Provided are devices, systems, and methods for the identification, quantification, and profiling of microscopic organisms. The methods for the identification, quantification, and profiling of microscopic organisms include, for example, the selective enrichment of microscopic organisms from a heterogeneous sample; subsequent loading of the microscopic organisms into microfluidic channels or reaction chambers; direct amplification of nucleic acids from single, isolated microscopic organisms; and examination of amplification products using digital High Resolution Melting (HRM) analysis.

Provided are devices, systems, and methods for the identification, quantification, and profiling of microscopic organisms. The methods for the identification, quantification, and profiling of microscopic organisms include, for example, the selective enrichment of microscopic organisms from a heterogeneous sample; subsequent loading of the microscopic organisms into microfluidic channels or reaction chambers; direct amplification of nucleic acids from single, isolated microscopic organisms; and examination of amplification products using digital High Resolution Melting (HRM) analysis.

Disclosed herein, inter alia, are methods and compositions for sequencing a plurality of template nucleic acids.

Disclosed herein, inter alia, are methods and compositions for sequencing a plurality of template nucleic acids.

Disclosed herein, inter alia, are methods and compositions for sequencing a plurality of template nucleic acids.

A method of forming a polymer matrix array includes treating a surface within a well of a well array with a surface compound including a surface reactive functional group and a radical-forming distal group; applying an aqueous solution including polymer precursors to the well of the well array; and activating the radical-forming distal group of the surface coupling compound with an initiator and atom transfer radical polymerization (ATRP) catalyst to initiate radical polymerization of the polymer precursors within the well of the well array to form the polymer matrix array.

A method of forming a polymer matrix array includes treating a surface within a well of a well array with a surface compound including a surface reactive functional group and a radical-forming distal group; applying an aqueous solution including polymer precursors to the well of the well array; and activating the radical-forming distal group of the surface coupling compound with an initiator and atom transfer radical polymerization (ATRP) catalyst to initiate radical polymerization of the polymer precursors within the well of the well array to form the polymer matrix array.

A method of forming a polymer matrix array includes treating a surface within a well of a well array with a surface compound including a surface reactive functional group and a radical-forming distal group; applying an aqueous solution including polymer precursors to the well of the well array; and activating the radical-forming distal group of the surface coupling compound with an initiator and atom transfer radical polymerization (ATRP) catalyst to initiate radical polymerization of the polymer precursors within the well of the well array to form the polymer matrix array.

Novel methods of generating a localized population of immobilized clonal amplicons on a support are provided.

Novel methods of generating a localized population of immobilized clonal amplicons on a support are provided.