24 being disposed near the first end 16 of the sample
processing compartment. Two additional apertures 26 and 28 are
formed in cover plate 12 and are arranged to cooperate with first
and second ends (indicated at 30 and 32 respectively) of the
by-pass channel 24. In this manner, a sample being held in an
external reservoir may be introduced into by-pass channel 24 to
form a sample plug of a known volume (defined by the dimensions of
the channel 24). The sample plug thus formed may then be introduced
into the first end 16 of the sample processing compartment 14 via
inlet port 18 by communicating external mechanical valving with
said inlet port and laser-ablated apertures 26 and 28 and flushing
solution through the by-pass channel 24 into the sample processing
compartment.
It is noted that the ablated by-pass channel 24 and apertures 26
and 28 further enable a wide variety of sample introduction
techniques to be practiced according to the invention.
Particularly, having a by-pass channel which is not connected to
the sample processing compartment allows a user to flush a sample
through the by-pass channel without experiencing sample carry-over
or column contamination. As will be appreciated by one of ordinary
skill in the art after reading this specification, one such sample
introduction technique may be effected by butt-coupling an
associated rotor to a stator (not shown) on the external surface of
a miniaturized column where the rotor selectively interfaces
external tubing and fluid sources with inlet port 18 and apertures
26 and 28, allowing a sample to be flushed from the by-pass channel
24 into external tubing from which the sample may then be
introduced into the column via inlet port 18 for liquid phase
analysis thereof. In this regard, a miniaturized column device
formed in a polyimide substrate enables a ceramic rotor, pressed to
the devices using tensioned force (to form a liquid-tight seal), to
still rotate between selected aperture positions on the device due
to the friction characteristics of the two materials. Other
suitable rotors can be formed in rigid materials such as, but not
limited to, glass and non-conductive substrates.
Accordingly, in the practice of the invention, external hardware
provides the mechanical valving necessary for communication of a
miniaturized column device to different external liquid reservoirs,
such as an electrolyte solution, flush solution or the sample via
laser-ablated holes designed into the cover plate 12. This feature
allows a variety of injection methods to be adapted to a
miniaturized planar column device constructed according to the
invention, including pressure injection, hydrodynamic injection or
electrokinetic injection. In the particular embodiment of FIGS.
1-3, it is contemplated that external valving and injection means
communicate with the sample processing device by butt-coupling to
the laser-ablated apertures, however, any other suitable methods of
connection known in the art may easily be adapted to the invention.
Further, it is noted that numerous other sample introduction and
fluid interfacing designs may be practiced and still fall within
the spirit of the subject invention.
Also according to the invention, a wide variety of means for
applying a motive force along the length of the sample processing
compartment 14 may be associated with the subject device. In this
regard, a pressure differential or electric potential may be
applied along the entire length of the sample processing
compartment by interfacing motive means with inlet port 18 and
outlet port 22.
The use of substrates such as polyimides in the construction of
miniaturized columns according to the invention allows the
possibility of using refractive-index (RI) detection to detect
separated analytes of interest passing through the subject columns.
In this regard, the provision of an associated laser diode which
emits radiation at a wavelength where polyimide is "transparent"
(such as at >500 nm) allows for a detection setup where no
additional features need to be ablated in the column devices.
Referring now to FIGS. 2-4, in a preferred embodiment of the
invention, detection means may be ablated into the substrate 4 and
cover plate 12, where said detection means is disposed
substantially downstream of the first end 16 of the sample
processing compartment 14. More particularly, an aperture 34 may be
ablated through substrate 4 to communicate with the sample
processing compartment 14. A corresponding aperture 36 may be
likewise formed in cover plate 12, and arranged so that it will be
in co-axial alignment with aperture 34 when the cover plate is
affixed to the substrate to form the sample processing compartment
14. In this manner, electrodes (not shown) may be connected to the
miniaturized column device via the apertures 34 and 36 to detect
separated analytes of interest passing through the sample
processing compartment by electrochemical detection techniques.
Referring to FIG. 5, a further embodiment of the invention,
indicated at 2' is shown comprising a preferred detection means
indicated generally at 42. More particularly, a first transparent
sheet 38 is provided wherein the cover plate 12 is interposed
between said first transparent sheet and substrate 4. A second
transparent sheet 40 is also provided wherein the second sheet is
disposed over the second planar surface 8 of the substrate 4. In
this manner, detection means 42 allows optical detection of
separated analytes passing through sample processing compartment,
formed by the combination of microchannel 10 and cover plate 12,
via transmission of radiation orthogonal to the major axis of the
sample processing compartment (and, accordingly, orthogonal to the
direction of electro-osmotic flow in an electrophoretic
separation). Further, in the practice of the invention, the
transparent sheets may comprise materials such as quartz, diamond,
sapphire, fused silica or any other suitable substrate which
enables light transmission therethrough.
The subject transparent sheets may be formed with just enough
surface area to cover and seal the detection apertures 34 and 36,
or said sheets may be sized to cover up to the entire surface area
of the column device. In this regard, additional structural
rigidity may be provided to a column device formed in a
particularly thin substrate film, such as a thin-film polyimide
substrate, by employing a substantially co-planar sheet of, for
example, fused silica.
Accordingly, the above described optical detection means 42 enables
adaptation of a variety of external optical detection means to
miniaturized columns constructed according to the invention.
Further, sealing of the transparent sheets 38 and 40 to the
miniaturized column device 2' is readily enabled, for example, when
substrate 4 and cover plate 12 are formed in polyimide materials
which include a layer of a thermal adhesive form of polyimide,
since it is known that quartz/Kapton.RTM. bonds formed using such
adhesives are very resilient. Sealing of other preferred
transparent sheet materials, such as diamond, sapphire or
fused-silica to the subject device may be accomplished using
adhesion techniques well known in the art.
The possibility of detecting with radiation over a range of
electromagnetic wavelengths offers a variety of spectrophotometric
detection techniques to be interfaced with a miniaturized column
according to the invention, including UV/Vis, fluorescence,
refractive index (RI) and Raman.
Furthermore, as will be readily appreciated, the use of optical
detection means comprising apertures ablated into the substrate and
cover plate provides great control over the effective detection
path length in a miniaturized column device constructed according
to the invention. In this regard, the detection path length will be
substantially equal to the combined thickness of the substrate 4
and the cover plate 12, and detection path lengths of up to 250
.mu.m are readily obtainable using the subject detection means 42
in thin-film substrates such as polyimides.
Referring now to FIG. 6, it can be seen that apertures 34 and 36
provide an enlarged volume in sample processing compartment 14 at
the point of intersection with the detection means 42, where that
volume will be proportional to the combined thickness of substrate
4 and cover plate 12. In this manner, sample plugs passing through
sample processing compartment 14 may be subject to untoward
distortion as the plug is influenced by the increased compartment
volume in the detection area, especially where the combined
thickness of the substrate and cover plate exceeds about 250 .mu.m,
thereby possibly reducing separation efficiency in the device.
