One aspect of the invention provides container for thermal cycling a plurality of samples in a microfluidic array. The container includes a plurality of walls defining an interior volume and a conductive member for heating the interior volume. Another aspect of the invention provides container for thermal cycling a plurality of samples in a microfluidic array. The container includes a plurality of walls defining an interior volume and a plurality of conductive members for heating an interior volume. Another aspect of the invention provides a container for thermal cycling a plurality of samples in a microfluidic array. The container includes a plurality of walls defining an interior volume and a first conductive member located in the interior volume and adapted to contact a first end of the microfluidic array.

A microfluidic system for separating biological entities includes a cooling device including a thermoelectric heat pump, a first fan, and a first heat exchanger disposed between the first fan and the thermoelectric heat pump; a first housing structure having a first shell that encases the first fan and the first heat exchanger; a microfluidic device and one or more piezoelectric transducers attached thereto; and a second housing structure reversibly attached to the first housing structure and having a second shell that encloses therein the microfluidic device and the one or more piezoelectric transducers. When the first and second housing structures are coupled, a first air passage is formed between a side of the first heat exchanger and an end of the microfluidic device, a second air passage is formed between the first fan and the piezoelectric transducers, thereby allowing air to circulate between the first and second air passages.

A reaction container 10 of the PCR device 1 has a tubular ring channel 20 formed by a substrate 11, a channel forming plate 12, and a cover plate 13. The ring channel 20 comprises an electrode pair 21 disposed, in a diametrical direction of an inner surface of one side wall of the ring channel 20, to face each other with a horizontal gap interposed therebetween, and is vertically erected. The gap length of the electrode pair 21 is across the entire width within a cross-section of the ring channel 20.

At least one exemplary embodiment of the invention is directed to a molecular diagnostic device that comprises a cartridge configured to eject samples comprising genomic material into a microfluidic chip that comprises an amplification area, a detection area, and a matrix analysis area.

The present invention provides novel methods and devices that employ microfluidic technology to generate molecular melt curves. In particular, the devices and methods in accordance with the invention are useful in providing for the analysis of PCR amplification products.

Provided is an electrowetting-on-dielectric (EWOD) device. The EWOD device comprises a first substrate and a second substrate opposite to the first substrate. The first substrate comprises a plurality of first electrodes configured to be respectively controllably connected to signal lines. The first hydrophobic layer disposed over the plurality of first electrodes. The second substrate comprises a second electrode configured to be connected to the signal lines. The second hydrophobic layer disposed over the second electrode. An internal space between the first substrate and the second substrate is provided for receiving a droplet and a surrounding medium. The droplet is surrounded by the surrounding medium.

There is provided a nucleic acid analysis apparatus including a heating unit configured to apply heat by contacting a microchip, and a chip holding unit configured to change a position between a first holding position that holds the microchip in midair and a second holding position that holds the microchip in contact with the heating unit.

A micropump that pumps liquid using electrothermally-induced flow is described, along with a corresponding self-regulating pump and infusion pump. The micropump has applications in microfluidic systems, such as biochips. The self-regulating infusion pump is useful for administration of large and small volumes of liquids such as drugs to patients and can be designed for a wide range of flow rates by combining multiple micropumps in one infusion pump system. The micropump uses electrode sequences on opposing surfaces of a flow chamber that are staggered with respect to each other. The opposing surfaces include staggered electrodes that have the same phase and same electrode sequence. As such electrodes with the same phase are staggered and not eclipsed.

The present invention provides for microelectrode array devices and method of making and using same for the purpose of isolating and analyzing micro- and nanoparticles contained within a fluid solution. In various aspects, the present invention is designed to take advantage of electrokinetics and the separation of certain forces in order to influence and control small particles in a fluid solution, thereby allowing further analysis to be conducted on such particles.

A microfluidic system for separating biological entities comprises a cooling device including a thermoelectric heat pump, a first fan, and a first heat exchanger disposed between the first fan and the thermoelectric heat pump; a first housing structure having a first shell that encases the first fan and the first heat exchanger; a microfluidic device and one or more piezoelectric transducers attached thereto; and a second housing structure reversibly attached to the first housing structure and having a second shell that encloses therein the microfluidic device and the one or more piezoelectric transducers. When the first and second housing structures are coupled, a first air passage is formed between a side of the first heat exchanger and an end of the microfluidic device, a second air passage is formed between the first fan and the piezoelectric transducers, thereby allowing air to circulate between the first and second air passages.