IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0984979
(1997-12-04)
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발명자
/ 주소 |
- Baer,Thomas M.
- Head,David F.
- Toeppen,John
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출원인 / 주소 |
- Arcturus Bioscience, Inc.
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
11 인용 특허 :
171 |
초록
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Systems and methods for acquiring laser capture microdissection samples are disclosed. An integral portion of a biological reaction vessel includes a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to the substrate surface of the transfer f
Systems and methods for acquiring laser capture microdissection samples are disclosed. An integral portion of a biological reaction vessel includes a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to the substrate surface of the transfer film carrier. The systems and methods facilitate quick and accurate laser capture microdissection while simultaneously minimizing contamination.
대표청구항
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What is claimed is: 1. An apparatus, comprising: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier, said laser capture microdissection transfer film including at least one integrally
What is claimed is: 1. An apparatus, comprising: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier, said laser capture microdissection transfer film including at least one integrally formed structural feature that protrudes and provides a controllable spacing between said laser capture microdissection transfer film and a sample. 2. The apparatus of claim 1, wherein said laser capture microdissection transfer film includes a material, that upon exposure to sufficient electromagnetic energy, expands and projects itself away from said substrate surface. 3. The apparatus of claim 1, further comprising a scattering media in proximity to said laser capture microdissection transfer film. 4. The apparatus of claim 1, wherein said laser capture microdissection transfer film includes an absorptive substance. 5. The apparatus of claim 1, wherein said laser capture microdissection transfer film is hot vacuum baked onto said substrate surface. 6. The apparatus of claim 1, wherein said laser capture microdissection transfer film is bonded to said substrate surface with a refractive index matching transparent glue. 7. The apparatus of claim 1, wherein said transfer film carrier includes a negative draft such that a distal diameter defined by said surface of said transfer film carrier is greater than a proximal diameter defined by an inner perimeter of said transfer film carrier. 8. The apparatus of claim 7, wherein said transfer film carrier includes a girdle that is contiguous with said negative draft. 9. The apparatus of claim 7, wherein said transfer film carrier includes a chamfer that is contiguous with said substrate surface. 10. The apparatus of claim 1, wherein said laser capture microdissection transfer film has a thickness that is less than 500 microns. 11. The apparatus of claim 1, wherein said laser capture microdissection transfer film has a thickness that is held to within 20% of a given value. 12. The apparatus of claim 1, wherein said laser capture microdissection transfer film has a capture surface that is opposite said substrate surface, said capture surface having a flatness that is held within five microns. 13. The apparatus of claim 1, wherein said laser capture microdissection transfer film includes at least one pedestal that protrudes and defines a laser capture microdissection acquisition zone. 14. The apparatus of claim 1, wherein said laser capture microdissection transfer film includes a protruding feature that runs along at least three points of a perimeter of said laser capture microdissection transfer film. 15. A microcentrifuge tube cap, comprising: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier, said laser capture microdissection transfer film including at least one integrally formed structural feature that protrudes and provides a controllable spacing between said laser capture microdissection transfer film and a sample. 16. An integral portion of a biological reaction vessel, comprising: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier, wherein said laser capture microdissection transfer film includes at least one integrally formed structural feature that protrudes and provides a controllable spacing between said laser capture microdissection transfer film and a sample. 17. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film includes a material, that upon exposure to sufficient electromagnetic energy, expands and projects itself away from said substrate surface. 18. The integral portion of a biological reaction vessel according to claim 16, further comprising a scattering media in proximity to said laser capture microdissection transfer film. 19. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film includes an absorptive substance. 20. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film is hot vacuum baked onto said substrate surface. 21. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film is bonded to said substrate surface with a refractive index matching transparent glue. 22. The integral portion of a biological reaction vessel according to claims 16, wherein said transfer film carrier includes a negative draft such that a distal diameter defined by said surface of said transfer film carrier is greater than a proximal diameter defined by an inner perimeter of said transfer film carrier. 23. The integral portion of a biological reaction vessel according to claim 22, wherein said transfer film carrier includes a girdle that is contiguous with said negative draft. 24. The integral portion of a biological reaction vessel according to claim 22, wherein said transfer film carrier includes a chamfer that is contiguous with said substrate surface. 25. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film has a thickness that is less than 500 microns. 26. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film has a thickness that is held to within 20% of a given value. 27. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film has a surface opposite said substrate surface having a flatness that is held within five microns. 28. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film includes at least one pedestal that protrudes and defines a laser capture microdissection acquisition zone. 29. The integral portion of a biological reaction vessel according to claim 16, wherein said laser capture microdissection transfer film includes a protruding feature that runs along at least three points of a perimeter of said laser capture microdissection transfer film. 30. A microcentrifuge tube cap, comprising an integral portion of a biological reaction vessel including: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier, wherein said laser capture microdissection transfer film includes at least one integrally formed structural feature that protrudes and provides a controllable spacing between said laser capture microdissection transfer film and a sample. 31. A laser capture microdissection assembly comprising: a plate having a top surface; and at least one laser capture microdissection cap coupled to said top surface of said plate, wherein said at least one laser capture microdissection cap includes: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier, wherein said laser capture microdissection transfer film includes at least one integrally formed structural feature that protrudes and provides a controllable space in between said laser capture microdissection transfer film and a sample. 32. The laser capture microdissection assembly of claim 31, further comprising a release layer coated on said plate, said release layer being located between said plate and said laser capture microdissection transfer film of each of said at least one laser capture microdissection cap. 33. The laser capture microdissection assembly of claim 32, wherein said release layer includes at least one nonadhesive material selected from the group consisting of silicones and polytetrafluoroethylenes. 34. The laser capture microdissection assembly of claim 33, wherein said at least one nonadhesive material is a silicone containing surfactant agent. 35. The laser capture microdissection assembly of claim 31, wherein a plano-concave void is located between said laser capture microdissection transfer film of said at least one laser capture microdissection cap and said top surface of said plate. 36. The laser capture microdissection assembly of claim 31, wherein said laser capture microdissection transfer film includes a transparent thermoplastic. 37. The laser capture microdissection assembly of claim 31, wherein said laser capture microdissection transfer film includes an absorptive substance. 38. The laser capture microdissection assembly of claim 31, wherein said laser capture microdissection transfer film is hot vacuum baked onto said substrate surface. 39. The laser capture microdissection assembly of claim 31, wherein said transfer film carrier includes a negative draft such that a distal diameter defined by said surface of said transfer film carrier is greater than a proximal diameter defined by an inner perimeter of said transfer film carrier. 40. The laser capture microdissection assembly of claim 31, wherein said laser capture microdissection transfer film has a thickness that is less than 500 microns. 41. The laser capture microdissection assembly of claim 31, wherein said laser capture microdissection transfer film has a thickness that is held to within 20% of a given value. 42. The laser capture microdissection assembly of claim 31, wherein said laser capture microdissection transfer film has a surface opposite said substrate surface having a flatness that is held within five microns. 43. The laser capture microdissection assembly of claim 31, further comprising at least one diffuser coupled to said at least one transfer film carrier. 44. A set of microcentrifuge tube caps, comprising a laser capture microdissection assembly including: a plate having a top surface; and at least one laser capture microdissection cap coupled to said top surface of said plate, wherein said at least one laser capture microdissection cap includes: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier, wherein said laser capture microdissection transfer film includes at least one integrally formed structural feature that protrudes and provides a controllable space in between said laser capture microdissection transfer film and a sample. 45. An apparatus comprising: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier wherein said transfer film carrier is adapted to cap a vessel such that at least a portion of said transfer film is disposed inside said vessel. 46. The apparatus according to claim 45, wherein said laser capture microdissection transfer film includes a material, that upon exposure to sufficient electromagnetic energy, expands and projects itself away from said substrate surface. 47. The apparatus according to claim 45, further comprising a scattering media in proximity to said laser capture microdissection transfer film. 48. The apparatus according to claim 45, wherein said laser capture microdissection transfer film includes a base material and an absorptive substance. 49. The apparatus according to claim 45, wherein said laser capture microdissection transfer film is hot vacuum baked onto said substrate surface. 50. The apparatus according to claim 45, wherein said laser capture microdissection transfer film is bonded to said substrate surface with a refractive index matching transparent glue. 51. The apparatus according to claim 45, wherein said transfer film carrier includes a negative draft such that a distal diameter defined by said surface of said transfer film carrier is greater than a proximal diameter defined by an inner perimeter of said transfer film carrier. 