Accordingly, in the present invention wherein detection path
lengths exceeding 250 .mu.m are desired, an alternative device
embodiment is provided having laser-ablated features on two
opposing surfaces of a substrate. More particularly, in FIGS. 7A
and 7B, a further embodiment of a miniaturized column device is
generally indicated at 52. The miniaturized column comprises a
substrate 54 having first and second substantially planar opposing
surfaces respectively indicated at 56 and 58. The substrate 54 has
a first microchannel 60 laser ablated in the first planar surface
56 and a second microchannel 62 laser ablated in the second planar
surface 58, wherein the microchannels can be provided in a wide
variety of geometries, configurations and aspect ratios as
described above.
The miniaturized column device of FIGS. 7A and 7B further includes
first and second cover plates, indicated at 64 and 66 respectively,
which, in combination with the first and second microchannels 60
and 62, define first and second elongate separation compartments
when substrate 54 is sandwiched between the first and second cover
plates.
Referring still to FIGS. 7A and 7B, a plurality of apertures can be
laser-ablated in the device to provide an extended separation
compartment, and further to establish fluid communication means.
More particularly, a conduit means 72, comprising a laser ablated
aperture in substrate 54 having an axis which is orthogonal to the
first and second planar surfaces 56 and 58, communicates a distal
end 74 of the first microchannel 60 with a first end 76 of the
second microchannel 62 to form an extended separation
compartment.
Further, an aperture 68, laser ablated in the first cover plate 64,
enables fluid communication with the first microchannel 60, and a
second aperture 70, laser ablated in the second cover plate 66,
enables fluid communication with the second microchannel 62. As
will be readily appreciated, when the aperture 68 is used as an
inlet port, and the second aperture 70 is used as an outlet port, a
miniaturized column device is provided having a flow path extending
along the combined length of the first and second microchannels 60
and 62.
In the embodiment of the invention as shown in FIGS. 7A and 7B, a
wide variety of sample introduction means can be employed, such as
those described above. External hardware can also be interfaced to
the subject device to provide liquid handling capabilities, and a
variety of means for applying a motive force along the length of
the separation compartment can be associated with the device, such
as by interfacing motive means with the first and/or second
apertures 68 and 70 as described above.
Additionally, a variety of detection means are easily included in
the subject embodiment. In this regard, a first aperture 78 can be
laser ablated in the first cover plate 64, and a second aperture 80
can likewise be formed in the second cover plate 66 such that the
first and second apertures will be in co-axial alignment with
conduit means 72 when the substrate 54 is sandwiched between the
first and second cover plates. Detection of analytes in a separated
sample passing through the conduit means is thereby easily enabled,
such as by connecting electrodes to the miniaturized column via
apertures 78 and 80 and detecting using electrochemical
techniques.
However, a key feature of the laser-ablated conduit means 72 is the
ability to provide an extended optical detection path length of up
to 1 mm, or greater, without experiencing untoward sample plug
distortion due to increased separation compartment volumes at the
point of detection. Referring to FIGS. 7A, 7B and 9, first and
second transparent sheets, indicated at 82 and 84 respectively, can
be provided such that the first cover plate 64 is interposed
between the first transparent sheet and the first planar surface
56, and the second cover plate 66 is interposed between the second
transparent sheet and the second planar surface 58. The transparent
sheets 82 and 84 can be selected from appropriate materials such as
quartz crystal, fused silica, diamond, sapphire and the like.
Further, the transparent sheets can be provided having just enough
surface area to cover and seal the apertures 78 and 80, or those
sheets can be sized to cover up to the entire surface area of the
column device. As described above, this feature allows additional
structural rigidity to be provided to a column device formed in a
particularly thin substrate.
As best shown in FIG. 9, the subject arrangement allows optical
detection of sample analytes passing through the miniaturized
column device to be carried out along an optical detection path
length 86 corresponding to the major axis of the conduit means 72.
As will be readily appreciated, the optical detection path length
86 is substantially determined by the thickness of the substrate
54, and, accordingly, a great deal of flexibility in tailoring a
miniaturized column device having .mu.-meter column dimensions and
optical path lengths of up to 1 mm or greater is thereby enabled
under the instant invention. In this manner, a wide variety of
associated optical detection devices may be interfaced with a
miniaturized column constructed according to the invention, and
detection of analytes in samples passing through the conduit means
72 may be carried out using UV/Vis, fluorescence, refractive index
(RI), Raman and like spectrophotometric techniques.
Referring now to FIGS. 8A and 8B, a related embodiment of the
invention is shown, comprising a miniaturized column device 52',
wherein the column portion and the first and second cover plates
are formed in a single, flexible substrate generally indicated at
88. The flexible substrate 88 thus comprises three distinct
regions, a column portion 88B, having first and second
substantially planar opposing surfaces 56' and 58', respectively,
where the column portion is interposed between a first cover plate
portion 88A and a second cover plate portion 88C. The first and
second cover plate portions have at least one substantially planar
surface. The first cover plate portion 88A and the column portion
88B are separated by at least one fold means 90 such that the first
cover plate portion can be readily folded to overlie the first
substantially planar surface 56' of the column portion 88B. The
second cover plate portion 88C and the column portion 88B are
likewise separated by at least one fold means 92 such that the
second cover plate can be readily folded to overlie the second
substantially planar surface 58' of the column portion 88B. In
particularly preferred embodiments, each fold means 90 and 92 can
comprise a row of spaced-apart perforations ablated in the flexible
substrate, spaced-apart slot-like depressions or apertures ablated
so as to extend only part way through the substrate, or the like.
The perforations or depressions can have circular, diamond,
hexagonal or other shapes that promote hinge formation along a
predetermined straight line.
Thus, the miniaturized column device 52' is formed by laser
ablating a first microchannel 60' in the first planar surface 56'
of the column portion 88B, and a second microchannel 62' in the
second planar surface 58' of the column portion. Each microchannel
can be provided in a wide variety of geometries, configurations and
aspect ratios. A first separation compartment is then formed by
folding the flexible substrate 88 at the first fold means 90 such
that the first cover plate portion 88A covers the first
microchannel 60' to form an elongate separation compartment. A
second separation compartment is then provided by folding the
flexible substrate 88 at the second fold means 92 such that the
second cover plate portion 88C covers the second microchannel 62'
to form a separation compartment as described above. A conduit
means 72', comprising a laser ablated aperture in the column
portion 88B having an axis which is orthogonal to the first and
second planar surfaces 56' and 58', communicates a distal end of
the first microchannel 60' with a first end of the second
microchannel 62' to form a single, extended separation
compartment.
Further, an aperture 68', laser ablated in the first cover plate
portion 88A, enables fluid communication with the first
microchannel 60', and a second aperture 70', laser ablated in the
second cover plate portion 88C, enables fluid communication with
the second microchannel 62'. As described above, when the first and
second apertures are used as an inlet and outlet port,
respectively, a miniaturized column device is provided having a
flow path extending along the combined length of the first and
second microchannels.
Detection means can optionally be included in the device of FIGS.
