A method of quantifying charge variants within an analyte may include introducing a sample buffer comprising the analyte into a capillary, separating charge variants within the sample buffer along an isoelectric gradient, incubating the capillary in a detection antibody, quantifying a relative abundance of a charge variant based on a signal that corresponds to the detection antibody. The method may further include generating an electropherogram, wherein the electropherogram includes a plot of a strength of a signal generated by a reporter molecule versus an isoelectric point along the isoelectric gradient where the signal was detected.

An electrophoresis apparatus with minimal autofluorescence to enable gel processing in situ, and methods of making and using the electrophoresis apparatus. An exemplary electrophoresis apparatus may comprise a cassette defining a cavity between a first pane and a second pane of a double-paned viewing window, and also may comprise a slab gel located in the cavity. The viewing window may be transparent to ultraviolet light that drives a derivatization reaction in the slab gel, and, absent the slab gel, may define a window autofluorescence inducible by irradiation with the ultraviolet light. The window autofluorescence, per unit area, may be less than five-fold a gel autofluorescence of the slab gel, per the same unit area and under the same irradiation with the ultraviolet light.

Provided is an electrophoresis device for enhancing its analysis performance. In order to achieve the task, the electrophoresis device includes a capillary array constituted by a capillary, a capillary head for bundling an end of the capillary, an electrode holder for holding an electrode provided at the other end of the capillary and a detector provided for the capillary, a first heater for heating the capillary, and an irradiation detection unit for irradiating a light to the detector to detect a fluorescence generated from a fluorescence labelled sample in the capillary. The electrophoresis device further includes a second heater for heating the detector.

Antibiotics (Abx) are the worlds most misused drugs. Antibiotics misuse occurs when the drug is administered in case of a non-bacterial infection (such as a viral infection) for which it is ineffective. Overall, it is estimated that 40-70% of the worldwide Abx courses are mis-prescribed. The financial and health consequences of Abx over-prescription include the direct cost of the drugs, as well as the indirect costs of their side effects, which are estimated at >$15 billion annually. Furthermore, over-prescription directly causes the emergence of Abx-resistant strains of bacteria, which are recognized as one of the major threats to public health today. This generates an immediate need for reliable diagnostics to assist physicians in correct Abx prescription, especially at the point-of-care (POC) where most Abx are prescribed. Accordingly, some aspects of the present invention provide methods using biomarkers for rapidly detecting the source of infection and administrating the appropriate treatment.

A method of collecting one or more target macromolecules in a capture membrane by gel electrophoresis is disclosed, as well as a kit for macromolecule isolation and recovery including: a preformed gel; a capture device; an insertion guide; and optionally, a migration gauge.

Provided herein are methods and systems pertaining to sequencing units of analytes using nanopores. In general, arresting constructs are used to modify an analyte such that the modified analyte pauses in the opening of a nanopore. During such a pause, an ion current level is obtained that corresponds to a unit of the analyte. After altering the modified analyte such that the modified analyte advances through the opening, another arresting construct again pauses the analyte, allowing for a second ion current level to be obtained that represents a second unit of the analyte. This process may be repeated until each unit of the analyte is sequenced. Systems for performing such methods are also disclosed.

Methods for detecting and/or discriminating between variants of an antibody contaminating protein or multiple antibodies in a sample by a physical parameter, in which the method includes: separating protein components of a sample by molecular weight or charge in one or more capillaries using capillary electrophoresis; immobilizing the protein components of the sample within the one or more capillaries; contacting the protein components within the one or more capillaries with one or more primary antibodies that specifically bind to the antibody, the contaminating protein or multiple antibodies in the sample, thereby detecting and/or discriminating between variants in the sample.

A diagnostic assay to determine a percentage rumen undegraded protein in a food product by comparing the percentage of modified protein content to the total crude protein content of the food product. The total crude protein content extracted from a food product sample prior to conducting gel electrophoresis to separate modified protein content from the total crude protein content. The gel band intensities of the separated protein contents analyzed to enumerate a ratio that is used to derive a correlated percentage numen undegraded protein for a given food product sample. The diagnostic assay capable of being provided onsite for quick, cost-efficient and accurate results.

A capillary array electrophoresis (CAE)-chemiluminescence (CL) detection coupled system includes a high-voltage power supply, a capillary array, an array channel CL reaction tank, a CAE sample tank, a CAE detection tank, a chemiluminescent reagent delivery unit, a multi-channel detection unit, and a data acquisition and processing unit. An inlet end of the capillary array is connected to the CAE sample tank. An outlet end of the capillary array is connected to the array channel CL reaction tank, and is further connected to the CAE detection tank.

A separation device receives a known or unknown glycan that is co-injected with three different oligomers maltooligosaccharide (MOL). A detector measures the separated glycan and the separated three different oligomers as intensity peaks that are a function of migration time. The migration times of a plurality of other oligomers of MOL are calculated from the migration times of the three different oligomers. Glucose unit (GU) values for the intensity peaks of the separated glycan are calculated by comparing their migration times to the calculated migration times of the plurality of other oligomers of MOL. The processor identifies the structure of the glycan by comparing the calculated GU values of the intensity peaks of the separated glycan to a database of GU values for known glycan structures.