The present disclose provides methods and systems for amplifying and quantifying nucleic acids and for detecting the presence or absence of a target in a sample. The methods and systems provided herein may utilize a device comprising a plurality of partitions separated from an external environment by a gas-permeable barrier. Certain methods disclosed herein involve subjecting nucleic acid molecules in the plurality of partitions to conditions sufficient to conduct nucleic acid amplification reactions. The nucleic acid molecules may be subjected to controlled heating in the plurality of partitions to generate data indicative of a melting point(s) of the nucleic acid molecules.

The present disclose provides methods and systems for amplifying and quantifying nucleic acids and for detecting the presence or absence of a target in a sample. The methods and systems provided herein may utilize a device comprising a plurality of partitions separated from an external environment by a gas-permeable barrier. Certain methods disclosed herein involve subjecting nucleic acid molecules in the plurality of partitions to conditions sufficient to conduct nucleic acid amplification reactions. The nucleic acid molecules may be subjected to controlled heating in the plurality of partitions to generate data indicative of a melting point(s) of the nucleic acid molecules.

The invention is directed to methods and systems for analyzing transcriptomes of single cells. In some embodiments, the invention comprises methods for analyzing transcriptomes of a plurality of single cells on separate regions of the same planar surface.

The invention is directed to methods and systems for analyzing transcriptomes of single cells. In some embodiments, the invention comprises methods for analyzing transcriptomes of a plurality of single cells on separate regions of the same planar surface.

The present invention provides a method for detecting the presence or absence of a target analyte in a test sample, comprising the steps: i) providing a plurality of detector nanoparticles comprising a first detector nanoparticle functionalised with a first probe specific for a first region of a target analyte and a second detector nanoparticle functionalised with a second probe specific for a second region of said target analyte; and ii) contacting said detector nanoparticles with a test sample under conditions suitable for the binding of the specific probes to the target analyte, wherein target analyte-induced agglomeration of the detector nanoparticles permits the release of a detectable signal means from a signal reservoir. Also provided are related devices and systems for performing the method of the invention.

The present invention provides a method for detecting the presence or absence of a target analyte in a test sample, comprising the steps: i) providing a plurality of detector nanoparticles comprising a first detector nanoparticle functionalised with a first probe specific for a first region of a target analyte and a second detector nanoparticle functionalised with a second probe specific for a second region of said target analyte; and ii) contacting said detector nanoparticles with a test sample under conditions suitable for the binding of the specific probes to the target analyte, wherein target analyte-induced agglomeration of the detector nanoparticles permits the release of a detectable signal means from a signal reservoir. Also provided are related devices and systems for performing the method of the invention.

A method of forming a polymer matrix array includes applying an aqueous solution into wells of a well array. The aqueous solution includes polymer precursors. The method further includes applying an immiscible fluid over the well array to isolate the aqueous solution within the wells of the well array and polymerizing the polymer precursors isolated in the wells of the well array to form the polymer matrix array. An apparatus includes a sensor array, a well array corresponding to the sensor array, and an array of polymer matrices disposed in the well array.

A method of forming a polymer matrix array includes applying an aqueous solution into wells of a well array. The aqueous solution includes polymer precursors. The method further includes applying an immiscible fluid over the well array to isolate the aqueous solution within the wells of the well array and polymerizing the polymer precursors isolated in the wells of the well array to form the polymer matrix array. An apparatus includes a sensor array, a well array corresponding to the sensor array, and an array of polymer matrices disposed in the well array.

The present invention provides a composition capable of hermetically sealing a PCR reaction vessel without using a closure member or adhesive seal. Disclosed is a composition for preventing evaporation of a nucleic acid amplification reaction solution during nucleic acid amplification reaction, which is a liquid during the reaction and becomes a solid through chemical or thermal changes after completion of the reaction. Also disclosed is a composition for preventing evaporation of a nucleic acid amplification reaction solution during nucleic acid amplification reaction, wherein the melting point of the composition is 0-15 C. Also disclosed is a composition for preventing evaporation of a nucleic acid amplification reaction solution during nucleic acid amplification reaction, wherein the melting point of the composition is 5-10 C.

The present invention provides a composition capable of hermetically sealing a PCR reaction vessel without using a closure member or adhesive seal. Disclosed is a composition for preventing evaporation of a nucleic acid amplification reaction solution during nucleic acid amplification reaction, which is a liquid during the reaction and becomes a solid through chemical or thermal changes after completion of the reaction. Also disclosed is a composition for preventing evaporation of a nucleic acid amplification reaction solution during nucleic acid amplification reaction, wherein the melting point of the composition is 0-15 C. Also disclosed is a composition for preventing evaporation of a nucleic acid amplification reaction solution during nucleic acid amplification reaction, wherein the melting point of the composition is 5-10 C.