The invention relates to methods of synthesizing polymers, biopolymers, and nucleic acids, to immobilised dNTP/NTPs and kits comprising said immobilised dNTP/NTPs for use in said methods of nucleic acid synthesis.

The invention relates to methods of synthesizing polymers, biopolymers, and nucleic acids, to immobilised dNTP/NTPs and kits comprising said immobilised dNTP/NTPs for use in said methods of nucleic acid synthesis.

There is disclosed a process for in vitro synthesis and assembly of long, gene-length polynucleotides based upon assembly of multiple shorter oligonucleotides synthesized in situ on a microarray platform. Specifically, there is disclosed a process for in situ synthesis of oligonucleotide fragments on a solid phase microarray platform and subsequent, on device assembly of larger polynucleotides composed of a plurality of shorter oligonucleotide fragments.

There is disclosed a process for in vitro synthesis and assembly of long, gene-length polynucleotides based upon assembly of multiple shorter oligonucleotides synthesized in situ on a microarray platform. Specifically, there is disclosed a process for in situ synthesis of oligonucleotide fragments on a solid phase microarray platform and subsequent, on device assembly of larger polynucleotides composed of a plurality of shorter oligonucleotide fragments.

Described herein is an enzyme-mediated approach to bioconjugation at nanoparticle (NP) surfaces. This process is enabled by a new synthetic linker compatible with the covalent attachment of alkyne modified substrates, including dyes, peptides and nucleic acids. The methods described herein specifically allow for the linkage of molecules to a DNA-functionalized nanoparticle surface. Enzymatic ligation of molecules to the terminal hydroxyl group of DNA using T4 DNA ligase is achieved through incorporation of a single monophosphate on the approaching substrate. In contrast to previous strategies, the linkers disclosed herein are compatible with alkyne modified molecules of a variety of sizes and charges indicating that the ligase minimally requires the monophosphate and the incoming hydroxyl for conjugation to be successful.

Methods for preparing sequencing libraries from a DNA-containing test sample, as well as methods for correcting sequencing-derived errors, are provided.

Systems, methods, and compositions provided herein relate to preparation of beads encapsulating biomolecules for performing sequential reactions on the biomolecules. Some embodiments include preparation of nucleic acid reactions within the bead, wherein the bead includes pores that allow diffusion of molecules into or out of the beads while retaining other molecules of interest.

Systems, methods, and compositions provided herein relate to preparation of beads encapsulating biomolecules for performing sequential reactions on the biomolecules. Some embodiments include preparation of nucleic acid reactions within the bead, wherein the bead includes pores that allow diffusion of molecules into or out of the beads while retaining other molecules of interest.

Embodiments of the present invention provide substrates having controllably co-located polymers of different sequences. Methods are provided that allow the fabrication of arrays of polymers on a substrate having controllably co-located polymers in regions of the array. For example, polymers of nucleic acids and peptides having different sequences and or compositions can be co-located within a region of a substrate. Also provided are arrays of DNA polymers wherein polymers having two different sequences are co-located within a region of an array. The co-located DNA polymers can comprise complementary DNA that is able to hybridize and form double stranded DNA. Arrays having regions comprising double stranded DNA are provided.

Embodiments of the present invention provide substrates having controllably co-located polymers of different sequences. Methods are provided that allow the fabrication of arrays of polymers on a substrate having controllably co-located polymers in regions of the array. For example, polymers of nucleic acids and peptides having different sequences and or compositions can be co-located within a region of a substrate. Also provided are arrays of DNA polymers wherein polymers having two different sequences are co-located within a region of an array. The co-located DNA polymers can comprise complementary DNA that is able to hybridize and form double stranded DNA. Arrays having regions comprising double stranded DNA are provided.