A gel for protein electrophoresis includes a separating gel and a stacking gel disposed on the separating gel. The separating gel is a polyacrylamide gel including a surfactant, and is alkaline. The surfactant of the separating gel includes 0.025-0.1% (m/v) of sodium lauroyl sarcosinate. The ratio of the molar concentration of the surfactant to the mass concentration of a loading protein is between 0.04 mmol/g and 11.56 mmol/g.

A separation unit is a configuration that is arranged vertically, and thus bubbles generating from the electrode will not negatively influence the contact location between the transfer membrane and separation unit. An anode (32) is arranged at a position separated by a certain distance in the conveying direction (X) of the transfer membrane (1) from the dispensing part (50a) of an electrophoresis gel chip (50). An insulating electrode cover (35) for setting free bubbles generating from the anode (32) is arranged at an upper part of the anode (32).

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.

Provided are devices that include a polymeric separation medium configured to immobilize one or more constituents of interest in the polymeric separation medium and have an increased pore size upon application of an applied stimulus. Systems including the devices, as well as methods of using the devices, are also provided. Embodiments of the present disclosure find use in a variety of different applications, including detecting whether an analyte is present in a fluid sample.

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.

Devices, systems, and methods of using them are disclosed that position an end of a capillary electrophoresis tube within an internal tapered nozzle region of an inkjet print head or other microfluidic pump. The capillary electrophoresis tube can extend through an inlet of the microfluidic pump and leave space for a sheath liquid to enter the pump and mix with separated analytes eluted from the capillary electrophoresis tube. The small volume of mixed sheath liquid and analyte can then be jetted through the nozzle at a moving surface, either continuously or as discrete droplets. Relative positions on the surface can indicate separation distances of dispensed analytes.

A kit is disclosed for distinguishing between bacterial and viral infections. One of the antibodies of the kit specifically binds to TNF-related apoptosis-inducing ligand (TRAIL) protein and another of the antibodies of the kit specifically binds to Procalcitonin (PCT) protein.

The disclosure provides methods of diagnosing, prognosing and stratifying cancers in a patient, comprising detecting elevated expression of desmoglein-2 (DSG-2) in a sample of the cancer and referencing that level to historic data to determine treatment regimen, stage, and prognosis of a patient.

A protein transfer system includes at least one base configured to receive one or more consumable protein transfer stacks and at least one lid configured to cover the base. The lid(s) comprise(s) one or more electrodes for supplying current to the one or more consumable protein transfer stacks. The protein transfer system further includes at least one voltage source configured to supply the current to the one or more consumable protein transfer stacks, one or more processors, and one or more hardware storage devices storing instructions that are executable by the one or more processors to configure the protein transfer system to control operation of the one or more voltage sources.

An electrophoretic separation device includes an anode and a cathode, a porous scaffold material, and a liquid separation medium, wherein the separation medium is located inside the porous scaffold material, is in contact with the cathode and the anode, and has been applied to the porous scaffold material in form of a custom-made geometrical shape defining a migration path for a biomolecule-containing sample, wherein the sample is enclosed by the separation medium. A method for electrophoretic separation of biomolecules includes the electrophoretic separation device, a biomolecule-containing sample, wherein the sample is applied to the porous scaffold material prior to the application of the separation medium, or the sample is applied to the separation medium located inside the porous scaffold material, resulting in enclosure of the sample by the separation medium, and applying a voltage to the separation medium by means of the anode and the cathode leading to the migration of the biomolecules inside the separation medium.