52. The apparatus according to claim 51, wherein said transfer film carrier includes a girdle that is contiguous with said negative draft. 53. The apparatus according to claim 51, wherein said transfer film carrier includes a chamfer that is contiguous with said substrate surface. 54. The apparatus according to claim 45, wherein said laser capture microdissection transfer film has a thickness that is less than 500 microns. 55. The apparatus according to claim 45, wherein said laser capture microdissection transfer film has a thickness that is held to within 20% of a given value. 56. The apparatus according to claim 45, wherein said laser capture microdissection transfer film has a surface opposite said substrate surface having a flatness that is held within five microns. 57. The apparatus according to claim 45 further including a sealing feature that excludes a portion of said transfer film carrier from the interior of said vessel. 58. The apparatus according to claim 45 wherein said vessel includes an internal ridge adapted to contact a portion of said transfer film carrier. 59. The apparatus according to claim 58 wherein said transfer film carrier includes at least one stand-off; and the portion of the carrier contacted by said internal ridge of the vessel includes said at least one stand-off. 60. An apparatus comprising: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier wherein said transfer film carrier is adapted to be coupled to a vessel such that at least a portion of said transfer film is disposed inside said vessel; and wherein said laser capture microdissection transfer film includes at least one pedestal that protrudes and defines a laser capture microdissection acquisition zone. 61. An apparatus comprising: a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier wherein said transfer film carrier is adapted to be coupled to a vessel such that at least a portion of said transfer film is disposed inside said vessel; and wherein said laser capture microdissection transfer film includes a protruding feature that runs along at least three points of a perimeter of said laser capture microdissection transfer film. 62. An apparatus comprising: a transfer film carrier having a substrate surface, and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier wherein said transfer film carrier is adapted to cap a microcentrifuge tube such that at least a portion of said transfer film is disposed inside said microcentrifuge tube. 63. A laser capture microdissection assembly comprising: a plate having a top surface; and at least one laser capture microdissection cap coupled to said top surface of said plate, wherein said at least one laser capture microdissection cap includes a transfer film carrier having a substrate surface; and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier. 64. The laser capture microdissection assembly of claim 63, further comprising a release layer coated on said plate, said release layer being located between said plate and said laser capture microdissection transfer film of each of said at least one laser capture microdissection cap. 65. The laser capture microdissection assembly of claim 64, wherein said release layer includes at least one nonadhesive material selected from the group consisting of silicones and polytetrafluoroethylenes. 66. The laser capture microdissection assembly of claim 65, wherein said at least one nonadhesive material is a silicone containing surfactant agent. 67. The laser capture microdissection assembly of claim 63, wherein a plano-concave void is located between said laser capture microdissection transfer film of said at least one laser capture microdissection cap and said top surface of said plate. 68. The laser capture microdissection assembly of claim 63, wherein said laser capture microdissection transfer film includes a transparent thermoplastic. 69. The laser capture microdissection assembly of claim 63, wherein said laser capture microdissection transfer film includes an absorptive substance. 70. The laser capture microdissection assembly of claim 63, wherein said laser capture microdissection transfer film is hot vacuum baked onto said substrate surface. 71. The laser capture microdissection assembly of claim 63, wherein said transfer film carrier includes a negative draft such that a distal diameter defined by said surface of said transfer film carrier is greater than a proximal diameter defined by an inner perimeter of said transfer film carrier. 72. The laser capture microdissection assembly of claim 63, wherein said laser capture microdissection transfer film has a thickness that is less than 500 microns. 73. The laser capture microdissection assembly of claim 63, wherein said laser capture microdissection transfer film has a thickness that is held to within 20% of a given value. 74. The laser capture microdissection assembly of claim 63, wherein said laser capture microdissection transfer film has a surface opposite said substrate surface having a flatness that is held within five microns. 75. The laser capture microdissection assembly of claim 63, further comprising at least one diffuser coupled to said at least one transfer film carrier. 76. A set of microcentrifuge tube caps, comprising a laser capture microdissection assembly including: a plate having a top surface; and at least one laser capture microdissection cap coupled to said top surface of said plate, wherein said at least one laser capture microdissection cap includes a transfer film carrier having a substrate surface, and a laser capture microdissection transfer film coupled to said substrate surface of said transfer film carrier.
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