Claims
- 1. A microfluidic apparatus for performing two-dimensional biomolecular separations, the apparatus comprising:
at least one first dimension microchannel; an array of second dimension microchannels; means for performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; means for transferring the separated sample to the microchannels of the array of second dimension microchannels; means for performing a second separation in the second dimension microchannels, where the second separation is performed by applying a temperature gradient.
- 2. The apparatus of claim 1 wherein the temperature gradient comprises a spatial temperature gradient.
- 3. The apparatus of claim 1 wherein the temperature gradient comprises a temporal temperature gradient.
- 4. The apparatus of claim 1 further comprising internal heating means for producing the temperature gradient.
- 5. The apparatus of claim 1 further comprising external heating means for producing the temperature gradient.
- 6. The apparatus of claim 4 wherein the internal heating means comprises electrodes embedded within the apparatus.
- 7. The apparatus of claim 1 wherein one or more heating elements is affixed to an exposed outer surface of a planar substrate, and by which the temperature of the substrate may be controlled.
- 8. The apparatus of claim 1 wherein one or more heating elements is bonded between a first and second planar substrates, and wherein the one or more heating elements is shaped to provide a desired temperature distribution across the first and second planar substrates when current is passed through the one or more heating elements.
- 9. The apparatus of claim 8 wherein the one or more heating elements comprises thin film gold.
- 10. The apparatus of claim 8 wherein the one or more heating elements comprise metal foil.
- 11. The apparatus of claim 8 wherein the one or more heating elements comprise conductive polymer.
- 12. The apparatus of claim 8 wherein the one or more heating elements comprise conductive ink.
- 13. The apparatus of claim 8 wherein the one or more heating elements comprise an electrically-conductive wire.
- 14. The apparatus of claim 1 wherein a nonconducting dielectric film is located between a heating element and a second planar substrate containing one or more second dimension microchannels.
- 15. The apparatus of claim 1 further comprising one or more separation electrodes wherein the one or more separation electrodes comprise a thin film metal deposited and patterned onto a planar substrate.
- 16. The apparatus of claim 1 further comprising one or more separation electrodes wherein the one or more separation electrodes comprise electrically-conductive wires positioned between a first and second planar substrates.
- 17. The apparatus of claim 1 wherein the biomolecular separation is performed on a biomolecular material and the biomolecular material comprises DNA, and wherein a first dimension separation is a size-based separation and a second dimension separation is a sequence-based separation.
- 18. The apparatus of claim 17 wherein the first dimension separation is substantially retained upon transfer to the second dimension.
- 19. The apparatus of claim 17 wherein the first-dimension separation medium comprises a gel solution.
- 20. The apparatus of claim 17 wherein the second-dimension separation medium comprises a gel solution.
- 21. The apparatus of claim 19 wherein the gel solution is a sieving matrix selected from the group consisting of: cross-linked polyacrylamide, linear polyacrylamide, polydimethylamide, N-acrylamoniethoxyethanol, hydroxyethylcellulose [HEC], poly(ethylene glycol), poly(ethylene oxide) [PEO], poly(vinylpyrrolidone) [PVP], or nonionic polymeric surfactants (n-alkyl polyoxyethylene ethers).
- 22. The apparatus of claim 20 wherein the gel solution is a sieving matrix selected from the group consisting of: cross-linked polyacrylamide, linear polyacrylamide, polydimethylamide, N-acrylamoniethoxyethanol, hydroxyethylcellulose [HEC], poly(ethylene glycol), poly(ethylene oxide) [PEO], poly(vinylpyrrolidone) [PVP], or nonionic polymeric surfactants (n-alkyl polyoxyethylene ethers).
- 23. The apparatus of claim 1 further comprising a detector placed near a second end of the array of second-dimension microchannels for monitoring the separated biomolecules.
- 24. The apparatus of claim 1 further comprising measurement means for monitoring DNA fragments resolved from the second separation dimension.
- 25. The apparatus of claim 1 further comprising an integrated optical detection system.
- 26. The apparatus of claim 1 further comprising an integrated laser-induced fluorescence detection system.
- 27. The apparatus of claim 1 further comprising an integrated laser-induced fluorescence detection system capable of simultaneously monitoring each second-dimension microchannels in the array of second-dimension microchannels.
- 28. The apparatus of claim 1 wherein first ends of the second-dimension microchannels terminate at the at least one first-dimension microchannel at one or more points between the first and second ends of the at least one first-dimension microchannel, and wherein an outlet reservoir is in fluid communication with the second ends of the second-dimension microchannels.
