Abstract: This disclosure provides methods and compositions for tagging long fragments of a target nucleic acid for sequencing and analyzing the resulting sequence information in order to reduce errors and perform haplotype phasing, for example.

Abstract: The present invention is directed to methods and compositions for acquiring nucleotide sequence information of target sequences. In particular, the present invention provides methods and compositions for improving the efficiency of sequencing reactions by using fewer labels to distinguish between nucleotides and by detecting nucleotides at multiple detection positions in a target sequence.

Abstract: The invention provides methods and kits for ordering sequence information derived from one or more target polynucleotides. In one aspect, one or more tiers or levels of fragmentation and aliquoting are generated, after which sequence information is obtained from fragments in a final level or tier. Each fragment in such final tier is from a particular aliquot, which, in turn, is from a particular aliquot of a prior tier, and so on. For every fragment of an aliquot in the final tier, the aliquots from which it was derived at every prior tier is known, or can be discerned. Thus, identical sequences from overlapping fragments from different aliquots can be distinguished and grouped as being derived from the same or different fragments from prior tiers. When the fragments in the final tier are sequenced, overlapping sequence regions of fragments in different aliquots are used to register the fragments so that non-overlapping regions are ordered.

Abstract: Methods, systems, and apparatuses are provided for creating and using a machine-leaning model to call a base at a position of a nucleic acid based on intensity values measured during a production sequencing run. The model can be trained using training data from training sequencing runs performed earlier. The model is trained using intensity values and assumed sequences that are determined as the correct output. The training data can be filtered to improve accuracy. The training data can be selected in a specific manner to be representative of the type of organism to be sequenced. The model can be trained to use intensity signals from multiple cycles and from neighboring nucleic acids to improve accuracy in the base calls.

Abstract: Provided herein are compositions, methods, and kits for enriching for one or more nucleic acid sequences of interest in a sample. The methods include providing a circular ligase, one or more 5? hook probes and/or one or more 3? hook probes and contacting the sample comprising the nucleic acids with the circular ligase and one or more 5? hook probes and/or one or more 3? hook probes under conditions to allow the hook probes to selectively bind to the one or more nucleic acid sequences of interest, and under conditions to form one or more hook products, each hook product comprising the hook probes and the one or more nucleic acid sequences of interest.

Abstract: This disclosure provides methods and compositions for tagging long fragments of a target nucleic acid for sequencing and analyzing the resulting sequence information in order to reduce errors and perform haplotype phasing, for example.

Abstract: A scalable reaction and detection system for automated high throughput sequencing of nucleic acids involving a combination of chemical processes and observation processes independent of the chemistry processes. Discrete functional units may be configured in a manner that allows the system to interchangeably utilize different sequencing reaction components in conjunction with discrete apparatus components for optical image collection and/or analysis.

Abstract: Embodiments of the invention provide an improved biosensor for biological or chemical analysis. According to embodiments of the invention, backside illumination (BSI) complementary metal-oxide-semiconductor (CMOS) image sensors can be used to effectively analyze and measure fluorescence or chemiluminescence of a sample. This measured value can be used to help identify a sample. Embodiments of the invention also provide methods of manufacturing an improved biosensor for biological or chemical analysis and systems and methods of DNA sequencing.

Abstract: A high density DNA array comprising a patterned surface, said surface comprising a pattern of small DNA binding regions separated by a non-DNA binding surface, wherein the DNA binding regions comprise DNA capture chemistry and the non-DNA binding surface does not have the DNA capture chemistry wherein more than 50% of the DNA binding regions in the array have single informative DNA species.

Abstract: An imaging system is provided wherein a positioning stage is translated with respect to an objective lens component and a scan mirror is repositioned while a two-dimensional image is made of a biochemical site on a substrate. In an example embodiment, an imaging system comprises a camera, an objective lens component, a positioning stage, and a scan mirror controllable by a servo system that synchronizes movement of the positioning stage and the tilting of the scan mirror so that the substrate image is maintained stable during imaging of the continuously moving positioning stage.

Abstract: An array chip design is provided where the chip includes a field region arranged with sites according to a first pitch and at least one track region having a one-dimensional site pattern arranged according to a second pitch that is less dense and is an integer multiple of the first pitch so that observation through pixel-based sensors using one-dimensional quad-cell averaging can be applied in the track region, thereby to attain alignment of the chip to pixel-based optical instrumentation with a higher density of sites.