8A and 8B. In one particular embodiment, a first aperture 78' can
be laser ablated in the first cover plate portion 88A, and a second
aperture 80' can likewise be formed in the second cover plate
portion 88C, wherein the apertures are arranged to co-axially
communicate with each other and communicate with the conduit means
72' when the flexible substrate 88 is hingeably folded as described
above to accurately align the apertures 78' and 80' with the
conduit means 72'.
In yet further related aspects of the invention, optional
micro-alignment means--formed either by laser ablation techniques
or by other methods of fabricating shaped pieces well known in the
art--are provided in the miniaturized column device 52'. More
specifically, a plurality of corresponding laser-ablated apertures
(not shown) can be provided in the column portion 88B and the first
and second cover plate portions, 88A and 88C, respectively of the
flexible substrate 88. The subject apertures are arranged such that
co-axial alignment thereof enables the precise alignment of the
column portion with one, or both of the cover plate portions to
align various features such as the optional detection means with
the ablated conduit. Such optional alignment can be effected using
an external apparatus with means (such as pins) for cooperating
with the co-axial apertures to maintain the components are portions
in proper alignment with each other.
Accordingly, novel miniaturized column devices have been described
which are laser ablated into a substrate other than silicon or
silicon dioxide materials, and which avoid several major problems
which have come to be associated with prior attempts at providing
micro-column devices. The use of laser ablation techniques in the
practice of the invention enables highly symmetrical and accurately
defined micro-column devices to be fabricated in a wide class of
polymeric and ceramic substrates to provide a variety of
miniaturized liquid-phase analysis systems. In this regard,
miniaturized columns may be provided which have micro-capillary
dimensions (ranging from 5-200 .mu.m in diameter) and column
detection path lengths of up to 1 mm or greater. This feature has
not been attainable in prior attempts at miniaturization, such as
in capillary electrophoresis, without substantial engineering of a
device after capillary formation. Further, laser ablation of
miniaturized columns in inert substrates such as polyimides avoids
the problems encountered in prior devices formed in silicon or
silicon dioxide-based materials. Such problems include the inherent
chemical activity and pH instability of silicon and silicon
dioxide-based substrates which limits the types of separations
capable of being performed in those devices.
In the practice of the invention, miniaturized column devices may
be formed by laser ablating a set of desired features in a selected
substrate using a step-and-repeat process to form discrete units.
In this regard, it is particularly contemplated to laser ablate the
subject devices in condensation polymer substrates including
polyimides, polyamides, poly-esters and poly-carbonates. Further,
the instant invention may be practiced using either a laser
ablation process or a LIGA process to form templates encompassing a
set of desired features, whereby multiple copies of miniaturized
columns may be mass-produced using injection molding techniques
well known in the art. More particularly, it is contemplated herein
to form miniaturized columns by injection molding in substrates
comprised of materials such as the following: polycarbonates;
polyesters, including poly(ethylene terephthalate) and
poly(butylene terephthalate); polyamides, (such as nylons);
polyethers, including polyformaldehyde and poly(phenylene sulfide);
polyimides, such as Kapton.RTM. and Upilex.RTM.; polyolefin
compounds, including ABS polymers, Kcl-F copolymers, poly(methyl
methacrylate), poly(styrene-butadiene) copolymers,
poly(tetrafluoroethylene), poly(ethylenevinyl acetate) copolymers,
poly(N-vinylcarbazole) and polystyrene.
Laser ablation of microchannels in the surfaces of the
above-described substrates has the added feature of enabling a wide
variety of surface treatments to be applied to the microchannels
before formation of the sample processing compartment. That is, the
open configuration of laser-ablated microchannels produced using
the method of the invention enables a number of surface treatments
or modifications to be performed which are not possible in closed
format constructions, such as in prior micro-capillaries. More
specifically, laser ablation in condensation polymer substrates
provides microchannels with surfaces featuring functional groups,
such as carboxyl groups, hydroxyl groups and amine groups, thereby
enabling chemical bonding of selected species to the surface of the
subject microchannels using techniques well known in the art. Other
surface treatments enabled by the open configuration of the instant
devices include surface adsorptions, polymer graftings and thin
film deposition of materials such as diamond or sapphire to
microchannel surfaces using masking and deposition techniques and
dynamic deactivation techniques well known in the art of liquid
separations.
The ability to exert rigid computerized control over the present
laser ablation processes enables extremely precise microstructure
formation, which, in turn, enables the formation of miniaturized
columns having features ablated in two substantially planar
components wherein those components may be aligned to define a
composite sample processing compartment of enhanced symmetry and
axial alignment. In this regard, it is contemplated to provide a
further embodiment of the invention wherein laser ablation is used
to create two component halves which, when folded or aligned with
one another, define a single miniaturized column device.
Referring now to FIG. 10, a miniaturized column for liquid phase
analysis of a sample is generally indicated at 102. The
miniaturized column 102 is formed by providing a support body 104
having first and second component halves indicated at 106 and 108
respectively. The support body may comprise a substantially planar
substrate such as a polyimide film which is both laser ablatable
and flexible so as to enable folding after ablation; however, the
particular substrate selected is not considered to be limiting in
the invention.
The first and second component halves 106 and 108 each have
substantially planar interior surfaces, indicated at 110 and 112
respectively, wherein miniaturized column features may be laser
ablated. More particularly, a first microchannel pattern 114 is
laser ablated in the first planar interior surface 110 and a second
microchannel pattern 116 is laser ablated in the second planar
interior surface 112. According to the invention, said first and
second microchannel patterns are ablated in the support body 104 so
as to provide the mirror image of each other.
Referring now to FIGS. 11 and 12, a sample processing compartment
118, comprising an elongate bore defined by the first and second
microchannel patterns 114 and 116 may be formed by aligning (such
as by folding) the first and second component halves 106 and 108 in
facing abutment with each other. In the practice of the invention,
the first and second component halves may be held in fixable
alignment with one another to form a liquid-tight sample processing
compartment using pressure sealing techniques, such as by
application of tensioned force, or by use of adhesives well known
in the art of liquid phase separation devices. It is further
contemplated according to the invention to form first and second
mirochannels 114 and 116 having semi-circular cross-sections
whereby alignment of the component halves defines a sample
processing compartment 118 having a highly symmetrical circular
cross-section to enable enhanced fluid flow therethrough; however,
as discussed above, a wide variety of microchannel geometries are
also within the spirit of the invention.
In a further preferred embodiment of the invention, it is
particularly contemplated to form the support body 104 from a
polymer laminate substrate comprising a Kapton.RTM. film
co-extruded with a thin layer of a thermal plastic form of
polyimide referred to as KJ.RTM. and available from DuPont
(Wilmington, Del.). In this manner, the first and second component
halves 106 and 108 may be heat sealed together, resulting in a
liquid-tight weld that has the same chemical properties and,
accordingly, the same mechanical, electrical and chemical
stability, as the bulk Kapton.RTM. material.
