The present invention addresses the problem of providing an electrophoretic medium container capable of stabilizing a liquid delivery pressure while ensuring sealing of an electrophoretic medium. In order to resolve this problem, this electrophoretic medium container is provided with a syringe part for holding an electrophoretic medium, and a sealing component for sealing one end of the syringe part, the electrophoretic medium container being characterized in that the sealing component has a sealing surface, a body part, and a groove provided between the sealing surface and the body part, wherein the sealing surface is in contact with the inner wall of the syringe part.

A method of treating a biological sample, preferably a sample of blood or bodily fluids likely to contain one or more species of interest, and including a step of decomplexification by acoustophoresis (as well as associated systems, devices, substrates and connection devices).

Structures for improved electrophoretic precast gel substrates are disclosed herein. In some embodiments, an electrophoretic precast gel substrate includes a front plate comprising a first tenon-and-mortise connective structure, and a rear plate comprising a second tenon-and-mortise connective structure. The front plate and the rear plate can include snap features that are configured to provide a snap fit with a corresponding structure. The front and rear plates can be configured to be coupled and/or decoupled along the first and second tenon-and-mortise connective structures.

A biochip compatible with very small blood sample volumes is used for delecting for detecting hemoglobin disorders and monitoring disorders associated with aberrant blood cell deformability and adhesion, including disease severity, upcoming pain crisis, treatment response, and treatment effectiveness in a clinically meaningful way.

An electrophoresis data correction device or a post-color-call data correction device selects specific wavelength data from first data, performs filtering processing to cut some or all of components on a high frequency side, compares peak intensities of the specific wavelength data before and after the filtering processing for each cutoff frequency, calculates, as a first cutoff frequency, the minimum cutoff frequency at which a decrease in peak intensity of the specific wavelength data falls within a predetermined allowable range, and corrects the first data or post-color-call data of the first data by performing filtering processing with the first cutoff frequency.

A device for extracting and concentrating a target analyte including a sample channel that receives the sample, a separation channel, a waste channel, a first junction between the sample channel and the separation channel, and, a second junction between the separation channel and the waste channel. The first junction selectively transports a first group of analytes, including target analytes, from the sample channel to the separation channel in accordance with a size of a first free transport region of the first junction. The second junction selectively transports a second group of analytes from the separation channel to the waste channel in accordance with a size of a second free transport region of the second junction, the second group being a subset of the first group, so as to concentrate a number of the target analytes in the separation channel.

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.

Single-sided optoelectrowetting (SSOEW)-configured substrates are provided, as well as microfluidic devices that include such substrates. The substrates can include a planar electrode, a photoconductive (or photosensitive) layer, a dielectric layer (single-layer or composite), a mesh electrode, and a hydrophobic coating. Fluid droplets can be moved across the hydrophobic coating of such substrates in a light-actuated manner, upon the application of a suitable AC voltage potential across the substrate and the focusing of light into the photoconductive layer of the substrate in a location proximal to the droplets. Walls can be disposed upon the substrates to form the microfluidic devices. Together the walls and substrate can form a microfluidic circuit, through which droplets can be moved.

An apparatus (1) for the measurement of a concentration of a charged species in a sample (10) is disclosed. The sample (10) comprises a plurality of types of charged species and at least one insoluble component. The apparatus (1) comprises a first circuit with a voltage control device (54) connectable to two first electrodes (30, 30′) arranged along a channel (12) holding the sample (10) and a second circuit with a conductivity detection device (55) connectable to two second electrodes (5, 5′) arranged in the channel (12). The first circuit and the second circuit are dc and ac electrically isolated from each other.

An apparatus includes a body portion that defines a reservoir and a set of substantially flexible capillaries. The set of substantially flexible capillaries are fixedly coupled to the body portion and in fluid communication with the reservoir. A connector is configured to be coupled to the body portion to be in fluid communication with the reservoir and the set of substantially flexible capillaries. The connector is further configured to be coupled to a vacuum source. The apparatus is arranged such that at least a part of the body portion is electrically conductive. Methods for separating and detecting an analyte from a biological sample with the apparatus are also provided. For example, methods for separating and detecting one or more proteins from a cellular lysate or a purified protein are also provided.