In some embodiments, a method for manipulating DNA molecules for use in a microfluidic device is provided, where the method may comprise providing a solution of a plurality of DNA molecules having a first radius of gyration under under a zero flow velocity, and maintaining the DNA molecules in a spherical shape under a flow velocity.

In some embodiments, a method for manipulating DNA molecules for use in a microfluidic device is provided, where the method may comprise providing a solution of a plurality of DNA molecules having a first radius of gyration under under a zero flow velocity, and maintaining the DNA molecules in a spherical shape under a flow velocity.

Provided herein is technology relating to methods for assaying a cell-containing body sample and particularly, but not exclusively, to treating a sample under conditions to cause cell lysis, preferably by means of a detergent; and subjecting the lysed sample to conditions causing the cleavage of nucleic acid molecules. The technology additionally relates to using nucleic acid cleavage conditions to enhance a membrane assay, a device for carrying out such an assay, and a kit for use in the assay.

Provided herein is technology relating to methods for assaying a cell-containing body sample and particularly, but not exclusively, to treating a sample under conditions to cause cell lysis, preferably by means of a detergent; and subjecting the lysed sample to conditions causing the cleavage of nucleic acid molecules. The technology additionally relates to using nucleic acid cleavage conditions to enhance a membrane assay, a device for carrying out such an assay, and a kit for use in the assay.

The present invention provides highly sensitive methods used for diagnosing and monitoring various diseases and disorders by detecting and analyzing “ultra short” (20-50 base pair) nucleic acids obtained from bodily fluids.

The present invention provides highly sensitive methods used for diagnosing and monitoring various diseases and disorders by detecting and analyzing “ultra short” (20-50 base pair) nucleic acids obtained from bodily fluids.

The invention is directed to tools, compositions and methods for collecting, storing, transporting, isolating and detecting macromolecules such as nucleic acid sequences obtained from specimens. The compositions are one-step formulations for killing or inactivating pathogens, inactivating enzymes, and releasing nucleic acids from the specimens that are prepared for further processing and/or analysis. In particular, the invention provides a single, one-step, sample collection and transport formulation that facilitates the concentration, extraction, isolation and analysis of nucleic acids, genes and genomes.

The invention is directed to tools, compositions and methods for collecting, storing, transporting, isolating and detecting macromolecules such as nucleic acid sequences obtained from specimens. The compositions are one-step formulations for killing or inactivating pathogens, inactivating enzymes, and releasing nucleic acids from the specimens that are prepared for further processing and/or analysis. In particular, the invention provides a single, one-step, sample collection and transport formulation that facilitates the concentration, extraction, isolation and analysis of nucleic acids, genes and genomes.

Provided herein are methods and systems for cell-free DNA extraction from liquid biological samples. The methods can be employed for determination of fetal DNA fraction and non-invasive prenatal screening of fetal aneuploidies and analyses of other types of cell-free DNA.

Provided herein are methods and systems for cell-free DNA extraction from liquid biological samples. The methods can be employed for determination of fetal DNA fraction and non-invasive prenatal screening of fetal aneuploidies and analyses of other types of cell-free DNA.