The present invention is directed to methods and compositions for generating a pool of oligonucleotides. The invention finds use in preparing a population or subpopulations of oligonucleotides in solution. The pool of oligonucleotides finds use in a variety of nucleic acid detection and/or amplification assays.

A method including steps of (a) providing an array of sites, wherein each site comprises a mixture of different nucleic acid templates; (b) extending primers hybridized to the different nucleic acid templates at each of the sites with different nucleotide analogs having different reversible blocking moieties, respectively, thereby producing different primer extension products at each site; (c) detecting the different primer extension products to distinguish the different nucleotide analogs at each site; and (d) removing the different reversible blocking moieties from the primer extension products at each of the sites using a first treatment that is selective for a first of the different reversible blocking moieties and a second treatment that is selective for a second of the different reversible blocking moieties.

A method including steps of (a) providing an array of sites, wherein each site comprises a mixture of different nucleic acid templates; (b) extending primers hybridized to the different nucleic acid templates at each of the sites with different nucleotide analogs having different reversible blocking moieties, respectively, thereby producing different primer extension products at each site; (c) detecting the different primer extension products to distinguish the different nucleotide analogs at each site; and (d) removing the different reversible blocking moieties from the primer extension products at each of the sites using a first treatment that is selective for a first of the different reversible blocking moieties and a second treatment that is selective for a second of the different reversible blocking moieties.

Techniques regarding screening for mutations using nanoscale deterministic arrays are provided. For example, one or more embodiments described herein can comprise a method, which can comprise cleaving a deoxyribonucleic acid segment hybridized with a molecular probe to form a sample fluid. The cleaving can occur at a first end and a second end of the molecular probe. Also, the cleaving can comprise a cleaving agent that targets base pair mismatches. The method can also comprise supplying the sample fluid to a nanoscale deterministic lateral displacement array to screen for a single nucleotide polymorphism.

Techniques regarding screening for mutations using nanoscale deterministic arrays are provided. For example, one or more embodiments described herein can comprise a method, which can comprise cleaving a deoxyribonucleic acid segment hybridized with a molecular probe to form a sample fluid. The cleaving can occur at a first end and a second end of the molecular probe. Also, the cleaving can comprise a cleaving agent that targets base pair mismatches. The method can also comprise supplying the sample fluid to a nanoscale deterministic lateral displacement array to screen for a single nucleotide polymorphism.

This invention provides a process for sequencing single-stranded DNA by employing a nanopore and modified nucleotides.

This invention provides a process for sequencing single-stranded DNA by employing a nanopore and modified nucleotides.

The invention relates to methods for processing an RNA sample and allows for single cell sequencing of full length total RNA. The method includes labeling the RNA sample with at least one of a barcode and a unique molecular identifier.

The invention relates to methods for processing an RNA sample and allows for single cell sequencing of full length total RNA. The method includes labeling the RNA sample with at least one of a barcode and a unique molecular identifier.

Modular flow cells, devices with modular flow cells, and methods of sequencing using modular flow cells, as well as systems and kits including modular flow cells, are described, permitting sequencing wherein less than the full capacity for sequencing is desired.