- 29. The apparatus of claim 1 wherein the second-dimension microchannels have first and second ends and the at least one first dimension microchannel intersects the second dimension microchannels at a position somewhere between the first and second ends of the second-dimension microchannels.
- 30. The apparatus of claim 29 wherein an inlet reservoir is in fluid communication with the first end of the second dimension microchannels and an outlet reservoir is in fluid communication with the second end of the second dimension microchannels.
- 31. The apparatus of claim 29 wherein the first ends of the second-dimension microchannels terminate at the at least one first-dimension microchannel and further comprising an array of tertiary microchannels, wherein a second end of the tertiary microchannels terminate at the at least one first-dimension microchannel.
- 32. The apparatus of claim 31 wherein the points at which the second-dimension microchannels intersect with the at least one first-dimension microchannel are staggered with respect to the points at which the tertiary microchannels intersect with the at least one first-dimension microchannel.
- 33. The apparatus of claim 31 wherein an outlet reservoir is in fluid communication with the second end of the second dimension microchannels and one or more inlet reservoirs are in fluid communication with the first end of the tertiary microchannels.
- 34. The apparatus of claim 1 further comprising first and second planar substrates and wherein the first and second planar substrates comprise glass.
- 35. The apparatus of claim 1 further comprising first and second planar substrates and wherein the first and second planar substrates comprise plastic.
- 36. The apparatus of claim 1 further comprising first and second planar substrates and wherein the first and second planar substrates comprise polycarbonate plastic.
- 37. The apparatus of claim 1 further comprising first and second planar substrates and wherein the first and second planar substrates comprise a combination of dissimilar materials.
- 38. The apparatus of claim 1 wherein the at least one first dimension microchannel and the second dimension microchannels have an inner width of between about 5 μm and about 200 μm.
- 39. The apparatus of claim 1 wherein the at least one first dimension microchannel and the second dimension microchannels have an average inner width of between about 5 μm and about 80 μm.
- 40. The apparatus of claim 1 wherein the at least one first dimension microchannel and the second dimension microchannels have an average inner width of between about 5 μm and about 20 μm.
- 41. The apparatus of claim 1 wherein the at least one first dimension microchannel and the second dimension microchannels possess different average widths.
- 42. The apparatus of claim 1 wherein the at least one first-dimension microchannel has an average width substantially smaller than the second-dimension microchannels.
- 43. The apparatus of claim 1 wherein the second-dimension microchannels have an average width substantially smaller than the at least one first-dimension microchannel.
- 44. The apparatus of claim 1 wherein the at least one first dimension microchannel and the second dimension microchannels have an inner depth of between about 5 μm and about 200 μm.
- 45. The apparatus of claim 1 wherein the at least one first dimension microchannel and the second dimension microchannels have an average inner depth of between about 5 μm and about 80 μm.
- 46. The apparatus of claim 1 wherein the at least one first dimension microchannel and the second dimension microchannels have an average inner depth of between about 5 μm and about 20 μm.
- 47. The apparatus of claim 1 wherein the at least one first-dimension microchannel is between about 1 cm and about 50 cm long.
- 48. The apparatus of claim 1 wherein the at least one first-dimension microchannel is between about 1 cm and about 4 cm long.
- 49. The apparatus of claim 1 wherein the second-dimension microchannels are between about 1 cm and about 50 cm long.
- 50. The apparatus of claim 1 wherein the second-dimension microchannels are between about 1 cm and about 4 cm long.
- 51. The apparatus of claim 1 further comprising an electric field and wherein the electric field along the at least one first-dimension microchannels is between about 100 V/cm and about 1000 V/cm.
- 52. The apparatus of claim 1 further comprising an electric field and wherein the electric field along the second-dimension microchannels is between about 100 V/cm and about 1000 V/cm.
- 53. A method for performing two-dimensional biomolecular separations, the method comprising the steps of:
providing at least one first dimension microchannel; providing an array of second dimension microchannels; performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; transferring the separated sample to the array of second dimension microchannels; and performing a second separation in the second dimension microchannels, where the second separation is performed by applying a temperature gradient.
- 54. The method of claim 53 wherein the temperature gradient is applied using one or more heating elements affixed to the external surface of a first or a second planar substrate.
- 55. The method of claim 53 wherein the temperature gradient is applied using one or more heating elements enclosed between a first and second planar substrate, wherein resistive heating of the one or more heating elements produces the temperature gradient.
- 56. The method of claim 53 wherein the temperature gradient varies from about 23 degrees Celcius at the intersection between the at least one first-dimension microchannel and the second-dimension microchannel, to about 90 degrees Celcius at a second end of the second-dimension microchannels.