Referring now to FIGS. 10-12, the miniaturized column device 102
further comprises means for communicating associated external fluid
containment means (not shown) with the sample processing
compartment 118 to provide a liquid-phase separation device. More
particularly, a plurality of apertures may be laser ablated in the
support body 104, wherein said apertures extend from at least one
exterior surface of the support body and communicate with at least
one microchannel, said apertures permitting the passage of fluid
therethrough. In this regard, an inlet port 120 may be laser
ablated in the first component half 106 and communicate with a
first end 122 of said first microchannel 114. In the same manner,
an outlet port 124 may be ablated in the first component half and
communicate with a second end 126 of said first microchannel
114.
As is readily apparent, a liquid phase sample processing device may
thereby be formed, having a flow path extending from the first end
122 of the microchannel 114 to the second end 126 thereof, by
communicating fluids from an associated source (not shown) through
the inlet port 120, passing the fluids through the sample
processing compartment 118 formed by the alignment of microchannels
114 and 116, and allowing the fluids to exit the sample processing
compartment via the outlet port 126. In this manner, a wide variety
of liquid phase analysis procedures may be carried out in the
subject miniaturized column device using techniques well known in
the art. Furthermore, various means for applying a motive force
along the length of the sample processing compartment 118, such as
a pressure differential or electric potential, may be readily
interfaced to the column device via the inlet and outlet ports, or
by interfacing with the sample processing compartment via
additional apertures which may be ablated in the support body
104.
Inlet port 120 may be formed such that a variety of external fluid
and/or sample introduction means may be readily interfaced with the
miniaturized column device 102. As discussed in greater detail
above, such means include external pressure injection, hydrodynamic
injection or electrokinetic injection mechanisms.
Referring now to FIGS. 10 and 11, the miniaturized column device
102 further comprises detection means laser ablated in the support
body 104. More particularly, a first aperture 128 is ablated in
said first component half 106 and communicates with the first
microchannel 114 at a point near the second end 126 thereof. A
second aperture 130 is likewise formed in said second component
half 108 to communicate with the second microchannel 116.
Accordingly, a wide variety of associated detection means may then
be interfaced to the sample processing compartment 118 to detect
separated analytes of interest passing therethrough, such as by
connection of electrodes to the miniaturized column via the first
and second apertures 128 and 130.
In yet a further preferred embodiment of the invention, an optical
detection means is provided in the miniaturized column device 102.
In this regard, first and second apertures 128 and 130 may be
ablated in the support body 104 such that when the component halves
are aligned to form the sample processing compartment 118 said
apertures are in co-axial alignment with one another, said
apertures further having axes orthogonal to the plane of said
support body. As will be readily appreciated by one of ordinary
skill in the art, by providing transparent sheets (not shown),
disposed over the exterior of the support body 104 and covering
said first and second apertures 128 and 130, a sample passing
through sample processing compartment 118 may be analyzed by
interfacing spectrophotometric detection means with said sample
through the transparent sheets using techniques well known in the
art. The optical detection path length may be substantially
determined by the combined thickness of said first and second
component halves 106 and 108. In this manner, an optical detection
path length of up to 250 .mu.m is readily provided by ablating the
miniaturized column device in a 125 .mu.m polymer film.
Accordingly, there have been described several preferred
embodiments of a miniaturized column device formed according to the
invention by laser ablating microstructures on component parts and
aligning the components to form columns having enhanced symmetries.
As described in detail above, formation of the subject
microchannels in the open configuration enables a wide variety of
surface treatments and modifications to be applied to the interior
surfaces of the channels before formation of the sample processing
compartment. In this manner, a wide variety of liquid phase
analysis techniques may be carried out in the composite sample
processing compartments thus formed, including chromatographic,
electrophoretic and electrochromatographic separations.
In the practice of the invention, it is further contemplated to
provide optional means for the precise alignment of component
support body halves, thereby ensuring accurate definition of a
composite sample processing compartment formed according to the
invention. More particularly, in a further preferred embodiment of
the invention, micro-alignment means are provided to enable
enhanced alignment of laser-ablated component parts such as
microchannels, detection apertures and the like.
Referring now to FIGS. 13 and 14, a miniaturized column device
constructed according to the present invention is generally
indicated at 150 and is formed in a flexible substrate 152. The
column device comprises first and second support body halves,
indicated at 154 and 156 respectively, each having a substantially
planar interior surface indicated at 158 and 160 respectively. The
interior surfaces comprise laser-ablated microstructures, generally
indicated at 162, where said microstructures are arranged to
provide the mirror image of one another in the same manner as
described in greater detail above.
The accurate alignment of component parts may be enabled by forming
a miniaturized column device in a flexible substrate 152 having at
least one fold means, generally indicated at 180, such that a first
body half 154 may be folded to overlie a second body half 156. The
fold means 180 may comprise a row of spaced-apart perforations
ablated in the substrate 152, spaced-apart slot-like depressions or
apertures ablated so as to extend only part way through the
substrate, or the like. The perforations or depressions may have
circular, diamond, hexagonal or other shapes that promote hinge
formation along a predetermined straight line.
Accordingly, in the practice of the invention, the fold means 180
allows said first and second support body halves 154 and 156 to
hingeably fold upon one another and accurately align composite
features defined by said microstructures ablated on said first and
second planar interior surfaces 158 and 160.
It is further contemplated to provide additional micro-alignment
means formed either by laser ablation or by other methods of
fabricating shaped pieces well known in the art. More specifically,
a plurality of laser-ablated apertures (not shown) may be provided
in said first and second support body halves 154 and 156 where said
apertures are so arranged such that co-axial alignment thereof
enables the precise alignment of the support body halves to define
composite features such as an ablated elongate bore. Alignment may
be effected using an external apparatus with means (such as pins)
for cooperating with said co-axial apertures to maintain the body
halves in proper alignment with one another.
Referring to FIGS. 13 and 14, in yet another particular embodiment
of the invention, micro-alignment means may been formed in said
first and second support body halves 154 and 156 using fabrication
techniques well known in the art e.g., molding or the like. In this
manner, a plurality of projections, indicated at 164, 166 and 168,
may be formed in said first support body half 154. A plurality of
depressions, indicated at 170, 172 and 174, may be formed in said
second support body half 156.
Accordingly, as is readily apparent, the micro-alignment means are
configured to form corresponding structures with one another,
whereby projection 164 mates with depression 170, projection 166
mates with depression 172, and projection 168 mates with depression
174 when said support body halves are aligned in facing abutment
with one another. In this manner, positive and precise alignment of
support body halves 154 and 156 is enabled, thereby accurately
defining composite features defined by said laser-ablated
microstructures 162.
As will be readily apparent to one of ordinary skill in the art
after reading this specification, a wide variety of corresponding
micro-alignment features may be formed in the subject miniaturized
column devices without departing from the spirit of the instant
invention. Such additional features include any combination of
holes and/or corresponding structures such as grooves and ridges in
said component parts where said features cooperate to enable
precise alignment of the component body parts.
FIG. 15 illustrates one embodiment of a .mu.-TAS. While this
embodiment is described for bioanalytical applications (see Example
1), it an object of the invention to provide start-to-finish
analysis for any solute species, including small (less than about
1000 molecular weight) solute species in complex matrices.
