The present invention provides a method for the quantification of virus particles in a biological sample, comprising the steps of: (a) introducing said biological sample comprising virus particles into a capillary tube containing a buffer solution; (b) applying an electrical field to said capillary tube of sufficient voltage to allow for the separation of the virus particles from additional constituents in said sample, to obtain electrophoretical fractions; (c) generating an electropherogram associated with the electrophoretical fractions; and (d) determining the concentration of virus particles in said sample by comparing the electropherogram with an electropherogram generated from a reference sample containing a known concentration of said virus particles.

A cartridge for use in an electrowetting sample processing system, the cartridge having at least one inlet port for introducing an input liquid in an internal gap of the cartridge, wherein the gap has at least one hydrophobic surface and is configured to provide an electrowetting induced movement of a microfluidic droplet of input liquid, wherein the input liquid has a carrier liquid and a processing liquid and the gap has a capture zone that is configured to capture at least a part of the processing liquid as a microfluidic droplet by use of electrowetting force and the gap further has a transfer zone that is configured to provide a passage for the carrier liquid next to the microfluidic droplet, while processing liquid is captured in the capture zone.

A sample containing particles having high-molecular-weight (HMW) DNA is entrapped in a gel matrix, and the gel matrix is exposed to a lysis reagent configured to release the HMW DNA from the particles. The HMW DNA may be purified by subjecting the gel matrix to an electrophoretic field that removes the HMW DNA from the particles, lysis reagents, and/or other sample constituents, from the gel matrix such that the HMW DNA remains. The gel matrix may be subjected with DNA cleavase re-agents configured to cleave at specific DNA sequences within the HMW DNA to liberate defined segments of the DNA as fragments of reduced size. The gel matrix may also be subjected to an electrophoretic field, which moves and separates the DNA fragments from uncleaved DNA of the HMW DNA, which remains substantially immobile. The electrophoretically separated DNA fragments may be isolated from the gel matrix.

Protein separation by capillary electrophoresis using a buffer composition comprising hydrophobic detergents that have alkyl chains longer than 12 carbon atoms. The formation of high molecular weight artifacts is suppressed.

There is provided a separation analysis method for analyzing a sample component s included in a sample liquid by introducing the sample liquid into a separation flow path filled with a flow path liquid, the method comprising: obtaining a correction factor representing a proportion of a time period from the first point in time when the sample liquid is introduced into the separation flow path, to the second point in time when an interface between the flow path liquid and the sample liquid reaches a predetermined position at the separation flow path, with respect to a time period from the first point in time to the third point in time when an optical characteristic value of the sample component is measured at the predetermined position, and correcting the measured optical characteristic value with the correction factor.

A sample containing particles having high-molecular-weight (HMW) DNA is entrapped in a gel matrix, and the gel matrix is exposed to a lysis reagent configured to release the HMW DNA from the particles. The HMW DNA may be purified by subjecting the gel matrix to an electrophoretic field that removes the HMW DNA from the particles, lysis reagents, and/or other sample constituents, from the gel matrix such that the HMW DNA remains. The gel matrix may be subjected with DNA cleavase reagents configured to cleave at specific DNA sequences within the HMW DNA to liberate defined segments of the DNA as fragments of reduced size. The gel matrix may also be subjected to an electrophoretic field, which moves and separates the DNA fragments from uncleaved DNA of the HMW DNA, which remains substantially immobile. The electrophoretically separated DNA fragments may be isolated from the gel matrix.

A horizontal electrophoresis apparatus according to the present invention comprises a first electrode and a second electrode arranged at respective sides of an electrophoretic gel and each in close contact with one side of the electrophoretic gel. By using the first electrode and the second electrode each in close contact with one side of the electrophoretic gel, the horizontal electrophoresis apparatus enables electric current to flow across the entire cross section of the electrophoretic gel, and thus can prevent an electric current difference from occurring between the upper and lower ends of the electrophoretic gel and solve the problem of a reduction in the resolution of protein bands.

Provided is a digital microfluidic device for quick polymerase chain reaction. The digital microfluidic device includes an enclosed chamber for holding droplets comprising PCR mixtures. The chamber has an upper layer and a lower layer, which provide a top heater and a bottom heater contained in a thermal electrode respectively to form dual heaters. The lower layer further has an array of electrodes and a dielectric layer, e.g. Norland Optical adhesive 61, coating thereon. Such arrangement of the digital microfluidic device allows quick and homogeneous heating of droplets to lower the heating voltage, shorten the reaction time, and prevent the dielectric layer from breakdown during the thermal cycle.

The present exemplary embodiments provide a sample separation device which applies an electric field to a selective ion permeable layer based on origami to concentrate a target material in a specific area and concentrates a target material and separates a non-target material through a filter layer in which a paper is compressed to adjust a size of micro pore.

Disclosed is a device for impregnation using electrophoresis, which includes a chassis, a storing unit, a pipeline unit, an injection unit, a bearing tank, a first driver element and a second driver element, wherein the storing unit has several storage tanks storing the materials for impregnation. The pipeline unit has several pipelines connecting the storage tanks and the injection unit. The injection unit has a static mixing tube and an injector, so as to inject said materials for impregnation into the several slide sets located in the bearing tank. The first driver element drives the bearing tank to reciprocate transversely, and the second driver element drives the injection unit to shift up and down. The device can perform impregnation operations automatically, with quick operation and low operational difficulty level, while the prepared gel has high quality stability and yield.