Embodiments described herein generally relate to cartridges suitable for performing electrophoretic separation of analytes. Cartridges described herein are particularly well suited for reuse. Cartridges described herein can include a reservoir disposed between a capillary and a container containing a run buffer. The reservoir can inhibit run buffer from intruding into the capillary, thereby allowing repeated electrophoretic separations to be more consistent, more accurate, and/or more reliable.

Described herein is a bias-free high-throughput and high-yield continuous isoelectric fractionation (CIF) nanocarrier fractionation technique based on distinct isoelectric points. The nanocarrier fractionation platform is enabled by a robust and tunable linear pH profile provided by water-splitting at a bipolar membrane and stabilized by flow without ampholytes.

A system for performing capillary electrophoresis of multiple samples comprises a capillary containing a separation medium and having inlet and distal ends and an interrogation region; a power source configured to apply voltages between inlet and distal ends; and logic to cause execution of: applying a first substantially constant forward polarity electrophoresis voltage to the capillary; before all of the first DNA fragments have passed the interrogation region, applying a reverse polarity voltage pulse to the capillary, thereby transporting at least some of the first DNA fragments in the capillary toward the capillary inlet; introducing a second sample to the capillary inlet, the second sample comprising second DNA fragments having a plurality of different sizes; and applying a second substantially constant forward polarity electrophoresis voltage to the capillary to simultaneously perform electrophoresis on the second DNA fragments and the first DNA fragments.

The invention is an improved multiplex capillary electrophoresis instrument or module with at least four and preferably six user-accessible vertically stacked drawers. An x-z stage moves samples from the user accessible drawers to the capillary array for analysis. An additional mechanical stage moves the array from side-to-side. The x-z stage, coupled with the additional array stage allows the system to sample all wells of a 384 well plate with a 96-capillary array. A computer program allows users to add capillary electrophoresis jobs to a queue corresponding to the analysis of rows or plates of samples without stopping or interrupting runs in progress.

A system and method for capturing and analyzing a set of cells, comprising: an array including a set of parallel pores, each pore including a chamber including a chamber inlet and a chamber outlet, and configured to hold a single cell, and a pore channel fluidly connected to the chamber outlet; an inlet channel fluidly connected to each chamber inlet of the set of parallel pores; an outlet channel fluidly connected to each pore channel of the set of parallel pores; a set of electrophoresis channels fluidly coupled to the outlet channel, configured to receive a sieving matrix for electrophoretic separation; and a set of electrodes including a first electrode and a second electrode, wherein the set of electrodes is configured to provide an electric field that facilitates electrophoretic analysis of the set of cells.

A biological analysis device for performing capillary electrophoresis includes a voltage section configured to generate a voltage differential across a cathode connector and an anode connector, an optical detector system configured to detect light emission from a sample, a temperature regulation section, and a cartridge holding portion configured to receive at least a portion of a removable cartridge comprising one or more capillaries and a separation medium container. The biological analysis device may include one or more actuators configured to actuate components of the removable cartridge when the removable cartridge is received in the cartridge holding portion. Devices and methods relate to biological analysis.

A system for assaying a biological sample for a presence of a target analyte includes an assaying device and a computer controller. The assaying device includes a housing, a receptacle disposed in the housing, and a source of activation energy. The receptacle is configured to accept an electrophoresis cell. The electrophoresis cell has a recess area configured to accept a chip configured to accept the biological sample. The chip includes a polymeric separation medium with activatable functional groups that covalently bond to the target analyte when activated. The source of activation energy is configured to supply activation energy to activate the activatable functional groups. The computer controller is operably coupled to the source of activation energy and is configured to activate the source of activation energy to direct an application of activation energy to the polymeric separation medium to activate the activatable functional groups.

A method for recovering a biological substance and a device for recovering a biological substance capable of improving a recovery rate of a target biological substance with a simple configuration are provided. The method for recovering a biological substance uses an electrophoresis device having a gel 13 and recovery holes 11 and 111. The method for recovering a biological substance includes a step of starting application of a voltage for moving a target biological substance toward the recovery hole, after that, a step of removing buffer solution in the recovery hole before the target biological substance reaches the recovery hole, after that, a step of injecting a solvent into the recovery hole, and, after that, a step of recovering the target biological substance that reaches the recovery hole.

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.

A capillary electrophoresis system includes a capillary reservoir. The capillary reservoir includes a capillary tip flow chamber configured to receive respective capillary tips and to conduct fluid past the capillary tips, and an electrode flow chamber in which an electrode is disposed and configured to conduct fluid past the electrode, the electrode flow chamber being separate from and in fluid communication with the capillary tip flow chamber. An ultraviolet (UV) light absorbance-based multiplexed capillary electrophoresis system includes a first enclosure and a second enclosure. The first enclosure covers a UV light source, and includes a slit. The second enclosure covers the first enclosure, a collimating lens, and a capillary window.