Abstract: A heater for a microfluidic test card is disclosed herein. In a general example embodiment, a test card for analyzing a fluid sample includes at least one substrate layer including a microchannel extending through at least a portion of one of the substrate layers, and a printed substrate layer that is bonded to or printed on one substrate layer of the at least one substrate layer. The printed substrate layer includes a heater printed on the printed substrate layer so as to align with at least a portion of the microchannel. The heater includes two electrodes aligned on opposite sides of the microchannel, and a plurality of heater bars electrically connecting the two electrodes. The plurality of heater bars includes a central heater bar disposed between outer heater bars.

Abstract: Apparatuses and for causing a point-of-care polymerase chain reaction and analyzing the polymerase chain reaction at the point-of-care, particularly when unwanted bubbles are present during the polymerase chain reaction, are described herein. In a general embodiment, a device for analyzing a polymerase chain reaction in a fluid sample includes a current source configured to cause the polymerase chain reaction by heating the fluid sample within a target zone, a camera imaging device configured to record a plurality of images of the fluid sample in the target zone while the current source causes the polymerase chain reaction, and a controller configured to (i) distinguish wanted objects in the plurality of images from an unwanted object in the plurality of images, and (ii) determine whether the fluid sample tests positive or negative for a bacteria or virus based on the wanted objects.

Abstract: A disposable test card configured to accept a fluid sample for an assay, and a method of manufacturing same, is disclosed herein. In a general example embodiment, a test card for analyzing a fluid sample includes a first substrate layer including an inlet port and an outlet port, a channel layer bonded to the first substrate layer, the channel layer including a microchannel placing the inlet port in fluid communication with the outlet port, and a second substrate layer bonded to the channel layer, the second substrate layer having electrodes printed adjacent to a target zone of the microchannel of the channel layer, wherein the electrodes are configured to raise the temperature of the fluid sample within the target zone of the microchannel when a current is applied thereto.

Abstract: A microfluidic chip is disclosed herein. In an embodiment, the microfluidic chip includes a body including at least one microfluidic pathway configured to receive a fluid sample, the at least one microfluidic pathway including a coating configured to reduce fluid diffusion and seal a surface of the at least one microfluidic pathway, and a heating device located on the body and forming a heating zone within a portion of the at least one microfluidic pathway.

Abstract: A microfluidic chip for a microfluidic system includes a PDMS substrate having a first thickness, at least one microfluidic pathway in the substrate, a coating along the microfluidic pathway, and a glass layer having a second thickness on the substrate and above the microfluidic pathway, wherein the coating contains an optically transparent material, and the first thickness is greater than the second thickness. The coating includes cyanoacrylates, an UV curable epoxy adhesive, a gel epoxy or epoxy under trade name of EPO-TEK OG175, MasterBond EP30LV-1 or Locite 0151.

Abstract: A microfluidic chip for a microfluidic system includes a PDMS substrate having a first thickness, at least one microfluidic pathway in the substrate, a coating along the microfluidic pathway, and a glass layer having a second thickness on the substrate and above the microfluidic pathway, wherein the coating contains an optically transparent material, and the first thickness is greater than the second thickness. The coating includes cyanoacrylates, an UV curable epoxy adhesive, a gel epoxy or epoxy under trade name of EPO-TEK OG175, MasterBond EP30LV-1 or Locite 0151.

Abstract: A microfluidic chip includes a thin biaxially-oriented polyethylene terephthalate (“BoPET”) film and a micro-channel in the BoPET film. A method for manufacturing a microfluidic chip includes coating UV epoxy on a first side of a BoPET film, placing the BoPET film on a first substrate with the first side facing the first substrate, curing the UV epoxy on the first side of the BoPET film to attach the BoPET film on the first substrate; forming at least one microfluidic pathway in the BoPET film, coating UV epoxy on a first side of a second substrate, placing the second substrate on the BoPET film with the first side of the second substrate facing a second side of the BoPET film, and curing the UV epoxy on the first side of the second substrate to attach the BoPET film to the second substrate. The microfluidic chip may be a multi-layered chip.

Abstract: A microfluidic chip for a microfluidic system includes a micro-to-macro seal. The microfluidic chip has a substrate, at least one microfluidic pathway in the substrate, and a PDMS seal layer on the substrate and above the microfluidic pathway. The PDMS seal layer provides a seal above the microfluidic pathway and prevent particles or contaminants entering the micro-channel during transportation or prior to application. During application, a needle or piping pierces through the PDMS seal layer, and fluid can be pumped into the microfluidic chip without concern for the fluid leaking despite high pressure required to pump or drive the fluid into the microfluidic pathway.

Abstract: A microfluidic chip includes a thin biaxially-oriented polyethylene terephthalate (“BoPET”) film and a micro-channel in the BoPET film. A method for manufacturing a microfluidic chip includes coating UV epoxy on a first side of a BoPET film, placing the BoPET film on a first substrate with the first side facing the first substrate, curing the UV epoxy on the first side of the BoPET film to attach the BoPET film on the first substrate; forming at least one microfluidic pathway in the BoPET film, coating UV epoxy on a first side of a second substrate, placing the second substrate on the BoPET film with the first side of the second substrate facing a second side of the BoPET film, and curing the UV epoxy on the first side of the second substrate to attach the BoPET film to the second substrate. The microfluidic chip may be a multi-layered chip.

Abstract: A microfluidic chip for a microfluidic system includes a PDMS substrate having a first thickness, at least one microfluidic pathway in the substrate, a coating along the microfluidic pathway, and a glass layer having a second thickness on the substrate and above the microfluidic pathway, wherein the coating contains an optically transparent material, and the first thickness is greater than the second thickness. The coating includes cyanoacrylates, an UV curable epoxy adhesive, a gel epoxy or epoxy under trade name of EPO-TEK 0G175, MasterBond EP30LV-1 or Locite 0151.