The present disclosure is related to methods and materials for depleting unwanted RNA species from a nucleic acid sample. In particular, the present disclosure describes how to remove unwanted rRNA, tRNA, mRNA or other RNA species that could interfere with the analysis, manipulation and study of target RNA molecules in a sample.

Provided herein is technology related to the chemical modification and purification of DNA. Specifically, the technology provides methods for performing a bisulfite conversion reaction on small amounts of single-stranded, fragmented DNA and performing the subsequent desulfonation and purification steps on magnetic beads.

Provided herein is technology related to the chemical modification and purification of DNA. Specifically, the technology provides methods for performing a bisulfite conversion reaction on small amounts of single-stranded, fragmented DNA and performing the subsequent desulfonation and purification steps on magnetic beads.

The present disclosure is related to methods and materials for depleting unwanted RNA species from a nucleic acid sample. In particular, the present disclosure describes how to remove unwanted rRNA, tRNA, mRNA or other RNA species that could interfere with the analysis, manipulation and study of target RNA molecules in a sample.

The present disclosure is related to methods and materials for depleting unwanted RNA species from a nucleic acid sample. In particular, the present disclosure describes how to remove unwanted rRNA, tRNA, mRNA or other RNA species that could interfere with the analysis, manipulation and study of target RNA molecules in a sample.

The present disclosure includes compounds, compositions, and methods for nucleic acid amplification reactions. In particular, the present disclosure provides compounds, compositions, and methods for viability PCR (vPCR) applications, in which the compounds that selectively bind to nucleic acids from non-viable cells.

The present disclosure includes compounds, compositions, and methods for nucleic acid amplification reactions. In particular, the present disclosure provides compounds, compositions, and methods for viability PCR (vPCR) applications, in which the compounds that selectively bind to nucleic acids from non-viable cells.

The invention relates to a method of identifying or producing an aptamer, the method comprising the steps of: a) Providing a candidate mixture of nucleic acids; b) Contacting the candidate mixture with a target sample; c) Partitioning nucleic acids that bind to the target sample from those that do not bind; d) Amplifying the binding nucleic acids to produce a population of nucleic acids that bind the target sample; e) Single strand displacement of the amplified nucleic acids, f) optionally repeating the steps a) to e), thereby identifying or producing an aptamer, wherein the target sample provides one or more peptides and/or proteins in a denatured form.

The invention relates to a method of identifying or producing an aptamer, the method comprising the steps of: a) Providing a candidate mixture of nucleic acids; b) Contacting the candidate mixture with a target sample; c) Partitioning nucleic acids that bind to the target sample from those that do not bind; d) Amplifying the binding nucleic acids to produce a population of nucleic acids that bind the target sample; e) Single strand displacement of the amplified nucleic acids, f) optionally repeating the steps a) to e), thereby identifying or producing an aptamer, wherein the target sample provides one or more peptides and/or proteins in a denatured form.

The invention provides methods and compositions for hybridizing at least one molecule to a target. The invention may, for example, utilize a of cyclic and/or non-cyclic solvent that is non-toxic and may eliminate or reduce the amount of formamide in the hybridization composition.