Abstract: 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.

Abstract: A biological analysis device (100) for performing capillary electrophoresis includes a voltage section (124) configured to generate a voltage differential across a cathode (106) connector and an anode (116) connector, an optical detector system (112) configured to detect light emission from a sample, a temperature regulation section (126), and a cartridge holding portion configured to receive at least a portion of a removable cartridge (102) comprising one or more capillaries (104) and a separation medium container (118). The biological analysis device may include one or more actuators (122) 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.

Abstract: A heating apparatus comprising a support base and a microplate having a first surface and an opposing second surface. The microplate is positioned adjacent the support base and comprises a plurality of wells formed in the first surface thereof. Each of the plurality of wells is sized to receive an assay therein. A sapphire crystalline transparent window is positioned adjacent the microplate opposing the support base. A heating device heats the transparent window in response to a control system.

Abstract: A heating apparatus comprising a support base and a microplate having a first surface and an opposing second surface. The microplate is positioned adjacent the support base and comprises a plurality of wells formed in the first surface thereof. Each of the plurality of wells is sized to receive an assay therein. A sapphire crystalline transparent window is positioned adjacent the microplate opposing the support base. A heating device heats the transparent window in response to a control system.

Abstract: Various embodiments of a low-volume sequencing system are provided herein. The system can include a low-volume flowcell having at least one reaction chamber of a defined volume (e.g., less than about 100 ?l). The system can also include an automated reagent delivery mechanism configured to reversibly couple with the inlet port corresponding to a target reaction chamber thereby placing allowing for reagent to be accurately moved from a storage container to the reaction chamber with minimal reagent waste. The flowcells can include a plurality of reaction chambers (e.g., 6) thereby allowing for parallel analysis of multiple samples. Various methods of analyzing a biomolecule are also provided herein.

Abstract: Various flowcell configurations and systems are provided as are methods of making and using same. The flowcells, systems, and methods of use can be useful in carrying out sequencing reactions and next generation sequencing methods.

Abstract: An apparatus for sealing a microplate, wherein the apparatus comprises a microplate having a first surface and an opposing second surface. A plurality of wells is formed in the first surface of the microplate, wherein each of the plurality of wells is sized to receive an assay therein. A sealing cover is disposed over the microplate adjacent the plurality of wells and is compliant to accommodate variations between the sealing cover and the microplate and/or distribute loads evenly therebetween.

Abstract: A heating apparatus comprising a support base and a microplate having a first surface and an opposing second surface. The microplate is positioned adjacent the support base and comprises a plurality of wells formed in the first surface thereof. Each of the plurality of wells is sized to receive an assay therein. A sapphire crystalline transparent window is positioned adjacent the microplate opposing the support base. A heating device heats the transparent window in response to a control system.