The invention provided methods and devices for performing sequential, regulated multiplex reactions in a single tube without the addition or removal of contents from the tube.

Provided herein are direct-to-library methods, systems, and compositions.

Provided herein are direct-to-library methods, systems, and compositions.

A method for template-directed sequencing-by-synthesis of an array of target polynucleotide can include: (a) providing an array of target polynucleotides in a fluidic vessel; (b) contacting the array of polynucleotides with a solution comprising (i) polymerization complex and (ii) reversibly terminating and differently labeled A, C, G, and T/U nucleotides; (c) incorporating one of the differently labeled nucleotides, using the polymerization complex, into a chain complementary to at least one of the array of polynucleotides; (d) binding imaging tags to the differently labeled nucleotides of step (c); (e) imaging and storing the identity and position of the imaging tags of step (d); (f) reversing termination (b)-(e); (g) repeating steps (b)-(e) and assembling a sequence for each of the array of target polynucleotides from the stored identity and position of the imaging tags, optionally as a homogeneous or one pot reaction. Additional methods of sequencing target polynucleotides are described herein.

A method for template-directed sequencing-by-synthesis of an array of target polynucleotide can include: (a) providing an array of target polynucleotides in a fluidic vessel; (b) contacting the array of polynucleotides with a solution comprising (i) polymerization complex and (ii) reversibly terminating and differently labeled A, C, G, and T/U nucleotides; (c) incorporating one of the differently labeled nucleotides, using the polymerization complex, into a chain complementary to at least one of the array of polynucleotides; (d) binding imaging tags to the differently labeled nucleotides of step (c); (e) imaging and storing the identity and position of the imaging tags of step (d); (f) reversing termination (b)-(e); (g) repeating steps (b)-(e) and assembling a sequence for each of the array of target polynucleotides from the stored identity and position of the imaging tags, optionally as a homogeneous or one pot reaction. Additional methods of sequencing target polynucleotides are described herein.

Rapid nucleic acid libraries, methods of generation, kits, and compositions relating to library synthesis, including reagents, intermediaries and final products are disclosed herein. The disclosure enables rapid synthesis of libraries that allow independent verification of sequence information and rapid identification of sequence information with template of origin.

Rapid nucleic acid libraries, methods of generation, kits, and compositions relating to library synthesis, including reagents, intermediaries and final products are disclosed herein. The disclosure enables rapid synthesis of libraries that allow independent verification of sequence information and rapid identification of sequence information with template of origin.

The present invention provides a method for sequencing a nucleic acid using an immersion reaction protocol. The immersion reaction protocol comprises sequentially immersing a solid support having nucleic acid molecules immobilized thereon in different reaction containers to realize nucleic acid sequencing.

FIG. 1 is published together with the abstract

The present invention provides a method for sequencing a nucleic acid using an immersion reaction protocol. The immersion reaction protocol comprises sequentially immersing a solid support having nucleic acid molecules immobilized thereon in different reaction containers to realize nucleic acid sequencing.

FIG. 1 is published together with the abstract

The present invention relates to method for preparing an RNA or DNA sample for a target specific next generation sequencing comprising performing a one-step target enrichment in a single reaction vessel or in a single reaction mixture, as well as a kit for preparing an RNA or DNA sample for next generation sequencing in a one-step target enrichment. Further envisaged is the use of the method or the kit for a rapid virus detection, a rapid leukocyte antigen-associated gene identification or a rapid blood group associated gene identification.