There is provided an impurity precipitant composition used for precipitating and removing impurities that inhibit the pure separation of DNA during the process of extracting DNA by lysis of cells in a sample. The composition includes 1.3-2.1% (w/v) phosphotungstic acid hydrate, 1.2-1.8% (w/v) zinc acetate dihydrate, 13.0-19.0% (v/v) acetic acid, with the remainder being water.

A method for preparing test solution for pathogen detection purpose, system, kit, detection primer and method are provided. The method of preparing a test solution includes lysing the sample to be tested with a lysis buffer to release the nucleic acids contained in the sample to obtain a lysis buffer containing nucleic acids and/or pathogen nucleic acids; extracting the lysis buffer containing nucleic acids through a nucleic acid extraction device to obtain an extract containing host nucleic acids and/or pathogen nucleic acids; preparing the test solution for pathogen detection purposes from the extract. A large volume of samples can be used in the present application and it greatly improves sensitivity and specificity of the assay.

The present invention provides a disposable pipette tip for dispersive solid phase extraction (SPE) that allows for rapid, automatable purification of large biomolecules, such as nucleic acids, proteins and polypeptides without the need for additional tools such as centrifuges, magnetic plates or vacuum manifolds. The pipette tip is designed for optimal biomolecule isolation while maintaining sample integrity. Optimized methods of using the dispersive pipette extraction system for isolation of large biomolecules are also provided.

The present invention provides circularized RNA and methods of making, purifying, and using same.

A method of single-stranded RNA purification comprising the steps applying a sample containing single-stranded RNA to a solid phase bearing dominantly or exclusively primary amino groups on its surface, at a pH value sufficient to bind at least predominantly the single-stranded RNA, eluting the single-stranded RNA from the surface of the solid phase by exposing the surface of the solid phase to increasing pH.

Methods and apparatus providing for the isolation of an unknown mutation from a sample comprising wild type nucleic acids and mutated nucleic acids through the application of time-varying driving fields and periodically varying mobility-altering fields to the sample within in an affinity matrix.

Methods and apparatus providing for the isolation of an unknown mutation from a sample comprising wild type nucleic acids and mutated nucleic acids through the application of time-varying driving fields and periodically varying mobility-altering fields to the sample within in an affinity matrix.

The present disclosure relates to fluidic systems and devices for processing, extracting, or purifying one or more analytes. These systems and devices can be used for processing samples and extracting nucleic acids, for example by isotachophoresis. In particular, the systems and related methods can allow for extraction of nucleic acids, including non-crosslinked nucleic acids, from samples such as tissue or cells. The systems and devices can also be used for multiplex parallel sample processing.

The present disclosure relates to fluidic systems and devices for processing, extracting, or purifying one or more analytes. These systems and devices can be used for processing samples and extracting nucleic acids, for example by isotachophoresis. In particular, the systems and related methods can allow for extraction of nucleic acids, including non-crosslinked nucleic acids, from samples such as tissue or cells. The systems and devices can also be used for multiplex parallel sample processing.

Methods, systems, and devices for sampling/isolating material from cells. An exemplary system may comprise a chip including an electrode array of sampling electrodes arranged along a surface of the chip. A cell-receiving area may be located adjacent the surface of the chip. The system also may comprise a tag array of tags supported by the chip and aligned with the electrode array. Each tag of the tag array may include an identifier that is unique to the tag within the tag array. Each tag may be configured to bind nucleic acids, or a capturing agent distinct from the tag may be aligned with each sampling electrode of the electrode array to capture a protein or other analyte of interest. The system further may comprise a control circuit configured to apply an individually controllable voltage to each sampling electrode of the electrode array and measure an electrical property of the sampling electrode.