Abstract: The present invention provides methods of making and using self-assembled arrays of single polynucleotide molecules for carrying out a variety of large-scale genetic measurements, such as gene expression analysis, gene copy number assessment, and the like. Random arrays used in the invention are “self-assembled” in the sense that they are formed by deposition of polynucleotide molecules onto a surface where they become fixed at random locations. The polynucleotide molecules fixed on the surface are then identified by direct sequence determination of component nucleic acids, such as incorporated probe sequences, or by other decoding schemes. Such identification converts a random array of determinable polynucleotides, and their respective probes into an addressable array of probe sequences.

Abstract: The present invention is related generally to analysis of polynucleotides, particularly polynucleotides derived from genomic DNA. The invention provides methods, compositions and systems for such analysis. Encompassed by the invention are arrays of polynucleotides in which the polynucleotides have undergone multiple rounds of amplification in order to increase the strength of signals associated with single polynucleotide molecules.

Abstract: Biochemical flow cells having sealed inlets and outlets are provided for performing high-volume assays on macromolecules. In one example embodiment, a flow cell with detachable inlet and outlet connectors comprises an inlet manifold, a coverslip, and a substrate disposed below the coverslip to form a reaction chamber, where the substrate is disposed to partially cover the inlet manifold such that a slit is formed along an entire edge of the substrate where fluids can flow from the inlet manifold through the slit, around substantially the entire edge of the substrate, and into the reaction chamber at equalized pressure and without bubbles.

Abstract: The present invention is directed to methods and compositions for acquiring nucleotide sequence information of target sequences. In particular, the present invention provides methods and compositions for improving the efficiency of sequencing reactions by using fewer labels to distinguish between nucleotides and by detecting nucleotides at multiple detection positions in a target sequence.

Abstract: An imaging system is provided wherein a positioning stage is translated with respect to an objective lens component and a scan mirror is repositioned while a two-dimensional image is made of a biochemical site on a substrate. In an example embodiment, an imaging system comprises a camera, an objective lens component, a positioning stage, and a scan mirror controllable by a servo system that synchronizes movement of the positioning stage and the tilting of the scan mirror so that the substrate image is maintained stable during imaging of the continuously moving positioning stage.

Abstract: An array chip useful for biochemical assays is provided wherein the chip includes a field region arranged with attachment sites according to a first pitch and at least one track region having a one-dimensional spot pattern arranged according to a second pitch that is less dense and is a non-integer multiple of the first pitch so that one-dimensional Moiré averaging may be applied in the track region, thereby to attain alignment of the chip to the optical instrumentation with a higher density of attachment sites.

Abstract: Nucleoside analogues and methods of using such nucleoside analogues for sequencing of nucleic acids are provided.

Abstract: The present invention is directed to methods and compositions for acquiring nucleotide sequence information of target sequences using adaptors interspersed in target polynucleotides. The sequence information can be new, e.g. sequencing unknown nucleic acids, re-sequencing, or genotyping. The invention preferably includes methods for inserting a plurality of adaptors at spaced locations within a target polynucleotide or a fragment of a polynucleotide. Such adaptors may serve as platforms for interrogating adjacent sequences using various sequencing chemistries, such as those that identify nucleotides by primer extension, probe ligation, and the like. Encompassed in the invention are methods and compositions for the insertion of known adaptor sequences into target sequences, such that there is an interruption of contiguous target sequence with the adaptors. By sequencing both “upstream” and “downstream” of the adaptors, identification of entire target sequences may be accomplished.

Abstract: The invention relates to an automated method for high-throughput DNA sequencing from high density DNA arrays by (a) initiating a first sequencing reaction on a first high density DNA array; and imaging said first high density DNA array using a detector, and (b) initiating a first sequencing reaction on a second high density DNA array; and imaging said second high density DNA array using the detector, wherein the first sequencing reaction in (a) is initiated before the first sequencing reaction in (b) is initiated such that the sequencing reactions in (a) and (b) are staggered. By using asynchronous sequencing reactions and imaging two separate arrays using one detector, imaging can be carried out on one array while sequencing reactions are carried out on one the other, substrate, the other substrate is imaged, reducing the idle time of the imaging system.