Generally, .mu.-TAS 200 can be constructed as described in detail
above by providing a substrate having first and second planar
opposing surfaces and laser ablating a microchannel having more
than one sample handling region (202 through 212 and 214 through
220) in the first planar substrate, and optionally having a
plurality of laser-ablated access ports (222 through 232) and
detection means (234 through 240). A sample processing compartment
having sample flow components (202 through 212) and sample
treatment components (214 through 220) corresponding to the sample
handling regions can be formed by arranging a cover plate over the
planar surface (see, e.g., FIGS. 1-4).
Alternatively, .mu.-TAS 200 may be constructed by providing a
support body having first and second component halves with planar
interior surfaces, laser ablating mirror images of a microchannel
having more than one sample handling region (202 through 212 and
214 through 220) in the interior surfaces of the first and second
component interior surfaces, and optionally having laser-ablated
access ports (222 through 232) and detection means (234 through
240). A sample processing compartment having sample flow components
(202 through 212) and sample treatment components (214 through 220)
may be formed by aligning the interior surfaces in facing abutment
with each other (see, e.g., FIGS. 10-12).
In a further embodiment, .mu.-TAS 200 may be constructed as
described above in reference to FIGS. 8A and 8B by providing a
single, flexible substrate having three distinct regions, a column
portion, having first and second substantially planar opposing
surfaces, a first cover plate portion and a second cover plate
portion. Thus, for example, a microchannel having more than one
sample handling region (202 through 212 and 214 through 220) can be
laser ablated in the first planar surface of the column portion of
the flexible substrate. A sample processing compartment is then
formed by folding the flexible substrate at the first fold means
such that the first cover plate portion covers the first planar
surface of the column portion. Alternatively, mirror images of a
microchannel having more than one sample handling region (202
through 212 and 224 through 220) can be laser ablated in the first
planar surface of the column portion and the interior surface of
the first cover portion of the flexible substrate such that a
sample processing compartment is formed by folding the flexible
substrate at the first fold means as described above by aligning
the first planar surface of the column portion with the interior
surface of the first cover portion in facing abutment with each
other.
Generally, the sample handling region of the microchannel from
which the sample flow components (202 through 222) are formed is
elongate and semi-circular in geometry. However, as described in
greater detail above, the microchannel may be formed in a wide
variety of channel geometries including semi-circular, rectangular,
rhomboid, and the like, and the channels may be formed in a wide
range of aspect ratios. The sample handling region of the
microchannel from which the sample treatment components (214
through 220) are formed is typically rectangular; however, it may
be laser ablated in any desired geometry. Furthermore, in any
particular .mu.-TAS, the sample handling regions of the
microchannel may be formed in any combination of geometries
including rectangular, square, triangular, and the like. In
addition, while the .mu.-TAS illustrated in FIG. 15 contains sample
flow components with high aspect ratios (i.e., aspect ratios in
which the depth of the microstructure is greater than the width)
and sample treatment components with low aspect ratios (i.e.,
aspect ratios in which the width of the microstructure is greater
than the depth), this is not intended to be limiting. For example,
sample treatment components may have high aspect ratios, as in
fourth sample treatment component 220.
As depicted in FIG. 15, .mu.-TAS is a serial arrangement of
alternating sample flow components 202 through 212 and sample
treatment components 214 through 220. Optionally, detection means
232 through 240 are disposed along the sample flow components. The
detection means may be formed in the cover plate, the substrate
itself, or both the cover plate and the substrate, as described in
greater detail above.
In addition, optional access ports (222 through 232) depicted in
FIG. 15 are disposed along the sample flow components. The access
ports allow the fluid communication of the sample flow component
with, for example, external liquid reservoirs or mechanical valving
necessary for the introduction or removal of samples, buffers and
the like from the sample flow component as required to effect
sample preparation by the .mu.-TAS. External hardware may also be
interfaced to the subject .mu.-TAS to provide liquid handling
capabilities, and a variety of means for applying a motive force
along the length of the sample processing compartment may be
associated with the .mu.-TAS. Thus, access ports may be in
divertable and switchable fluid communication with a valving
manifold such that a valve in communication with an access port can
be individually "actuated," i.e., opened to allow flow or closed to
prevent flow through the access port.
In particular reference to FIG. 15, .mu.-TAS 200 depicted therein
contains first access port 222 by which sample may be introduced
into first sample flow component 202 that is in fluid communication
with first sample treatment component 214. The sample may be
directly added to the sample flow component via first access port
222 without prior processing. Optionally, fist access port 222 may
be interfaced with an external pre-column sample preparation
device, e.g., a filtration device.
In one embodiment, sample treatment component 214 performs a
filtration function and may be filled with a porous medium made of
particles, sheets or membranes. In a preferred embodiment, the
medium has an effective pore size of between 45 .mu.m and 60 .mu.m.
Preferably, the medium is biocompatible and may be made from such
materials as nylon, cellulose, polymethylmethacrylate,
polyacrylamide, agarose, or the like. In an alternative embodiment,
the filtration function may be performed by an in-line device prior
to introduction of the sample into sample flow component 214.
In the particular embodiment depicted in FIG. 15, sample treatment
component 214 is designed to serve a "capture" function. Thus,
sample treatment component can be an affinity chromatography, ion
exchange chromatography, a complexation reaction or any such
quantal chromatographic technique (i.e., a chromatographic
technique that could otherwise be performed in a batch mode rather
than with a flowing sample stream). An affinity chromatography
matrix may include a biological affiant, an antibody, a lectin,
enzyme substrate or analog, enzyme inhibitor or analog, enzyme
cofactor or analog, a capture oligonucleotide, or the like,
depending on the nature of the sample. The ion exchange matrix may
be an anionic or cationic ion exchange medium. Complexation
reactions may include boronate reactions, dithiol reactions,
metal-ion reactions, for example, with porphyrin or phenanthroline,
or other reactions in which the sample is reversibly reacted with
the chromatography matrix.
First and second access ports 222 and 224 are respectively
disposed. upstream and downstream from first sample treatment
component 214. When first access port 222 is used as an input port
and second access port 224 is used as a withdrawal port, sample
treatment component 214 can be isolated from downstream .mu.-TAS
sample handling regions. Thus, while a sample is loaded onto sample
treatment component 214, extraneous materials which are flushed
from the sample treatment component during analyte capture may be
withdrawn and, in this manner, prevented from entering downstream
.mu.-TAS sample handling regions. Alternatively, second access port
224 may be used as an fluid input port to provide flow regulation,
sample derivatization, or other like function when connected to a
source of fluid which may be an external fluid source or an
on-device fluid reservoir compartment (see FIG. 16).
Once a sample has been introduced into first sample flow component
214, sample flow may be effected by way of an external motive means
which is interfaced with first access port 222. Alternatively,
sample flow into sample treatment component 214 may be effected by
activation of an on-device motive means, e.g., an on-device fluid
reservoir compartment.
First detection means 234 may be in direct or indirect
communication with second sample flow component 204 downstream from
first sample treatment component 214. First detection means 234 can
be used to monitor the presence of a sample in sample flow
component 204 which is to be loaded onto second sample treatment
component 216 or to monitor sample elution from first sample
treatment component 214. In the latter case, it is preferred that
first detection means 234 is placed in second sample flow component
204 upstream from second access port 224.
