RU2000123565A - DEVICE AND METHOD FOR CAPILLARY ELECTROPHORESIS - Google Patents

Claims (1)

1. An electrophoresis device comprising a plurality of capillaries, each of said plurality of capillaries intersecting a plane, and said plurality of capillaries arranged to intersect said plane such that the intersection points of each of said plurality of capillaries with said plane form a curved outline; a capillary guide with an inner surface and an outer surface, said capillary guide comprising capillary inlets at a first end and capillary outlets at a second end, and said capillaries extend along a portion of said outer surface; and a capillary illuminator located outside said capillary guide.  2. The electrophoresis device according to claim 1, further containing a light-collecting lens outside said capillary guide to collect light emitted by substances inside said capillaries.  3. The electrophoresis device according to claim 1, wherein said illuminator comprises one or more lenses for focusing light on the interior of said capillaries.  4. The electrophoresis device according to claim 1, wherein said capillary illuminator is mounted on a stationary platform, and said capillary guide rotates in front of said illuminator for sequential illumination of each of said plurality of capillaries.  5. The device for electrophoresis according to claim 1, further comprising a filling / overfilling system for filling or overfilling said capillaries with liquid.  6. The electrophoresis device according to claim 5, wherein said filling / overfilling system allows filling or overfilling said capillaries with liquid without disconnecting said capillaries from said device.  7. The electrophoresis device according to claim 5, further comprising a capillary guide having inner and outer surfaces and first and second ends, said capillary guide comprising capillary inlets at one end and capillary outlets at the other end, and said capillaries are exposed along at least a portion of said outer surface of said capillary guide.  8. The electrophoresis device according to claim 7, further comprising an upper buffer chamber substantially surrounding one end of said capillary guide, said upper buffer chamber comprising a housing with a channel extending along its periphery and one or more openings for receiving said output ends of said capillaries, so that said output ends can contact a buffer in said channel; an electrical conductor extending along said channel; and a connector electrically connected to said conductor for supplying voltage to said output ends of said capillaries.  9. The device according to claim 8, wherein said filling / overfilling system comprises one or more inlet ports in fluid communication with said capillaries and said channel for supplying liquid to said capillaries.  10. The device according to claim 9, wherein said filling / overfilling system further comprises one or more output ports in fluid communication with said channel and said upper buffer chamber, for removing liquid from said channel in said upper buffer chamber.  11. The device according to claim 10, wherein said filling / overfilling system further comprises solenoid valves connected to said input ports and to said output ports, for regulating a fluid flow through said input and output ports.  12. The device according to claim 11, wherein said filling / overfilling system further comprises one or more reservoirs containing said liquid, said reservoirs being in fluid communication with said capillaries and said channel, and a pump for transferring said liquid from said reservoirs to said capillaries and said channel.  13. The device according to p. 12, in which said pump comprises a high pressure pump.  14. The device according to p. 12, further containing a lower buffer chamber located so that said capillaries can contact a buffer in said lower buffer chamber.  15. An electrophoresis device comprising a plurality of capillaries and a filling / overfilling system for filling or overfilling said capillaries with liquid, each of said plurality of capillaries intersecting a plane, and said plurality of capillaries arranged to intersect said plane so that the intersection points of each said plurality of capillaries with said plane form a curved contour.  16. The device according to p. 15, in which the aforementioned curved contour is almost closed.  17. The device according to claim 15, wherein said curved contour forms at least a portion of a circle.  18. The device according to p. 17, in which said capillaries are additionally placed so as to intersect said plane at right angles to it in order to form an almost cylindrical chain of capillaries.  19. The device according to claim 15, wherein said filling / overfilling system allows the capillaries to be filled or overfilled with liquid without disconnecting said capillaries from said device.  20. The device according to p. 15, further containing a capillary guide having an inner surface and an outer surface, said capillary guide comprising capillary inlets at the first end and capillary outlets at the second end, and said capillaries extend along a portion of said inner surface.  21. An electrophoresis device according to claim 20, further comprising a capillary illuminator located inside said capillary guide.  22. The electrophoresis device according to claim 21, further comprising a light-collecting lens inside said capillary guide to collect light emitted from substances inside said capillaries.  23. The electrophoresis device according to claim 21, wherein said illuminator comprises one or more lenses for focusing light on the interior of said capillaries.  24. The electrophoresis apparatus of claim 21, wherein said capillary illuminator is mounted on a rotating platform for sequentially illuminating each of said plurality of capillaries.  25. Device for electrophoresis, containing many capillaries; a light source for illuminating said capillaries; a light collector for detecting light emitted by substances inside said capillaries, said light collector comprising a spectral separator and at least one charge-coupled single-line device. 26. The electrophoresis device according to claim 25, wherein said spectral separator comprises a diffraction grating,
