An example of a flow cell includes a substrate, a plurality of chambers defined on or in the substrate, and a plurality of depressions defined in the substrate and within a perimeter of each of the plurality of chambers. The depressions are separated by interstitial regions. Primers are attached within each of the plurality of depressions, and a capture site is located within each of the plurality of chambers.

Some embodiments described herein relate to new polymer coatings for surface functionalization and new processes for grafting pre-grafted DNA-copolymers to surface(s) of substrates for use in DNA sequencing and other diagnostic applications.

The present invention is concerned with compositions and methods for improving the rate of correct sample identification in indexed nucleic acid library preparations for multiplex next generation sequencing by exonuclease treatment and optionally blocking the 3′ ends of pooled indexed polynucleotides from multiple samples prior to amplification and sequencing.

The present invention is concerned with compositions and methods for improving the rate of correct sample identification in indexed nucleic acid library preparations for multiplex next generation sequencing by exonuclease treatment and optionally blocking the 3′ ends of pooled indexed polynucleotides from multiple samples prior to amplification and sequencing.

The present disclosure relates to processes for suspending stretched nucleic acids over surface features. These processes can be used to prepare stretched nucleic acids that are more active in enzymatic reactions and other reactions than those laid down on a flat surface. These processes can be achieved by using a photoresist layer on top of a substrate, stretch a nucleic acid on top of the surface, and then remove part of the photoresist to form surface features that suspend the stretched nucleic acid. Furthermore, the formation of a hydrogel layer over the stretched nucleic acid and the surface features can transfer the stretched nucleic acid to the hydrogel for further reactions, including enzymatic reactions.

The present disclosure relates to processes for suspending stretched nucleic acids over surface features. These processes can be used to prepare stretched nucleic acids that are more active in enzymatic reactions and other reactions than those laid down on a flat surface. These processes can be achieved by using a photoresist layer on top of a substrate, stretch a nucleic acid on top of the surface, and then remove part of the photoresist to form surface features that suspend the stretched nucleic acid. Furthermore, the formation of a hydrogel layer over the stretched nucleic acid and the surface features can transfer the stretched nucleic acid to the hydrogel for further reactions, including enzymatic reactions.

Structured substrate including (a) a plurality of nanoparticles distributed on a solid support, (b) a gel material forming a layer in association with the plurality of nanoparticles, and (c) a library of target nucleic acids in the gel material.

Structured substrate including (a) a plurality of nanoparticles distributed on a solid support, (b) a gel material forming a layer in association with the plurality of nanoparticles, and (c) a library of target nucleic acids in the gel material.

A method includes forming a patterned substrate including a plurality of base pads, using a nano-imprint lithography process. A capture substance is attached to each of the plurality of base pads, optionally through a linker, the capture substance being adapted to promote capture of a target molecule.

A method includes forming a patterned substrate including a plurality of base pads, using a nano-imprint lithography process. A capture substance is attached to each of the plurality of base pads, optionally through a linker, the capture substance being adapted to promote capture of a target molecule.