BIOMEDICAL CHIP FOR BLOOD COAGULATION TEST, METHOD OF PRODUCTION AND USE THEREOF
First Claim
1. A biomedical chip for blood coagulation tests, comprising:
- a substrate layer made of a hydrophilic material, a middle layer, and a cap layer made of a hydrophilic material, sequentially engaged and stacked from bottom to top with each other, wherein the substrate layer, the middle layer and the cap layer define a microfluidic channel formed at the cap layer, having a first inlet and an outlet at two opposite ends of the microfluidic channel respectively;
a second inlet being disposed proximate to the first inlet and interconnected to the microfluidic channel; and
a mixing interval expanded radially outward and interconnected to the second inlet and the externally expanded mixing interval having a diameter greater than the diameter of the second inlet, wherein an interconnect portion is disposed at the bottom of the second inlet; and
a capillary portion is disposed between the substrate layer and the cap layer, and interconnected to the interconnect portion and disposed around the periphery thereof, wherein the microfluidic channel'"'"'s internal diameter is small enough to produce a capillary force to drive blood in the first inlet and a reagent in the second inlet to flow along a lengthwise direction, such that the blood is driven automatically to pass through the capillary portion to absorb the reagent in the interconnect portion and flow towards the outlet.
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Accused Products
Abstract
In a biomedical chip for blood coagulation tests and its manufacturing method and use, the biomedical chip comprises a substrate layer, a middle layer, and a cap layer, engaged and stacked with each other to define a microfluidic channel which has a first inlet and an outlet of the microfluidic channel respectively. A mixing interval is expanded outward from the microfluidic channel and interconnected to a second inlet, and has an interconnect portion and a capillary portion disposed between the substrate layer and the cap layer, and more specifically disposed around the periphery of the interconnect portion. With the biomedical chip having the substrate layer and cap layer made of a hydrophilic material, the blood and the reagent can be driven automatically by the capillary force of the microfluidic channel to flow and mix with each other, and the hydrophilic capillary force can be permanently maintained.
40 Citations
13 Claims
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1. A biomedical chip for blood coagulation tests, comprising:
a substrate layer made of a hydrophilic material, a middle layer, and a cap layer made of a hydrophilic material, sequentially engaged and stacked from bottom to top with each other, wherein the substrate layer, the middle layer and the cap layer define a microfluidic channel formed at the cap layer, having a first inlet and an outlet at two opposite ends of the microfluidic channel respectively;
a second inlet being disposed proximate to the first inlet and interconnected to the microfluidic channel; and
a mixing interval expanded radially outward and interconnected to the second inlet and the externally expanded mixing interval having a diameter greater than the diameter of the second inlet, wherein an interconnect portion is disposed at the bottom of the second inlet; and
a capillary portion is disposed between the substrate layer and the cap layer, and interconnected to the interconnect portion and disposed around the periphery thereof, wherein the microfluidic channel'"'"'s internal diameter is small enough to produce a capillary force to drive blood in the first inlet and a reagent in the second inlet to flow along a lengthwise direction, such that the blood is driven automatically to pass through the capillary portion to absorb the reagent in the interconnect portion and flow towards the outlet.- View Dependent Claims (2, 3, 4, 5, 6, 7, 12, 13)
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8. A method of manufacturing a biomedical chip for blood coagulation tests, comprising the steps of:
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(a) attaching and fixing a middle layer onto the top of a hydrophilic substrate layer; (b) forming a slender penetrating microchannel at the middle layer, wherein the microchannel has an externally expanded section radially expanded outward; (c) forming a first inlet hole, a second inlet hole and a outlet hole with an interval apart from each other and passed through the top side of the hydrophilic cap layer by a laser manufacturing method, and the second inlet hole having a diameter smaller than the diameter of the externally expanded section; and (d) stacking and fixing the cap layer produced in Step (c) onto the top side of the middle layer to cover the microchannel, such that the cap layer, the substrate layer and the middle layer define an internal diameter of the microchannel which is small enough to produce a capillary force for driving the blood to flow in the microfluidic channel automatically, and the first filling hole and the discharging hole are interconnected to two opposite ends of the microfluidic channel respectively, and the second inlet hole and the externally expanded section are interconnected correspondingly. - View Dependent Claims (9, 10, 11)
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Specification