27. The device according to p. 25, further containing a filling / overfilling system for filling or overfilling said capillaries with liquid.  28. The electrophoresis device according to claim 27, wherein said filling / overfilling system allows the capillaries to be filled or re-filled with liquid without disconnecting said capillaries from said device.  29. A method for determining the sequence of multiple nucleic acid chains, comprising the following steps: generating a set of nucleic acid fragments labeled with one or more dyes, the fragments in each element of the said set ending specifically with a nucleotide of one of the four types present in DNA; introducing one or more elements of said set of labeled nucleic acids into one or more of a plurality of capillary tubes arranged in a chain in an electrophoresis device comprising a filling / overfilling system for filling or overfilling said capillaries with a liquid, each of said plurality of capillaries intersecting a plane, and said plurality of capillaries are arranged so as to intersect said plane so that the intersection points of each of said plurality Auger capillaries with the aforementioned plane form a curved contour; separating said labeled fragments by size; coverage of the above fragments; and detecting light emitted by said one or more dyes.  30. The method of claim 29, wherein the step of detecting light comprises a step of directing said light to a charge-coupled single-line device.  31. The method of claim 29, wherein said step of illuminating said fragments comprises a step of passing a beam of light around the interior of said chain.  32. The method of claim 29, wherein said step of illuminating said fragments comprises a step of scrolling the outer part of said chain in front of a ray of light.  33. The method of claim 29, wherein said introduction step comprises introducing one or more elements of said set of labeled nucleic acids into one or more of a plurality of capillary tubes arranged in a chain in an electrophoresis device comprising a filling / overfilling system for filling or overfilling said capillaries with liquid without disconnecting said capillaries from said device, wherein each of said plurality of capillaries intersects a plane, and said plurality crosses the apillaries are arranged so as to intersect said plane so that the intersection points of each of said plurality of capillaries with said plane form a curved contour.  34. A method of manufacturing a device for capillary electrophoresis, comprising the following steps: placing a plurality of capillaries so that each of said plurality of capillaries intersects a plane, and said plurality of capillaries is arranged so as to intersect said plane so that the intersection points of each of said plurality of capillaries with the said plane form a curved contour; installing a light-collecting lens in close proximity to at least one of said plurality of capillaries; and connecting the filling / overfilling system to said capillaries so that said capillaries can be filled or overfilled with liquid.  35. The method according to p. 34, wherein said placement step comprises the steps of installing said plurality of capillaries on a capillary rail and installing said capillary rail on a rotating platform.  36. The method of claim 34, wherein said step of installing the light-collecting lens comprises installing a light-collecting lens on a rotating platform.  37. The method of claim 34, wherein said connection step comprises connecting a filling / overfilling system to said capillaries so that said capillaries can be filled or overfilled with liquid without disconnecting said capillaries from said device.  38. An electrophoresis apparatus comprising a chain of capillaries containing a plurality of capillaries, said capillaries having ends for sample entry and ends for sample exit, each of the plurality of capillaries intersecting a plane, and said plurality of capillaries arranged to intersect said plane such so that the intersection points of each of said plurality of capillaries with said plane form a curved contour; a light source configured to direct light onto said capillary chain; a illuminator mounted on a rotating platform inside said capillary chain, said illuminator configured to focus light from said light source on said individual capillaries and said illuminator is further configured to output light emitted by substances in the individual said capillaries from said capillary chain; a spectral separator configured to receive said light emitted by said substances located in said capillaries and to emit said light after spectral separation; and at least one charge-coupled single-line device located for receiving light with a first wavelength emitted by said spectral separator in a first portion located thereon, and for receiving light with a second wavelength emitted by said spectral separator in a second located on mute plot.  39. The electrophoresis device according to claim 38, further comprising a capillary guide having inner and outer surfaces and first and second ends, said capillary guide comprising capillary inlets at one end and capillary outlets at the other end, and said capillaries extend along along at least a portion of said inner surface of said capillary guide.  40. The electrophoresis device according to claim 39, further comprising an upper buffer chamber substantially surrounding one end of said capillary guide, said upper buffer chamber comprising a housing with a channel extending along its periphery and one or more openings therein for receiving said output the ends of said capillaries, so that said output ends can contact a buffer in said channel; an electrical conductor extending along said channel; and a connector electrically connected to said conductor for supplying voltage to said output ends of said capillaries.  41. The device according to p. 40, further comprising a filling / overfilling system for filling or overfilling said capillaries with liquid.  42. The device according to claim 41, wherein said filling / overfilling system comprises one or more inlet ports in fluid communication with said capillaries and said channel for supplying liquid to said capillaries.  43. The device according to claim 41, wherein said filling / overfilling system allows filling or overfilling said capillaries with liquid without disconnecting said capillaries from said device.  44. The device according to claim 42, wherein said filling / overfilling system further comprises one or more output ports in fluid communication with said channel and said upper buffer chamber, for removing liquid from said channel in said upper buffer chamber.  