- 57. The method of claim 53 wherein the temperature gradient varies from about 23 degrees Celcius at the intersection between the at least one first-dimension microchannel and the second-dimension microchannels, to about 70 degrees Celcius at a second end of the second-dimension microchannels.
- 58. The method of claim 53 wherein the temperature gradient varies from about 90 degrees Celcius at the intersection between the at least one first-dimension microchannel and the second-dimension microchannel, to about 23 degrees Celcius at a second end of the second-dimension microchannels.
- 59. The method of claim 53 wherein the temperature gradient varies from about 70 degrees Celcius at the intersection between the at least one first-dimension microchannel and the second-dimension microchannel, to about 23 degrees Celcius at a second end of the second-dimension microchannels.
- 60. The method of claim 53 wherein the temperature gradient is a temporal temperature gradient, wherein;
b) one or more heating elements induce a constant spatial temperature across a length and width of the second-dimension microchannels; and b) the constant spatial temperature is varied with time;
- 61. The method of claim 60 wherein the constant spatial temperature is varied from an initial temperature of about 23 degrees Celcius to a final temperature of about 90 degrees Celcius.
- 62. The method of claim 60 wherein the constant spatial temperature is varied from an initial temperature of about 23 degrees Celcius to a final temperature of about 70 degrees Celcius.
- 63. The method of claim 60 wherein the constant spatial temperature is varied from an initial temperature of about 90 degrees Celcius to a final temperature of about 23 degrees Celcius.
- 64. The method of claim 60 wherein the constant spatial temperature is varied from an initial temperature of about 70 degrees Celcius to a final temperature of about 23 degrees Celcius.
- 65. The method of claim 53 wherein the biomolecular separations are performed on biomolecules and wherein the biomolecules are DNA molecules.
- 66. A microfluidic apparatus for performing two-dimensional biomolecular separations, the apparatus comprising:
at least one first dimension microchannel; an array of second dimension microchannels; means for performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; means for electrokinetically transferring the separated sample simultaneously to the second dimension microchannels; and means for performing a second separation in the second dimension microchannels, where the second separation is performed by applying a temperature gradient.
- 67. A microfluidic apparatus for performing two-dimensional biomolecular separations, the apparatus comprising:
at least one first dimension microchannel for performing a first biomolecular separation; an array of one or more second dimension microchannels for performing a second separation; an array of one or more tertiary microchannels; one or more electrodes that intersect the one or more second dimension microchannels and the one or more tertiary microchannels; one or more voltage sources operatively connected to the one or more electrodes to control the voltage at the points of intersection with the microchannels.
- 68. A method for performing two-dimensional biomolecular separations, the method comprising the steps of:
providing a first dimension microchannel; providing an array of second dimension microchannels; performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; and electrokinetically transferring the separated sample to the second dimension microchannels.
- 69. A method for performing two-dimensional biomolecular separations, the method comprising the steps of:
providing at least one first dimension microchannel; providing an array of second dimension microchannels; performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; and simultaneously transferring the separated sample to the second dimension microchannels.
- 70. A method for performing two-dimensional biomolecular separations, the method comprising the steps of:
providing at least one first dimension microchannel; providing an array of second dimension microchannels; performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; and electrokinetically transferring the separated sample simultaneously to the second dimension microchannels.
- 71. A method for performing two-dimensional biomolecular separations, the method comprising the steps of:
providing at least one first dimension microchannel; providing an array of second dimension microchannels; performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; and electrokinetically transferring the separated sample simultaneously to the second dimension microchannels; and performing a second separation in the second dimension microchannels, where the second separation is performed by applying a temperature gradient.
- 72. A method for performing two-dimensional biomolecular separations, the method comprising the steps of:
providing at least one first dimension microchannel; providing an array of second dimension microchannels; providing at least one voltage-control microchannel; performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; and applying a voltage gradient in the voltage-control microchannels to individually define the voltage within the second-dimension microchannels near the intersections of the first-dimension microchannel and second-dimension microchannels to be nearly equal to the voltage within the first-dimension microchannel near the intersections of the first-dimension microchannel and second-dimension microchannels; and electrokinetically transferring the separated sample simultaneously to the second dimension microchannels; and performing a second separation in the second dimension microchannels, where the second separation is performed by applying a temperature gradient.