In the particular embodiment depicted in FIG. 15, second sample
treatment component 216 serves to desalt or neutralize the analyte
eluted from first sample treatment component 214. Thus, second
sample treatment component 216 may be an electrophoretic desalting,
pH neutralizing, size exclusion chromatography component, or the
like.
As with first sample treatment component 214, second sample
treatment component 216 is flanked by second and third access ports
224 and 226. First, second and third access ports 222, 224 and 226
may be used in any combination of inlet and outlet ports.
Generally, once the sample has been eluted from first sample
treatment component 214 and loaded onto second sample treatment
component 216, second access port 224 serves as an inlet port and
third access port 226 serves as an outlet port, thereby isolating
second sample treatment component 216 from downstream .mu.-TAS
sample handling regions. In order to prevent backflow into first
sample treatment component 214, first access port 222 can be
closed.
As exemplified in FIG. 15, third sample treatment component 218 has
been configured as an analyte focussing and pre-final sample
processing compartment. As such, third sample treatment component
218 can be an isoelectric focusing component, an isotachophoretic
sample stacking component, or the like. Again, third sample
treatment component 218 is flanked by third and fourth access ports
226 and 228, which may be operated in a manner similar to that
described for access port pairs 222/224 and 224/226 to isolate
third sample treatment component 218 from downstream sample
handling regions. Second and third detection means 236 and 238 may
also be used as described above for first detection means 234.
Fourth sample treatment component 220 may include single or
multiple functions selected from chromatographic, electrophoretic,
or electro-chromatographic functions. Although only one sample
treatment component 220 is shown in FIG. 15, multiple components of
various dimensions can be laser ablated in continuum and
specifically prepared as different sample processing functions in
series. Examples of chromatographic functions which may be included
in fourth sample treatment component 220 are reverse phase
chromatography, hydrophobic interaction chromatography, affinity
chromatography, size exclusion chromatography, ion exchange
chromatography, chiral separation chromatography, and the like. For
chromatographic functions, the stationary phase may be bonded or
otherwise adhered to the surface of a particle or to the walls of
the component. Examples of electrophoretic chromatography include
open tubular electrophoresis, micellar electrokinetic capillary
electrophoresis (see, Terabe et al. (1985) Anal. Chem. 57:834-831),
capillary chiral electrophoresis, and the like. Open tubular
electrophoresis includes bonded phase, dynamic deactivation using
any of a variety of inorganic or organic reagents, isoelectric
focussing, and the like. Micellar electrokinetic capillary
chromatography may be done using surfactants such as sodium dodecyl
sulfate, cetyl ammonium bromide, alkyl glucosides, alkyl
maltosides, zwitterionic surfactants such as
3-[(3-cholamidopropyl)-dimethylammonio]-1-propane sulfonate
("CHAPS"),
3-[(3-cholamidopropyl)-dimethylammonio]-2-hydroxy-1-propane
sulfonate ("CHAPSO"), or the like. Capillary chiral electrophoresis
may be done using reagents such as cyclodextrins, crown ethers,
bile salts, or the like.
Fourth detection means 240 can be situated in the sample flow
component that is downstream from fourth sample treatment component
220. The detection means may be ablated into the substrate, cover
plate, or both the substrate and the cover plate.
Optionally, as illustrated and described in detail in reference to
FIGS. 7 and 8, fourth detection means 240 may be conduit means 72
comprising a laser-ablated aperture in the substrate 54 having an
axis which is orthogonal to the first 56 and second 58 planar
surfaces of the substrate, and communicating a distal end 74 of the
sample processing compartment 60 with a first end 76 of a second
microchannel 62 to form an extended sample processing compartment.
As depicted in FIG. 9, this arrangement allows optical detection of
sample analytes passing through the .mu.-TAS to be carried out
along an optical detection path length 86 corresponding to the
major axis of the conduit means 72. In this manner, a wide variety
of associated optical detection devices may be interfaced with a
.mu.-TAS constructed according to the invention, thereby allowing
detection of analytes in samples passing through the conduit means
72 using UV/Vis, fluorescence, refractive index (RI), Raman and
like spectrophotometric techniques.
In a further optional embodiment of the .mu.-TAS, fifth access port
230 may serve one or more of a number of functions. As described
above, fifth access port 230 may serve as an outlet port for fourth
sample treatment component 220. It may optionally be attached to an
external or on-device fluid reservoir compartment, thereby
providing a means to regulate sample flow rates through the
.mu.-TAS or a means to introduce reagents into fifth sample flow
component 210 which react with the sample to facilitate sample
detection by fourth detection means 240.
Sixth access port 232 may serve one or more of a variety of
functions as well including withdrawal of sample after final
detection. Optionally, as with fifth access port 230, sixth access
port 232 may be attached to a fluid reservoir compartment. In
addition, sixth access port 232 may interface additional laser
ablated microstructures for communicating a sample droplet to a
post-column collection device (see FIGS. 17 and 18).
FIG. 16 illustrates a .mu.-TAS 250 having a laser-ablated fluid
reservoir compartment 252 as an integral "on-device" microstructure
on the substrate. Fluid reservoir compartment 252 may be formed by
laser ablation of a suitable microstructure in the substrate to
provide a compartment in which buffers or other reagents may be
held. Such reservoir compartment may be used to provide a makeup
flow fluid, a flow regulation function or to provide a reagent for
post-separation pre-detection analyte derivatization.
In one example depicted in FIG. 16A, reservoir microstructure 252
having inlet port 254 and outlet port 256 is laser ablated into
planar substrate 258. The reservoir microstructure may be formed in
any geometry and with any aspect ratio to provide a reservoir
compartment having a desired volume. Outlet port 256 can be in
fluid communication with sample processing compartment 260 by way
of interconnecting microchannel 262. The inlet port is optionally
divertably connected to an external source of fluid from which the
reservoir compartment may be filled. The reservoir compartment 252,
interconnecting reservoir flow component 262, and sample processing
compartment 260 are respectively formed from the reservoir
microstructure and the interconnecting microchannel in combination
with cover plate 264.
In another example illustrated in FIG. 16B, fluid reservoir
compartment 252 may be formed by laser ablating a reservoir
microstructure 252 having an inlet port 254 and an outlet port 256
into first planar substrate 258 and mirror image structures 252',
254' and 256' in second planar substrate 258'. The reservoir
compartment 252 is formed when the first and second substrates are
aligned as described in detail above.
Buffers or reagents held in the fluid reservoir compartment may be
delivered to sample processing compartment 260, to a sample flow
component or to a sample treatment component reservoir compartment
252 via connecting microchannel 262. Fluid flow from the reservoir
compartment to the sample processing compartment may occur via
passive diffusion. Optionally, the fluid may be displaced from the
reservoir compartment by an actuator means. A variety of micropumps
and microvalves that will find utility as an actuator means
according to the invention disclosed herein are well known in the
art and have been described, for example, in Manz et al. (1993)
Adv. Chromatogr. 33:1-66 and references cited therein.
