Abstract: Data extracted from fluorosphore responses of fluorophore labeled bases in genetic material used in sequencing of unknown fragments from a defined set of for example a model system are converted into a class of block codes that are then employed in a computer-based process to compare and correct preliminary calls of calls of the categorically known genetic material. In a specific embodiment, the Reed-Solomon codes are employed to identify one or more errors as may occur in a finite block of codes. The methodology is also useful to identify elements of a real system containing known elements in the form of a tag. Reed-Solomon sensors may be employed with and in addition to other types of genome sensors.

Abstract: The present invention provides methods and compositions for sequencing small amounts of complex nucleic acids such as human genomes and for analyzing the resulting sequence information in order to reduce sequencing errors and perform haplotype phasing, for example.

Abstract: Methods are provided for efficient shotgun sequencing to allow efficient selection and sequencing of nucleic acids of interest contained in a library. The nucleic acids of interest can be defined any time before or after preparation of the library. One example of nucleic acids of interest is missing or low confidence genome sequences resulting from an initial sequencing procedure. Other nucleic acids of interest include subsets of genomic DNA, RNA or cDNAs (exons, genes, gene sets, transciptomes).

Abstract: Sequencing information is used to correlate alleles at certain locations to alleles at other locations. The statistical information from the reads of fragments in a sample can be used to determine the phasing of haplotypes and to correct or confirm based calls at the locations. In one example, a confidence value (strength score) is determined for a particular hypothesis, which can include whether two alleles are on a same haplotype at two particular loci, as well as what the alleles are on another haplotype (e.g. for a diploid organism). The strength can include a positive contribution from data that is consistent with the hypothesis and a negative contribution from data is that inconsistent with the hypothesis, where both values can be used in a formula to determine the strength.

Abstract: Haplotypes of one or more portions of a chromosome of an organism from sequencing information of DNA or RNA fragments can be determined. Heterozygous loci (hets) can be used to determine haplotypes. One allele on a first het can be connected (likely to be on the same haplotype) to an allele on a second het, thereby defining a particular orientation between the hets. Haplotypes can be assembled through these connections. Errors can be identified through redundant connection information, particularly using a confidence value (strength) for a particular connection. The connections among a set of hets can be analyzed to determine likely haplotypes for that set, e.g., an optimal tree of a graph containing the hets. Furthermore, haplotypes of different contiguous sections (contig) of the chromosome can be matched to a particular chromosome copy (e.g., to a particular parental copy). Thus, the phase of an entire chromosome can be determined.

Abstract: Methods are provided for efficient shotgun sequencing to allow efficient selection and sequencing of nucleic acids of interest contained in a library. The nucleic acids of interest can be defined any time before or after preparation of the library. One example of nucleic acids of interest is missing or low confidence genome sequences resulting from an initial sequencing procedure. Other nucleic acids of interest include subsets of genomic DNA, RNA or cDNAs (exons, genes, gene sets, transciptomes). By designing an efficient (simple to implement, speedy, high specificity, low cost) selection procedure, a more complete sequence is achieved with less effort than by using highly redundant shotgun sequencing in an initial sequencing procedure.

Abstract: Substrates are provided for use in the detection, identification and analysis of biologic or chemical samples that are labeled with a fluorescent label, in which the plane of maximum fluorescence is displaced from a reflective substrate surface so that the intensity maximum of the standing wave interference pattern of incident and reflected probe radiation is enhanced. The format of the substrates includes substantially planar surfaces as well as substrates with introduced variations to the substrate surface, e.g., depressions, wells, pedestals and the like, disposed in arrays or other similar structures such that one or more fluorophore-comprising objects can be attached thereto.

Abstract: The invention relates to methods and devices for analyzing single molecules, i.e. nucleic acids. Such single molecules may be derived from natural samples, such as cells, tissues, soil, air and water without separating or enriching individual components. In certain aspects of the invention, the methods and devices are useful in performing nucleic acid sequence analysis by probe hybridization.

