Systems for operating electrokinetic devices

1 . A system for operating an electrokinetic device, said system comprising: a support configured to hold and operatively couple with an electrokinetic device, wherein said support comprises a socket configured to receive and interface with said electrokinetic device, and an electrical signal generation subsystem configured to apply a biasing voltage across a pair of electrodes in said electrokinetic device when said electrokinetic device is held by, and operatively coupled with, said support; and a light modulating subsystem configured to emit structured light onto said electrokinetic device when said electrokinetic device is held by, and operatively coupled with, said support. 2 . (canceled) 3 . The system of claim 1 , wherein said electrical signal generation subsystem comprises a waveform generator configured to generate a biasing voltage waveform to be applied across said electrode pair when said electrokinetic device is held by, and operatively coupled with, said support. 4 . The system of claim 3 , wherein said electrical signal generation subsystem further comprises a waveform amplification circuit configured to amplify the biasing waveform generated by said waveform generator, and an oscilloscope configured to measure the biasing voltage waveform, wherein data from said measurement is provided as feedback to said waveform generator. 5 . (canceled) 6 . The system of claim 1 , further comprising a thermal control subsystem configured to regulate a temperature of said electrokinetic device when said electrokinetic device is held by, and operatively coupled with, said support. 7 . The system of claim 6 , said thermal control subsystem comprising a thermoelectric power module, a Peltier thermoelectric device, and a cooling unit, wherein said thermoelectric power module is configured to regulate a temperature of said Peltier thermoelectric device, and wherein said Peltier thermoelectric device is interposed between a surface of said electrokinetic device and a surface of said cooling unit. 8 . (canceled) 9 . The system of claim 7 , wherein said Peltier thermoelectric device and said thermoelectric power module are mounted on and/or integrated with said support. 10 . The system of claim 6 , wherein said support further comprises a microprocessor that controls one or both of said electrical signal generation subsystem and said thermal control subsystem. 11 . The system of claim 10 , wherein said support comprises a printed circuit board (PCB), and wherein at least one of said electrical signal generation subsystem, said thermoelectric power module, and said microprocessor are mounted on and/or integrated with said PCB. 12 . The system of claim 10 , further comprising an external computational device operatively coupled with said microprocessor, wherein said external computational device comprises a graphical user interface configured to receive operator input and for processing and transmitting said operator input to said microprocessor for controlling one or both of said electrical signal generation subsystem and said thermal control subsystem. 13 . The system of claim 12 , wherein the microprocessor is configured to transmit to said external computational device data and/or information sensed or received, or otherwise calculated based upon data or information sensed or received, from one or both of said electrical signal generation subsystem and said thermal control subsystem. 14 . The system of claim 12 , wherein said microprocessor and/or said external computational device are configured to measure and/or monitor an impedance of an electrical circuit across said electrodes of said electrokinetic device when said electrokinetic device is held by, and operatively coupled with, said support. 15 . The system of claim 14 , wherein said microprocessor and/or said external computational device are configured to determine a flow volume of a fluid path based upon a detected change in the measured and/or monitored impedance of said electrical circuit, said fluid path comprising at least part of a microfluidic circuit within said electrokinetic device. 16 . The system of claim 14 , wherein said microprocessor and/or said external computational device are configured to determine a height of an interior microfluidic chamber of said electrokinetic device based upon a detected change in the measured and/or monitored impedance of said electrical circuit. 17 . The system of claim 14 , wherein said microprocessor and/or said external computational device are configured to determine one or more characteristics of chemical and/or biological material contained within the microfluidic circuit of said electrokinetic device based upon a detected change in the measured and/or monitored impedance of said electrical circuit. 18 . The system of claim 1 , wherein said support and said light modulating subsystem are configured to be mounted on a light microscope. 19 . The system of claim 1 , wherein said support and said light modulating subsystem are integral components of a light microscope. 20 . The system of claim 1 , wherein said electrokinetic device is an optically actuated electrokinetic device. 21 . The system of claim 1 , further comprising a first fluid line having a distal end configured to be fluidically coupled to an inlet port of said optically actuated electrokinetic device, and a second fluid line having a proximal end configured to be fluidically coupled to an outlet port of said optically actuated electrokinetic device, respectively, when said electrokinetic device is held by, and operatively coupled with, said support. 22 . The system of claim 21 , further comprising at least one flow controller operatively coupled with one or both of said first and second fluid lines. 23 . The system of claim 22 , wherein said at least one flow controller comprises a first thermally-controlled flow controller operatively coupled with one of said first fluid line and said second fluid line to selectively allow fluid to flow therethrough. 24 . The system of claim 23 , wherein said first thermally-controlled flow controller comprises a first thermally conductive interface thermally coupled with a flow segment of the first fluid line, and at least one flow control Peltier thermoelectric device configured to controllably lower or raise a temperature of the first thermally conductive interface sufficiently to controllably freeze or thaw fluid contained in the flow segment of the first fluid line and thereby selectively prevent or allow fluid to flow through into or out of the inlet port of said electrokinetic device through the first fluid line. 25 . The system of claim 24 , wherein said first thermally-controlled flow controller further comprises: a first housing having a first passageway through which the flow segment of the first fluid line extends, said housing further containing said first thermally conductive interface and the at least one flow control Peltier thermoelectric device; and/or an insulating material at least partially surrounding the flow segment of the first fluid line proximate the first thermally conductive interface. 26 . The system of claim 23 , wherein said at least one flow controller comprises a second thermally-controlled flow controller operatively coupled with the other one of said first fluid line and said second fluid line to selectively allow fluid to flow therethrough.