Abstract: Microfluidic systems having photodetectors disclosed therein and methods of producing the same are disclosed herein. According to an aspect, a microfluidic system includes a body including an interior wall that at least partially defines an interior space for receipt of fluid. Further, the microfluidic system includes a photodetector disposed on the interior wall and positioned to receive light from fluid in the interior space for generating an electrical signal representative of the received light.

Abstract: Microfluidic systems having photodetectors disclosed therein and methods of producing the same are disclosed herein. According to an aspect, a microfluidic system includes a body including an interior wall that at least partially defines an interior space for receipt of fluid. Further, the microfluidic system includes a photodetector disposed on the interior wall and positioned to receive light from fluid in the interior space for generating an electrical signal representative of the received light.

Abstract: The present disclosure provides systems, apparatus, and methods that include an electrowetting-on-dielectric microfluidic apparatus for effecting poration of cells in a droplet.

Abstract: Methods for sampling a liquid flow are provided. The method includes supplying a continuous liquid flow from a continuous flow fluid input source to a surface along a first flow path. The method additionally includes sampling the continuous liquid flow by performing an electric field-based technique to split off a sample droplet from a portion of the liquid flow, whereby the sample droplet is distinct from the liquid flow and controllable independently of the liquid flow, wherein the electric field-based technique is performed by providing a set of electrodes on the surface and selectively biasing the set of electrodes, whereby the sample droplet is formed on one of the set of electrodes.

Abstract: Methods for amplifying nucleic acid, such as DNA or RNA, on a printed circuit board (PCB) substrate are disclosed. The amplification can be achieved through a variety of methods such as thermocycling or isothermally. The printed circuit board substrate can comprise an array of electrodes for transporting droplets and can be part of a sandwich structure including a top plate parallel to the printed circuit board substrate.

Abstract: Apparatuses for mixing droplets, such as a binary mixing apparatus, are provided. The binary mixing apparatus includes an array of electrodes and a conducting element positioned in relation to at least one of the electrodes to enable a droplet placed in electrical communication with the at least one electrode to electrically communicate with the conducting element. The binary mixing apparatus additionally includes an electrode selector for sequentially biasing one or more selected electrodes of the array to move a droplet disposed on the array into contact with another droplet. The apparatus further includes a first droplet supply area communicating with the array and a second droplet supply area communicating with the array.

Abstract: Methods for performing microfluidic sampling are provided. The method includes providing a substrate including an arrangement of first, second and third electrodes, wherein the second electrode is interposed between the first and third electrodes. The method additionally includes causing a fluid input to continuously flow to the first electrode and biasing the first, second and third electrodes to a first voltage to cause a portion of the fluid input to spread across the second and third electrodes. The method further includes biasing the second electrode to a second voltage different from the first voltage to form a droplet on the third electrode, the droplet being separate from the fluid input.

Abstract: Apparatuses and methods for manipulating droplets on a printed circuit board (PCB) are disclosed. Droplets are actuated upon a printed circuit board substrate surface by the application of electrical potentials to electrodes defined on the PCB. The use of soldermask as an electrode insulator for droplet manipulation as well techniques for adapting other traditional PCB layers and materials for droplet-based microfluidics are also disclosed.

Abstract: Methods are provided for manipulating droplets. The methods include providing the droplet on a surface comprising an array of electrodes and a substantially co-planer array of reference elements, wherein the droplet is disposed on a first one of the electrodes, and the droplet at least partially overlaps a second one of the electrodes and an intervening one of the reference elements disposed between the first and second electrodes. The methods further include activating the first and second electrodes to spread at least a portion of the droplet across the second electrode and deactivating the first electrode to move the droplet from the first electrode to the second electrode.