45. The device according to claim 43, wherein said filling / overfilling system further comprises solenoid valves connected to said input ports and to said output ports, for controlling a fluid flow through said input and output ports.  46. The device according to claim 45, wherein said filling / overfilling system further comprises one or more reservoirs containing said liquid, said reservoirs being in fluid communication with said capillaries and said channel, and a pump for transferring said liquid from said reservoirs to said capillaries and said channel.  47. The device according to p. 46, wherein said pump comprises a high pressure pump.  48. The device according to p. 46, further containing a lower buffer chamber located so that said ends of the sample inlet of said capillaries can contact a buffer in said lower buffer chamber.  49. An electrophoresis apparatus comprising a rotating chain of capillaries, said capillaries having ends for sample entry and ends for sample exit, each of said plurality of capillaries intersecting a plane, and said plurality of capillaries arranged to intersect said plane so that the intersection points of each of said plurality of capillaries with said plane form a curved contour; a light source configured to direct light to said capillary array; a spectral separator configured to receive said light emitted by said substances located in said capillaries and to emit said light after spectral decomposition; and at least one charge-coupled single-line device located for receiving light with a first wavelength emitted by said spectral separator in a first portion located thereon, and for receiving light with a second wavelength emitted by said spectral separator in a second located on mute plot.  50. The electrophoresis device according to claim 49, further comprising a capillary guide having inner and outer surfaces and first and second ends, said capillary guide comprising capillary inlets at one end and capillary outlets at the other end, and said capillaries extend along at least a portion of said outer surface of said capillary guide.  51. Device for electrophoresis, containing many capillaries having ends of the input of the sample and the ends of the output of the sample; Light source; a rotating illuminator configured to direct light from said light source to said capillaries; a detector configured to detect light emitted by substances in the plurality of capillaries; and a filling / overfilling system for filling or overfilling said capillaries with liquid.  52. The electrophoresis device according to claim 51, wherein said filling / overfilling system allows the capillaries to be filled or re-filled with liquid without disconnecting said capillaries from said device.  53. Device for electrophoresis, containing a rotating set of capillaries having ends of the input of the sample and the ends of the output of the sample; Light source; a detector configured to detect light emitted by substances in the plurality of capillaries.  54. The device according to p. 53, further containing a filling / overfilling system for filling or overfilling said capillaries with liquid.  55. The electrophoresis device according to claim 54, wherein said filling / overfilling system allows the capillaries to be filled or re-filled with liquid without disconnecting said capillaries from said device.  56. A method for performing electrophoresis, comprising the following steps: rotating a chain of capillaries; illumination of capillaries in said rotating chain; and detecting light emitted by substances in said capillaries.  57. The method of claim 56, wherein said rotation step comprises rotating a chain of capillaries, wherein each of said capillaries intersects a plane, and said capillaries are arranged to intersect said plane so that the intersection points of each of said capillaries with said plane form curved contour.  58. A method for performing electrophoresis, comprising the following steps: rotating a illuminator in front of an array of capillaries in a device; detection of light emitted by substances in said capillaries; and filling / overfilling said capillaries with a liquid using the filling / overfilling system of said device.  59. The method of claim 58, wherein said step of rotating the illuminator comprises rotating the illuminator in front of a chain of capillaries, each of said capillaries intersecting a plane and said capillaries being arranged to intersect said plane so that the intersection points of each of said capillaries are the mentioned plane form a curved contour.  60. The method of claim 58, wherein said filling / overfilling step comprises filling / overfilling said capillaries with a liquid using the filling / overfilling system of said device without disconnecting said capillaries from said device.  61. A support with a base for aligning capillaries with cells in a microbiological plate, comprising a housing having holes, said holes being sized to include capillaries, and configured to align said holes with cells in said microbiological plate when said the housing is located above the microbiological die.  62. A method for determining the sequence of multiple nucleic acid chains, comprising the following steps: generating a set of nucleic acid fragments labeled with one or more dyes, the fragments in each element of the said set ending specifically with a nucleotide of one of the four types present in DNA; introducing one or more elements of said set of labeled nucleic acids into one or more of a plurality of capillary tubes in an electrophoresis device comprising a plurality of capillaries, each of said plurality of capillaries intersecting a plane, and said plurality of capillaries arranged to intersect said plane in such a way that the intersection points of each of said plurality of capillaries with said plane form a curved contour, and a capillary guide, Commercially inner surface and an outer surface, wherein said capillary guide includes capillary inputs at a first end and capillary outputs at the second end, and said capillaries are located along a portion of said outer surface; separating said labeled fragments by size; lighting said fragments by scrolling the outer parts of said plurality of capillary tubes in front of a ray of light; and detecting light emitted by said one or more dyes.  63. The method of claim 62, wherein the step of detecting light comprises a step of directing said light to a charge-coupled single-line device.