IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0750348
(2000-12-29)
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발명자
/ 주소 |
- Shvets, Igor
- Kashanin, Dmitriy
- Kelleher, Dermot
- Williams, Vivienne
- Volkov, Yuri
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출원인 / 주소 |
- The Provost, Fellows and Scholars of the College of the Holy & Undivided Trinity of Queen Elizabeth Near Dublin
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대리인 / 주소 |
Birch, Stewart, Kolasch & Birch, LLP
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인용정보 |
피인용 횟수 :
20 인용 특허 :
25 |
초록
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Biological assays using various constructions of biochips are disclosed to mirror in vivo situations. The biochip 50 comprises a microchannel 51 having a liquid outlet port 1 , bubble release port 2 and a liquid outlet port 3 with an associated bubble release port 4 . A multiplicity of tests can be
Biological assays using various constructions of biochips are disclosed to mirror in vivo situations. The biochip 50 comprises a microchannel 51 having a liquid outlet port 1 , bubble release port 2 and a liquid outlet port 3 with an associated bubble release port 4 . A multiplicity of tests can be performed often by coating the bore of the microchannel 50 which various adhesion mediating proteins or the use of chemoattractants. The assay assembly 60 comprises a syringe pump feeding the biochip 50 . An inverted microscope 65 , digital camera 66 and recorder 67 are provided. A sample liquid containing cells in suspension is injected slowly through the biochip and the effect of the assay recorded over a long period.
대표청구항
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1. A biological assay method for measuring cell flow, rolling, binding, tethering, migration of previously adhered cells, and/or adhesion comprising:preparing a sample liquid of a suspension of animal cells;coating the internal bore of a biochip with a protein, the biochip comprising an elongate enc
1. A biological assay method for measuring cell flow, rolling, binding, tethering, migration of previously adhered cells, and/or adhesion comprising:preparing a sample liquid of a suspension of animal cells;coating the internal bore of a biochip with a protein, the biochip comprising an elongate enclosed microchannel having a bore substantially the same size as post capillary venules of the animal;delivering the sample liquid at a controlled steady flow rate through the microchannel; andmeasuring cell flow, rolling, binding, tethering, migration of previously adhered cells, and/or adhesion. 2. The biological assay method according to claim 1, further comprising coating the internal bore of the biochip with a protein in the form of an extracellular matrix ligand. 3. The biological assay method according to claim 1, further comprising:coating the internal bore of the biochip by seeding the biochip with endothelial cells; andallowing the cells to grow and form an endothelial layer on the bore. 4. The biological assay method according to claim 1, wherein the cells are taken from an animal and the bore of the biochip is substantially the same size as the post capillary venules of the animal. 5. The biological assay method according to claim 1, comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel. 6. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel, the fluid pressure of the liquids being so chosen as to cause a diffusion of the reagent through the interconnecting channel and into the sample liquid. 7. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel, and the fluid pressures of the liquids are maintained equal to prevent diffusion of the reagent through the interconnecting channel. 8. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat. 9. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat, the fluid pressure of the liquids being so chosen as to cause a diffusion of the reagent through the interconnecting channel and into the sample liquid. 10. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat and the fluid pressures of the liquids are maintained equal to prevent diffusion of the reagent through the interconnecting channel. 11. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat having a cross-section less than that of a cell freely suspended in the sample liquid. 12. The biological assay meth od according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat having a cross-section less than that of a cell freely suspended in the sample liquid, the fluid pressure of the liquids being so chosen as to cause a diffusion of the reagent through the interconnecting channel and into the sample liquid. 13. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat having a cross-section less than that of a cell freely suspended in the sample liquid and the fluid pressures of the liquids are maintained equal to prevent diffusion of the reagent through the interconnecting channel. 14. The biological assay method according to claim 1, further comprising coating the bore of the microchannel with a hydrophobic coating and delivering a reagent liquid through the microchannel with the sample liquid. 15. The biological assay method according to claim 1, further comprising coating the bore of the microchannel with a liquid silicone and delivering a reagent liquid through the microchannel with the sample liquid. 16. The biological assay method according to claim 1, wherein the sample liquid contains more than one cell type in suspension. 17. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat having a cross-section less than that of a cell freely suspended in the sample liquid. 18. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat having a cross-section less than that of a cell freely suspended in the sample liquid, the fluid pressure of the liquids being so chosen as to cause a diffusion of the reagent through the interconnecting channel and into the sample liquid. 