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: A method and associated system for imaging high density biochemical arrays comprises one or more imaging channels that share a common objective lens and a corresponding one or more time delay integration-type imaging cameras with optical alignment mechanisms that permit independent inter-channel and intra-channel adjustment of each of four degrees: X, Y, rotation and scale. The imaging channels are configured to independently examine different spectra of the image of the biochemical arrays.

Abstract: Methods, apparatuses, and systems for identification of junctions (e.g., resulting from large-scale rearrangements) of a sequenced genome with respect to a human genome reference sequence is provided. For example, false positives can be distinguished from actual junctions. Such false positives can result from many sources, including mismapping, chimeric reactions among the DNA of a sample, and problems with the reference genome. As part of the filtering processes, a base pair resolution (or near base pair resolution) of a junction can be provided. In various implementations, junctions can be identified using discordant mate pairs and/or using a statistical analysis of the length distributions of fragments for local regions of the sample genome. Clinically significant junctions can also be identified so that further analysis can be focused on genomic regions that may have more of an impact on the health of a patient.

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: Methods are provided for carrying out nucleic acid analysis, including sequence identification, employing voltage and/or controlled electric charge to enhance operation. A device comprises substrates for nucleic acid analysis, a first electrically conductive layer, a first electrically insulative layer of dielectric material on the first conductive layer, a second electrically conductive layer disposed upon the first insulative layer in a pattern to define discrete attachment sites for macromolecules on the first insulative layer, the second conductive layer provided with means for resisting affinity for the macromolecules to impede their attachment to sites on the second conductive layer, and terminals for the first and second conductive layers for applying a voltage pattern between the first and the second conductive layers to control affinity between the macromolecules and the discrete attachment sites.

Abstract: Aspects described and claimed herein provide methods to insert multiple DNA adaptors into a population of circular target DNAs at defined positions and orientations with respect to one another. The resulting multi-adaptor constructs are then used in massively-parallel nucleic acid sequencing techniques.

Abstract: A system and associated method for imaging high density biochemical arrays comprises one or more imaging channels that share a common objective lens and a corresponding one or more time delay integration-type imaging cameras with optical alignment mechanisms that permit independent inter-channel and intra-channel adjustment of each of four degrees: X, Y, rotation and scale. The imaging channels are configured to independently examine different spectra of the image of the biochemical arrays.

Abstract: The present invention is directed to compositions and methods for nucleic acid identification and detection. Compositions and methods of the present invention include extracting and fragmenting target nucleic acids from a sample, using the fragmented target nucleic acids to produce target nucleic acid templates and subjecting those target nucleic acid templates to amplification methods to form nucleic acid nanoballs. The invention also includes methods of detecting and identifying sequences using various sequencing applications, including sequencing by ligation methods.

Abstract: A system and associated method for imaging high density biochemical arrays comprises one or more imaging channels that share a common objective lens and a corresponding one or more time delay integration-type imaging cameras with optical alignment mechanisms that permit independent inter-channel and intra-channel adjustment of each of four degrees: X, Y, rotation and scale. The imaging channels are configured to independently examine different spectra of the image of the biochemical arrays.

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: Assay flow cells used as part of an overall system for biological assays include, in various configurations, a carrier in which an assay substrate may be provided, where a substantial portion of the assay substrate can be used for biochemical analysis, since the carrier component of the flow cell is designed to provide functionalities that in prior art systems were performed by the assay substrate itself The flow cells may be used in automated systems, are flat for imaging and various configurations of the components of the flow cells minimize evaporation, yet allow for precise control of fluid intake and evacuation.

Abstract: Assay flow cells used as part of an overall system for biological assays include, in various configurations, a carrier in which an assay substrate may be provided, where a substantial portion of the assay substrate can be used for biochemical analysis, since the carrier component of the flow cell is designed to provide functionalities that in prior art systems were performed by the assay substrate itself The flow cells may be used in automated systems, are flat for imaging and various configurations of the components of the flow cells minimize evaporation, yet allow for precise control of fluid intake and evacuation.