Various implementations of electrophoretic systems and instruments are provided to improve electrophoresis and ease of use. Various electrophoretic systems and instruments utilize different electrode designs that can result in uniform electromigration of analytes. The electrophoretic systems and instrumentations optimize the size and/or location of electrodes relative to a sample, thereby increasing uniformity of electric field and reducing or minimizing drift of analyte migration. In addition, the electrophoresis systems and instruments provide a solution to conveniently check for electrical connections in the systems and instruments, and alert users of potential improper electrical connections, prior to performing electrophoresis.

A biosensor system includes an array of biosensors with a plurality of electrodes situated proximate the biosensor. A controller is configured to selectively energize the plurality of electrodes to generate a DEP force to selectively position a test sample relative to the array of biosensors.

The present disclosure relates, in some embodiments, to a system for measuring capillary electrophoresis current. The system includes a plurality of capillaries, where each capillary has a cathode end and an anode end. The system further includes a plurality of cathode buffers. Each of the cathode buffers is configured to be electrically isolated from the other cathode buffers. Further, each cathode buffer is associated with one capillary of the plurality of capillaries. The cathode end of each capillary is immersed in its associated cathode buffer. The system includes a plurality of current sensors, each current sensor associated with one capillary of the plurality of capillaries for measuring current. In some embodiments, the plurality of capillaries is four capillaries.

This invention is directed to an inexpensive, miniaturized, portable, low-power device and method for electrophoretic separation and electrochemical detection of an analyte, including different isotopes of the same element. The invention replaces a conventional or microfabricated capillary electrophoresis tube with a microchip comprising an array of parallel electrophoretic separation nanotubes or aligned hollow channels fabricated in a porous substrate.

A sample processing apparatus (102) includes a plurality of processing stations (108) configured to process a sample that includes a DNA sample and an ILS substance carried by a sample carrier. One of the plurality of processing stations includes an electrophoresis processing station. The sample processing apparatus further includes an optical reader (110) that generates a plurality of DNA sample color group signals and an ILS signal based on a result of the electrophoresis processing station. One of the DNA sample color group signals includes at least the locus amelogenin X-peak. The sample processing apparatus further includes an ILS signal validator (112) that validates peaks of the ILS signal as true peaks of the ILS signal only if the amelogenin X-peak of the one of the DNA sample color group signals is found between two peaks of the ILS signal.

Disclosed herein are devices, systems, and methods for sorting a particle based on a characteristic of a particle.

A method for enriching a heterogeneous population of cells includes loading one or more sample chambers containing DEP electrodes therein with a solution containing the heterogeneous population of cells, wherein the heterogeneous population of cells comprises a first subpopulation of cells having a first crossover frequency and a second subpopulation of cells having a second, higher crossover frequency. An AC electrical field is applied to the DEP electrodes, wherein the AC electrical field has an applied frequency that is between the crossover frequency of the first subpopulation of cells and the second subpopulation of cells, wherein the first subpopulation of cells are substantially killed by the applied electrical field and the second subpopulation of cells are substantially not killed by the applied electrical field.

An electrophoresis system includes an electrophoresis device including a measurement unit that measures a measurement target separated by electrophoresis, and a current detection unit that detects a current flowing through the flow path. Moreover, the electrophoresis system is configured to display each of a time-series value of a measurement value of the measurement target measured by the measurement unit and a time-series value of a current detection value of the current detected by the current detection unit on a display unit during measurement of the measurement target.

An apparatus for glycan analysis is disclosed. The apparatus includes a plurality of loading wells adapted to receive a plurality of samples; a plurality of capillaries arranged in correspondence with the loading wells, each of the capillaries including a first portion including a stacking gel and a second portion including a resolving gel; and a plurality of eluting wells arranged in correspondence with the capillaries and adapted to receive a portion of the samples having traversed the capillaries.

Devices and methods are provided for the separation and dispensing of material using a microfluidic electrophoresis column, sheath liquid pump, and exit channel, all on the same monolithic chip. Material is separated in the electrophoresis column and passed into the exit chamber in response to a voltage potential between a first electrode within the electrophoresis column and a terminating electrode integrated into the chip. The terminating electrode can be in the sheath liquid pump chamber, the sheath liquid reservoir, or a separate flow channel that intersects the exit channel along with the electrophoresis column and sheath liquid pump chamber. The flow of sheath liquid into the exit chamber entrains separated analytes into an effluent that is dispensed out of the exit chamber via a discharge outlet.