Devices, methods, and systems for visualizing electrowetting pathing using electrophoretic materials

1 . A visualization device, comprising in order as viewed from above: a light transmissive electrode layer; an electrophoretic medium comprising charged particles that translate in response to an applied electric field, an applied magnetic field, or a change in temperature; an adhesive layer; a hydrophobic layer; a dielectric layer; and a substrate comprising a plurality of propulsion electrodes coupled to a set of thin-film-transistors, the propulsion electrodes being disposed on a side of the substrate toward the dielectric layer. 2 . The visualization device of claim 1 , additionally including a controller operatively coupled to the set of thin-film-transistors and configured to provide propulsion voltages to the thin-film transistors. 3 . The visualization device of claim 1 , wherein the hydrophobic layer and the dielectric layer are the same layer. 4 . The visualization device of claim 1 , wherein the electrophoretic medium is compartmentalized in microcapsules held in a binder layer or compartmentalized in microcells sealed with a sealing layer. 5 . The visualization device of claim 1 , wherein the electrophoretic medium comprises two types of charged particles that have different optical properties and opposite electrical charges. 6 . The visualization device of claim 5 , wherein one of the types of charged particles is ferromagnetic. 7 . The visualization device of claim 6 , wherein the ferromagnetic particles are black. 8 . The visualization device of claim 1 , wherein the charged particles are black in color. 9 . A visualization cartridge including a visualization device of claim 1 and having a connector to allow the visualization cartridge to be connected to a digital microfluidic processing unit configured to drive an active matrix electrowetting on dielectric digital microfluidic (AM-EWOD-DMF) device. 10 . A system for visualizing digital microfluidic pathing, comprising: a digital microfluidic processing unit, including a processor and memory, and configured to provide instructions to an active matrix of propulsion electrodes to cause one or more aqueous droplets in a hydrophobic medium to move across the matrix of propulsion electrodes by changing the voltage provided to the respective propulsion electrodes as a function of time; a visualization device comprising a light-transmissive electrode, an electrophoretic medium, and an active matrix of propulsion electrodes controlled by thin-film-transistors, the visualization device being coupled to the digital microfluidic processing unit and configured to receive the instructions; and a camera to observe changes in the visualization device when the instructions are delivered from the digital microfluidic processing unit to the visualization device. 11 . The system of claim 10 , wherein the electrophoretic medium includes two types of electrically-charged particles having different optical states and opposite electric polarities. 12 . The system of claim 11 , wherein one of the types of electrically-charged particles is ferromagnetic. 13 . The system of claim 12 , further comprising a magnetic actuator, wherein the magnetic actuator is also operatively connected to the digital microfluidic processing unit. 14 . The system of claim 10 , further comprising a heating element, wherein the heating element is also operatively connected to the digital microfluidic processing unit. 15 . The system of claim 10 , wherein the visualization device comprises a dielectric layer between the electrophoretic medium and the active matrix of propulsion electrodes controlled by thin-film-transistors. 16 . The system of claim 10 , wherein the visualization device comprises a hydrophobic layer between the electrophoretic medium and the active matrix of propulsion electrodes controlled by thin-film-transistors. 17 . A method for visualizing programmed pathing or magnetic actuation in a digital microfluidic device including an array of propulsion electrodes controlled by thin-film-transistors, the method comprising: providing a digital microfluidic processing unit, including a processor and memory, and configured to provide instructions to an active matrix of propulsion electrodes to cause one or more aqueous droplets in a hydrophobic medium to move across the matrix of propulsion electrodes by changing the voltage provided to the respective propulsion electrodes as a function of time; providing a visualization device comprising a light-transmissive electrode, an electrophoretic medium, and an active matrix of propulsion electrodes controlled by thin-film-transistors; coupling the visualization device to the digital microfluidic processing unit; executing instructions for an active matrix of propulsion electrodes to cause one or more aqueous droplets in a hydrophobic medium to move across the matrix of propulsion electrodes by changing the voltage provided to the respective propulsion electrodes as a function of time; and visualizing a change in the visualization device. 18 . The method of claim 17 , wherein visualizing comprises observing optical changes in the electrophoretic medium. 19 . The method of claim 18 , wherein the electrophoretic medium includes two types of electrically-charged particles having different optical states and opposite electric polarities. 20 . The method of claim 19 , wherein one of the types of electrically-charged particles is ferromagnetic. 21 . The method of claim 20 , further comprising providing a magnetic actuator, wherein the magnetic actuator is also operatively connected to the digital microfluidic processing unit, and executing instructions for the magnetic actuator to move more proximate or less proximate to the visualization device. 22 . The method of claim 17 , further comprising providing a heating element, wherein the heating element is also operatively connected to the digital microfluidic processing unit, and executing instructions for the heating element to provide thermal energy to the visualization device. 23 . The method of claim 17 , further comprising providing a detector and aligning the detector to one or more propulsion electrodes.