- 73. A microfluidic apparatus for performing two-dimensional biomolecular separations, the apparatus comprising:
a) at least one first-dimension microchannel for receiving a first-dimension separation medium, wherein the at least one first dimension channel has a first end and a second end and extends in a first direction; b) an array of one or more second-dimension microchannels for receiving a second-dimension separation medium, wherein the microchannels of the array of one or more second-dimension microchannels each have a first end and a second end, extend in a second direction orthogonal to the first direction and intersect with the at least one first-dimension microchannel; c) a first reservoir in fluid communication with the at least one first dimension microchannel, d) at least a first electrode, having a first end and a second end, the first end being in electrical communication with the first reservoir, g) at least one voltage source in electrical communication with the second end of the first electrode; h) at least a second reservoir in fluid communication with microchannels of the array of second dimension microchannels; i) at least a second electrode, having a first end and a second end, the first end being in electrical communication with the second reservoir; and j) at least one voltage source in electrical communication with the second end of the second electrode.
- 74. A microfluidic apparatus for performing two-dimensional biomolecular separations, the apparatus comprising:
a) a first planar substrate containing one or more microchannels; b) a second planar substrate bonded to the first planar substrate to provide enclosure of the one or more microchannels; c) a first-dimension microchannel containing a first-dimension separation medium, wherein the channel has a first end and a second end; d) an array of one or more second-dimension microchannels containing a second-dimension separation medium, wherein the microchannels have a first end and a second end, and wherein the one or more second-dimension microchannels intersect the first-dimension microchannel; e) one or more injection microchannels, wherein the microchannels have a first end and a second end, and wherein the one or more injection microchannels intersect the first-dimension microchannel near the first end of the first-dimension microchannel; f) one or more reservoirs formed in the first or second substrate having disposed therein an electrolyte solution and a first end of one or more separation electrodes, and wherein the reservoirs are located at the end of the one or more microchannels; g) one or more high voltage power supplies attached to a second end of a selected number of the one or more separation electrodes; and h) one or more grounding electrodes attached to the second end of a selected number of the one or more separation electrodes
- 75. The apparatus of claim 74 wherein the one or more reservoirs include:
a) a sample injection inlet reservoir intersecting the first end of the injection microchannel; b) a sample injection outlet reservoir intersecting the second end of the injection microchannel; c) a first-dimension separation inlet reservoir intersecting the first end of the first-dimension microchannel; d) a first-dimension separation outlet reservoir intersecting the second end of the first-dimension microchannel; e) one or more second-dimension separation inlet reservoirs intersecting the first end of the one or more second-dimension microchannels; and f) one or more second-dimension separation outlet reservoirs intersecting the second end of the one or more second-dimension microchannels.
- 76. A method of performing two-dimensional gel electrophoresis of biomolecules, comprising:
a) applying a high electric field along the length of the injection microchannel, thereby injecting a sample stream containing the biomolecules of interest from the first end of the injection microchannels towards the second end of the injection microchannel, wherein;
1) a high voltage is applied to the electrode disposed within the injection outlet reservoir; 2) a grounding voltage is applied to the electrode disposed within the injection inlet reservoir; 3) all other reservoirs are disconnected from any voltage source; 4) the sample stream crosses through a portion of the first-dimension microchannel. b) applying a high electric field along the length of the first-dimension microchannel, thereby separating the biomolecules based on their migration time through the gel contained therein and resulting in separation of the biomolecules based on their size, wherein;
1) a high voltage is applied to the electrode disposed within the first-dimension outlet reservoir; 2) a grounding voltage is applied to the electrode disposed within the first-dimension inlet reservoir; 3) all other reservoirs are disconnected from any voltage source; 4) the separated sample stream passes by the one or more second-dimension microchannels intersecting with the first-dimension microchannels. c) applying a high electric field along the length of the one or more second-dimension microchannels while applying a temperature gradient, thereby denaturing the biomolecules and further separating the biomolecules based on their migration time through the gel contained therein, wherein;
1) a spatial temperature gradient is formed along the length of the one or more second-dimension microchannels; 2) a high voltage is applied to the electrode disposed within the second-dimension outlet reservoir; 3) a grounding voltage is applied to the electrode disposed within the second-dimension inlet reservoir; 4) all other reservoirs are disconnected from any voltage source.
- 77. The method of claim 76 wherein a low voltage is applied to the first-dimension outlet reservoir, with a grounding voltage applied to the one or more first-dimension inlet reservoirs, and the second-dimension inlet reservoir is disconnected from any voltage source, during application of the high electric field along the length of the one or more second-dimension separation microchannels, thereby generating a small electric field along the length of the first-dimension microchannel and causing biomolecules to be drawn slightly towards the first-dimension outlet reservoir to ensure efficient transfer of the biomolecules from the first-dimension microchannel into the one or more second dimension microchannels.