As illustrated in cross-section in FIG. 16C, the reservoir
compartment 252 is optionally covered with thin membrane 266 to
form a diaphragm-type pump; passive one-way microvalve 268 is
optionally integrated into interconnecting microchannel 262 to
prevent backflow of displaced fluid into the reservoir compartment.
Optional gas- or liquid-filled cavity 270 is disposed above the
membrane. Actuator means 272 can be employed to effect fluid
displacement from reservoir compartment 252 by deflection of
membrane 266.
Actuator means 272 may act to directly deflect membrane 266.
Accordingly, the actuator means may be a piezoelectric, piston,
solenoid or other type of membrane-deflecting device.
Alternatively, the actuator means can be a heating means by which
the temperature inside cavity 270 can be regulated. The heating
means may be a resistance-type heating means or any type of
suitable heating means known in the art. Upon actuation, the
temperature of the heating means increases, thereby heating the
contents of cavity 270 and increasing the volume thereof, producing
a downward deflection of membrane 266, and displacing fluid from
reservoir compartment 252, into interconnecting microchannel 262,
past valve 268 and into sample processing compartment 260.
Alternatively, heating means 272 may be disposed in thermal contact
with reservoir compartment 252 itself. In this configuration, as
the heating means temperature increases, the volume of the fluid in
the reservoir compartment increases and is thereby displaced from
the reservoir compartment into the sample processing
compartment.
Other examples of pumping mechanisms which may be incorporated into
the .mu.-TAS disclosed and claimed herein include those which
operate on the principles of ultrasonic-induced transport (Moroney
et al. (1991) Proc MEM S'91, p. 277) or electrohydrodynamic-induced
transport (Richter et al. (1991) Proc MEM S'91 p. 271). In
addition, chemical valves composed of electrically driven
polyelectrolyte gels (Osada (1991) Adv. Materials 3:107; Osada et
al. (1992) Nature 355:242) may be used.
Microstructures laser ablated in the substrate for communicating a
sample droplet to a post-column sample collection device (320) are
generally shown in FIG. 17, FIGS. 17A, 17B and 17C are
cross-sections of a .mu.-TAS illustrating means whereby sample
droplets are generated and expelled from the .mu.-TAS for
post-column collection. Referring now to FIG. 17A, sixth sample
flow component 212 and sixth access port 232 are in fluid
communication with sample delivery means 302 comprising mixing
chamber 304 in fluid communication and in axial alignment with
sixth access port 232, fluid communication means 306 and an outlet
nozzle 308. The fluid communication means 306 may be a conduit
interfaced with an external source of fluid (FIG. 17A) or a
microchannel (FIG. 17C) laser ablated in the substrate. As shown in
FIG. 17A, fluid communication means 306 is in divertable fluid
communication with an external reservoir of gas or liquid (not
shown) and a means whereby a pulse of gas or liquid may be expelled
from the external reservoir, thereby generating sample droplet 310.
In FIG. 17A, post-column collection device 320 shown therein in
cross-section may be a substrate in which sample droplet receiving
microwell 322 has been laser ablated. As described with respect to
other microstructures formed by laser ablation, microwell 322 may
be of any geometry and any aspect ratio. Post-column collection
device 320 is shown in greater detail in FIG. 18.
A further example of means for generating and expelling a sample
droplet from a .mu.-TAS is shown in cross-section in FIG. 17B. A
heating means 312 can be situated in thermal contact with sample
delivery means 302. As the temperature of heating means 312
increases, a steam bubble builds up in mixing chamber 304, thereby
forming sample droplet 310. For further discussion of fluid
delivery using this method see Allen et al. (1985) Hewlett-Packard
J. May 1985:21-27. As in FIG. 17A, post-column collection device
320 shown in FIG. 17B in cross-section may be a substrate in which
sample droplet receiving microwell 322 has been laser ablated. In
addition, cover plate 324 may be movably interposed between the
.mu.-TAS and the post-column collection device 320. Cover plate 324
is a structure that has an opening 326 in axial alignment with
nozzle 308 and receiving well 322 and is intended to provide
protection of empty or filled wells from contamination or from
evaporation of sample droplets previously collected.
Yet another example of means for generating and expelling a sample
droplet from a .mu.-TAS is shown in cross-section in FIG. 17C. As
illustrated in FIG. 17C, and in further reference to FIG. 16, fluid
communication means 306 can be interconnecting microchannel 262
having a first end in fluid communication with sixth access port
232 and a second end in fluid communication with on-device fluid
reservoir compartment 252. Alternatively, fluid communication means
306 may be a microchannel having a having a first end in fluid
communication with sixth access port 232 and a second end
terminating in an access port which is in fluid communication with
an external fluid reservoir (not shown). Heating means 312 may be
situated in thermal contact with fluid communication means 306. As
described above, actuation of heating means 312 results in the
increase in the temperature thereof, the build up of a steam bubble
in mixing chamber 304, and the formation and expulsion of sample
droplet 310. Fluid communication means 306 is optionally formed
from a microchannel laser ablated in cover plate 264 or from
mirror-image microchannels laser ablated in interior surfaces 258
and 258'. As in FIGS. 17A and 17B, post-column collection device
320 shown in FIG. 17C in cross-section may be a substrate which
holds a bibulous sheet means 328 for solid-phase sample collection.
Bibulous sheet means 328 for solid-phase sample collection may be
filter paper, absorbent membranes, or the like. As described with
respect to FIG. 17B, cover plate 324 may optionally be movably
interposed between the .mu.-TAS and the post-column collection
device 320.
As shown in FIG. 18, post-column collection device 320 comprising
sample receiving means that may be sample receiving wells 322 or
bibulous sheet means 328 can be positioned relative to nozzle means
308 to receive the sample droplet 310 from the nozzle means. The
sample receiving means may be a microwell 322 laser ablated in a
substrate for liquid phase sample collection or may be a bibulous
sheet means 328 for solid-phase sample collection. The substrate
for post-column collection device 320 is optionally a material
other than silicon or silicon dioxide and microwells 322 are
laser-ablated in the substrate. As shown in FIG. 18, the receiving
means is optionally in rotatable alignment with the outlet nozzle
such that multiple fractions may be connected. Alternatively, as
shown in FIG. 18B, post-column collection device 320 includes
protection means 324 with opening 326 in axial alignment with the
outlet nozzle, wherein protection means 324 is interposed between
.mu.-TAS 200 and sample receiving wells 322. Although post-column
collection device 320 is depicted as a disc in rotatable alignment
with .mu.-TAS 200, it will be recognized by one of skill in the art
that the configuration of the collection device need not be so
limited. Thus, post-column collection device 320 may be configured,
for example, as a linear arrangement of sample receiving wells 322,
or the like.
It is to be understood that while the invention has been described
in conjunction with the preferred specific embodiments thereof,
that the description above as well as the example which follows are
intended to illustrate and not limit the scope of the invention.