19. The biological assay method according to claim 1, further comprising delivering a reagent liquid at a controlled steady flow rate through another microchannel connected to the other microchannel, the channels being connected intermediate their ends by an interconnecting channel having a restricted entry throat having a cross-section less than that of a cell freely suspended in the sample liquid and the fluid pressures of the liquids are maintained equal to prevent diffusion of the reagent through the interconnecting channel. 20. The biological assay method according to claim 1, further comprising coating the bore of the microchannel with a hydrophobic coating and delivering a reagent liquid through the microchannel with the sample liquid. 21. The biological assay method according to claim 1, further comprising coating the bore of the microchannel with a liquid silicone and delivering a reagent liquid through the microchannel with the sample liquid. 22. The biological assay method according to claim 1, wherein the sample liquid contains more than one cell type in suspension. 23. The biological assay method according to claim 1, further comprising delivering a reagent liquid and the sample liquid through the microchannel to form multilaminar flow. 24. The biological assay method according to claim 1, further comprising:delivering a reagent liquid and a sample through a microchannel to form mult ilaminar flow, the sample liquid comprising more than once cell type in suspension and the reagent liquid comprising a chemoattractant suitable for one of the types of cell;allowing the flow to continue sufficiently so as to remove that cell type into the reagent liquid; and separating the reagent liquid and the sample liquid. 25. The biological assay method according to claim 1, wherein the biochip comprises two microchannels, one a feeding microchannel having a cell reservoir intermediate its ends and the other a reactant microchannel connected to the reservoir by a connecting means comprising:storing cells in the cell reservoir;feeding and growing the cells in the cell reservoir by delivering a culture medium through the feeding microchannel; anddelivering liquid through the reactant microchannel. 26. The biological assay method according to claim 1, wherein the biochip comprises two microchannels, one a feeding microchannel having a cell reservoir intermediate its ends and the other a reactant microchannel connected to the reservoir by a connecting means comprising:storing cells in the cell reservoir;feeding and growing the cells in the cell reservoir by delivering a culture medium through the feeding microchannel; anddelivering a reagent chosen from one or more of a chemoattractant toxic substance and pharmaceutical preparation recombinant or cell derived through the reactant microchannel. 27. The biological assay method according to claim 1, wherein a plurality of tests are carried out simultaneously using a sample liquid forming portion of a larger sample and using different test conditions. 28. The biological assay method according to claim 1, wherein a plurality of tests are carried out simultaneously using different sample liquids and the same test conditions. 29. A transmigration assay method to determine cell migration from the endothelium to the extracellular matrix comprising:delivering a sample liquid comprising a suspension of cells at a controlled steady flow rate through a microchannel forming a biochip with an internal bore;delivering a chemoattractant through another microchannel forming the biochip and being connected to the other microchannel through a restricted entry of size less than that of a freely suspended cell; andobserving the migration of cells through the restricted entry to the chemoattractant. 30. The transmigration method according to claim 29, further comprising coating the internal bore of the biochip with a protein. 31. The transmigration method according to claim 29, further comprising coating the internal bore of the biochip with a protein in the form of an extracellular matrix ligand. 32. The transmigration method according to claim 29, further comprising:coating the internal bore of the biochip by seeding the biochip with an endothelial cells; andallowing the cells to grow and form an endothelial layer on the bore. 33. The transmigration method according to claim 29, wherein the fluid pressure of the liquids is so chosen as to provide a diffusion of the sample liquid through the restricted entry. 34. The transmigration method according to claim 29, wherein the fluid pressures of the liquids are the same. 35. The transmigration method according to claim 29, wherein a plurality of tests are carried out simultaneously using a sample liquid forming portion of a larger sample and using different test conditions. 36. A method of separating a cell type from a sample liquid containing at least another cell type comprising:delivering a chemoattractant and the sample liquid through a microchannel forming part of a biochip, the liquids forming multilaminar flow and the chemoattractant having an affinity to the cell type allowing the flow to continue sufficiently so as to remove that cell type into the chemoattractant; andsubsequently separating the chemoattractant liquid and the sample liquid. 37. A method of separating a cell type from a sample liquid containing at least another cell type compr ising:delivering a chemoattractant and the sample liquid through a microchannel forming part of a biochip, the liquids forming multilaminar flow and the chemoattractant having an affinity to the cell type allowing the flow to continue sufficiently so as to remove that cell type into the chemoattractant; andsubsequently separating the chemoattractant liquid and the sample liquid. 38. The method according to claim 37, wherein a plurality of tests are carried out simultaneously using a sample liquid forming portion of a larger sample and using different test conditions. 39. The method according to claim 37, wherein a plurality of tests are carried out simultaneously using different sample liquids and the same test conditions.
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