- 78. The method of claim 76 wherein one or more intersection control voltages are applied to the one or more second-dimension separation inlet reservoirs and the one or more second-dimension separation outlet reservoirs to control the electric field lines at the intersection of the one or more first-dimension separation microchannels and the one or more second-dimension separation microchannels in such a manner that the distribution of biomolecules undergoing separation during the first-dimension separation step are not substantially affected by the intersections.
- 79. The method of claim 76 wherein one or more intersection control voltages are applied to the one or more voltage-control microchannel inlet reservoirs and the one or more voltage-control microchannel outlet reservoirs to control the electric field lines at the intersection of the one or more first-dimension separation microchannels and the one or more second-dimension separation microchannels in such a manner that the distribution of biomolecules undergoing separation during the first-dimension separation step are not substantially affected by the intersections.
- 80. The method of claim 76 wherein the one or more intersection control voltages are applied using a plurality of voltage sources, wherein;
a) one voltage source is connected to the first end of a first resistive element; b) a second voltage source is connected to the second end of the first resistive element to generate a potential gradient along the first resistive element; c) the resistive element is placed in electrical contact with the one or more second-dimension separation inlet microchannels such that the intersection control voltage at each point of electrical contact is set by the voltage of the first resistive element at the point of electrical contact; d) the one or more intersection control voltages are chosen such that the voltage near the intersection of the one or more first-dimension separation microchannels and the one or more second-dimension separation microchannels at which the intersection control voltage is applied is slightly different than the voltage within the intersection itself. e) A third voltage source is connected to the first end of a second resistive element; f) a fourth voltage source is connected to the second end of the second resistive element to generate a potential gradient along the second resistive element; g) the resistive element is placed in electrical contact with the one or more second-dimension separation inlet reservoirs such that the intersection control voltage in each reservoir is set by the voltage of the second resistive element at the point of electrical contact; h) the one or more intersection control voltages are chosen such that the voltage near the intersection of the one or more first-dimension separation microchannels and the one or more second-dimension separation microchannels connected to the reservoir at which the intersection control voltage is applied is slightly different than the voltage within the intersection itself.
- 81. The method of claim 76 wherein the one or more intersection control voltages are applied using a plurality of voltage sources, wherein;
a) one voltage source is connected to the inlet reservoir of a first voltage-control microchannel; b) a second voltage source is connected to the outlet reservoir of a first voltage-control microchannel to generate a potential gradient along the first voltage-control microchannel; c) the first voltage-control microchannel intersects the one or more second-dimension separation microchannels such that the intersection control voltage in each second-dimension separation microchannel is set by the voltage of the inlet reservoir and outlet reservoir of the first voltage-control microchannel; d) the one or more intersection control voltages are chosen such that the voltage near the intersection of the one or more first-dimension separation microchannels and the one or more second-dimension separation microchannels is slightly different than the voltage within the intersection itself. e) A third voltage source is connected to the inlet reservoir of a second voltage-control microchannel; f) a fourth voltage source is connected to the outlet reservoir of a second voltage-control microchannel to generate a potential gradient along the second voltage-control microchannel; g) the second voltage-control microchannel intersects the one or more tertiary microchannels such that the intersection control voltage in each tertiary microchannel is set by the voltage of the inlet reservoir and outlet reservoir of the second voltage-control microchannel; h) the one or more intersection control voltages are chosen such that the voltage near the intersection of the one or more first-dimension separation microchannels and the one or more tertiary microchannels is slightly different than the voltage within the intersection itself.
- 82. A microfluidic apparatus for performing two-dimensional biomolecular separations, the apparatus comprising:
at least one first dimension microchannel; an array of second dimension microchannels; means for performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; and means for electrokinetically transferring the separated sample to the second dimension microchannels.
- 83. A microfluidic apparatus for performing two-dimensional biomolecular separations, the apparatus comprising:
at least one first dimension microchannel; an array of second dimension microchannels; means for performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; and means for simultaneously transferring the separated sample to the second dimension microchannels.
- 84. A microfluidic apparatus for performing two-dimensional biomolecular separations, the apparatus comprising:
at least one first dimension microchannel; an array of second dimension microchannels; means for performing a first biomolecular separation in the first dimension microchannel to produce a separated sample; and means for electrokinetically transferring the separated sample simultaneously to the second dimension microchannels.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims priority from U.S. Provisional Patent Application Serial No. 60/287,801, filed May 1, 2001, which is incorporated herein by reference in its entirety.
Provisional Applications (1)
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Number |
Date |
Country |
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60287801 |
May 2001 |
US |