Other aspects, advantages and modifications within the scope of the
invention will be apparent to those skilled in the art to which the
invention pertains.
The following example is put forth so as to provide those of
ordinary skill in the art with a complete disclosure and
description of how to use the method of the invention, and is not
intended to limit the scope of what the inventors regard as their
invention. Efforts have been made to ensure accuracy with respect
to numbers (e.g., amounts, temperature, etc.) but some errors and
deviations should be accounted for. Unless indicated otherwise,
parts are parts by weight, temperature is in .degree. C. and
pressure is at or near atmospheric.
EXAMPLE 1
Separation of Immunoglobulins from Serum
The serum sample used in this Example is composed of the following
immunoglobulin analytes.
______________________________________ IgG IgA IgM
______________________________________ Concentration 1200 200 100
(mg/dl) .mu. .gamma. fast .gamma. to .beta. fast .gamma. to .beta.
Mass (kDa) 150 160 900 ______________________________________
Examples of other serum constituents from which the immunoglobulin
analytes will be extracted include albumin (4600 mg/dl), bilirubin
(0.4 mg/dl), cholesterol (211 mg/dl), creatinine (1.1 mg/dl),
glucose (108 mg/dl), calcium (9.8 mg/dl), phosphorous (4.0 mg/dl),
nitrogen as urea (15 mg/dl) and uric acid (5.9 mg/dl).
A .mu.-TAS device with exterior dimensions of approximately 20
mm.times.60 mm is fabricated using the laser ablation techniques
described above in a polyimide material available under the
trademark Kapton.RTM. from DuPont (Wilmington, Del.). Unless
otherwise noted, the dimensions of the sample treatment components
in millimeters are indicated below as
width.times.length.times.depth.
First sample treatment component 214 is approximately
5.times.10.times.0.2. This provides component with a volume of 2.0
.mu.l. The component is loaded with a matrix having a high surface
area, for example, a microparticle or a membrane material, and
having specificity for the analyte, in this case immunoglobulins G,
A or M. The specificity of the analyte-matrix interaction is based
on, for example, the hydrophobic nature of the analyte (e.g.,
reverse phase or hydrophobic interaction chromatography) or the
ionic character of the analyte (e.g., ion exchange chromatography).
On the other hand, the specificity may be based on the specific
affinity of the matrix for the analyte. In either case, the
function of the first sample treatment component is to "capture"
the desired analyte and thereby provide a preconcentration
function. First and second access ports 222 and 224 are laser
ablated in the substrate and provide means by which fluids may be
introduced into or withdrawn from first and second sample flow
components 202 and 204 which flank first sample treatment component
214 and which are in fluid communication therewith. First and
second ports 222 and 224 are in divertable communication with a
valving manifold such that valves specifically associated with the
indicated ports can be individually "actuated" to isolate this
component during the "capture" step. In this manner, undesirable
constituents in the samples are flushed to waste during sample
loading and prior to elution of the analyte from the first sample
treatment component.
For the purpose of the example, 5 .mu.l of human serum, containing
a total of about 150 femtomoles of IgG, 2.2 femtomoles of IgM and
25 femtomoles of IgA, is loaded onto first sample treatment
component 214, which contains a membrane material containing
protein A/G (Pierce) which binds to IgG, IgA and IgM. Sample
loading may be done by injecting a bolus thereof or pumping the
sample into the component through first access port 222. The sample
is allowed to equilibrate with the protein in the first sample
treatment component 214. The component is then flushed with a
buffer solution to clear the chamber of other unbound solutes in
the sample.
After the sample has equilibrated with the capture matrix in the
first sample treatment component 214, valves associated with first
and second access ports 222 and 224 are actuated, and a decoupling
solution pumped through the component to elute the analyte from the
matrix. A qualitative spectrophotometer optically coupled to first
detection means 234 is monitored to determine when the analyte has
been eluted from first sample treatment component 214 and has been
loaded on the second sample treatment component 216.
Second sample treatment component 216 (3.times.30.times.0.2; 18
.mu.l) is designed to serve a desalting function. There are several
modes which may be used to desalt the analyte. For example,
desalting can be accomplished using an electromotive separation
based on the different mobilities of small and large solutes in a
particular matrix. One alternative desalting method uses fluid
pressure as a means for effecting mass transport, with size
exclusion chromatography as the mode of separation. Further, it is
possible that a mode combining both motive forces could be applied
simultaneously, using an electrochromatography separation mode
(see, e.g., Knox et al. (1987) Chromatographia 24:135; Knox et al.
(1989) J. Liq. Chromatogr 12:2435; Knox et al. (1991)
Chromatographia 32:317).
For the purpose of this example, second sample treatment component
216 contains an anti-convective media such as polyacrylamide,
polymethylmethacrylate or agarose. Valves associated with second
and third access ports 224 and 226 are actuated to isolate the
second sample treatment component 216 during this step.
Third sample component 218 (3.times.40.times.0.2; 24 .mu.l) serves
an analyte band focusing function. After the capture and desalting
steps, it is likely that band broadening will have occurred, and so
a band focusing step is required. Analyte focusing can be done
either by isoelectric focusing (IEF) mechanism in a gel matrix,
chromatofocusing, or by isotachophoresis.
For the purpose of this example, third sample treatment component
218 contains a liquid ampholyte or an ampholyte in a gel matrix as
described by Wehr et al (1990) Am. Biotechnol. Lab. 8:22 and Kilar
et al. (1989) Electrophoresis 10:23-29.
Valves coupled to third and fourth access ports 226 and 228 are
actuated in order to equilibrate the matrix in third sample
treatment component 218 with the appropriate buffer. Valves
communicating with second and fourth access ports 224 and 228 are
then actuated to elute the analyte from second sample treatment
component 216. Second detection means 326 is monitored to determine
when all of the analyte has been loaded into third sample treatment
component 218. Finally, the pH gradient is produced by actuating
valves communicating with third and fourth access ports 226 and
228. A so-called polybuffer having an operating range of pH 7-4 or
9-6 (Sigma) is used. Separation of IgG from IgM and IgA occurs in
this step.
Fourth sample treatment component 220 (50 .mu.m.times.50 mm; 100
nl) effects the final separation of IgA from IgM. The separation is
accomplished using capillary zone electrophoresis (CZE), in which
the separation of IgA and IgM occurs based on the large difference
between the charge/size ratio. As above, this component is loaded
and isolated by actuation of valves in the manifold which
communicate with fourth and fifth access ports 228 and 230 and
sample loading is monitored via third detection means 238.
The last step of the exemplary determination of serum
immunoglobulin analytes by the .mu.-TAS occurs in fifth sample flow
component 210 by monitoring fourth detection means 240. This is the
detection on which analyte quatitation is based. Spectrophotometric
detection would provide the quantitative data required. Fifth
access port 230 is used as a means for introducing a reagent for
post-column derivatization, e.g., dansylation or dabsylation, and
detection. Femtomoles of immunoglobulins in nanoliters of final
elution buffer yield micromolar to high nanomolar concentrations.
Depending on the path length and mode of spectrophotometric
detection, no reagent may be needed.
* * * * *