The present disclosure relates to methods and kits for generating single cell barcodes and imparting them to the constituent molecules within a single cell. Additionally, methods to overlay sample barcode and spatial barcode information onto the single cell barcodes are also described. Generation of single cell barcodes is achieved by labeling the genomic DNA of a cell/nucleus with a small handful, preferably just a one or two cellular barcode probes (CBP) that can be amplified and propagated to label the constituent molecules within the cell. The disclosure finds utility in applications such as characterization of cellular heterogeneity, comprehensive profiling of tissue composition, characterization of adherent cells, discovery of new cell subtypes and functions of individual cells in the context of its microenvironment, and others.

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.

Examples relate to techniques for performing a nucleic acid amplification reaction. The method includes generating a nucleic acid solution comprising a plurality of nucleic acid molecules, and combining the nucleic acid solution with a plurality of chamber particles. Each chamber particle includes a chamber for receiving the nucleic acid solution, wherein the chamber receives, at most, one of the plurality of nucleic acid molecules. Each chamber particle also includes reagents for causing a polymerase chain reaction within the chamber. The method further includes inducing nucleic acid amplification to generate an amplified nucleic acid, and performing a detection process to detect the presence of the amplified nucleic acid within the chamber.

Examples relate to techniques for performing a nucleic acid amplification reaction. The method includes generating a nucleic acid solution comprising a plurality of nucleic acid molecules, and combining the nucleic acid solution with a plurality of chamber particles. Each chamber particle includes a chamber for receiving the nucleic acid solution, wherein the chamber receives, at most, one of the plurality of nucleic acid molecules. Each chamber particle also includes reagents for causing a polymerase chain reaction within the chamber. The method further includes inducing nucleic acid amplification to generate an amplified nucleic acid, and performing a detection process to detect the presence of the amplified nucleic acid within the chamber.

Provided herein, among other things, are various compositions and methods for analyzing chromatin. In some embodiments, the composition may comprise a mixture of a nicking enzyme, four dNTPs, at least one labeled dNTP and, optionally, a polymerase. In some embodiments, this method may comprise: obtaining a sample comprising chromatin, reacting the sample with the composition to selectively label the open chromatin in the sample, and analyzing the labeled sample.

Provided herein, among other things, are various compositions and methods for analyzing chromatin. In some embodiments, the composition may comprise a mixture of a nicking enzyme, four dNTPs, at least one labeled dNTP and, optionally, a polymerase. In some embodiments, this method may comprise: obtaining a sample comprising chromatin, reacting the sample with the composition to selectively label the open chromatin in the sample, and analyzing the labeled sample.

This invention features systems and methods for the detection of analytes, and their use in the treatment and diagnosis of disease.

The present disclosure relates to compositions and methods for generating capture probes on a substrate for identifying the location of analytes in a biological sample.

Provided herein, among other things, are various compositions and methods for analyzing chromatin. In some embodiments, the composition may comprise a mixture of a nicking enzyme, four dNTPs, at least one labeled dNTP and, optionally, a polymerase. In some embodiments, this method may comprise: obtaining a sample comprising chromatin, reacting the sample with the composition to selectively label the open chromatin in the sample, and analyzing the labeled sample.