A method for sequencing a polynucleotide sample having a barcode sequence, includes: introducing a series of nucleotides to the polynucleotide sample according to a predetermined flow ordering; obtaining a series of signals resulting from the introducing of nucleotides to the polynucleotide sample; and resolving the series of signals over the barcode sequence to render a flowspace string, wherein the flowspace string is a codeword of an error-tolerant code capable of distinguishing the barcode sequence from other barcode sequences in the presence of one or more errors.

This disclosure provides methods for preparing a sequencing library including the steps of providing a template nucleic acid sequence, dNTPs, dUTP, a primer, a polymerase, a dUTP excising enzyme, and a plurality of beads including oligonucleotide adapter sequence segments; amplifying the template nucleic acid with the polymerase, dNTPs, dUTP and random hexamer to provide a complementary nucleic acid sequence including occasional dUTPs; and excising the incorporated dUTPs with the dUTP excising enzyme to provide nicks in the complementary nucleic acid sequence to provide a sequencing library.

A kit for use with a nucleic acid sequencing instrument can include a plurality of combinatorial barcodes sequences meeting the following criteria: each of the combinatorial barcode sequences comprise a plurality of iterations of a sequence motif, where the sequence motif comprises a first nucleotide base from a first group of nucleotide bases followed by a second nucleotide base from a second group of nucleotide bases, the first group and the second group differing from each other; and the plurality of combinatorial barcode sequences is at least 1,000,000 different barcode sequences.

This disclosure provides methods for preparing a sequencing library including the steps of providing a template nucleic acid sequence, dNTPs, dUTP, a primer, a polymerase, a dUTP excising enzyme, and a plurality of beads including oligonucleotide adapter sequence segments; amplifying the template nucleic acid with the polymerase, dNTPs, dUTP and random hexamer to provide a complementary nucleic acid sequence including occasional dUTPs; and excising the incorporated dUTPs with the dUTP excising enzyme to provide nicks in the complementary nucleic acid sequence to provide a sequencing library.

A method for sequencing a polynucleotide sample having a barcode sequence includes: introducing a series of nucleotides to the polynucleotide sample according to a predetermined order of nucleotide flows; obtaining a series of signals resulting from the introducing of nucleotides to the polynucleotide sample; and resolving the series of signals over the barcode sequence to render a flowspace string, wherein the flowspace string is a codeword of an error-correcting code that is (i) designed based on and adapted for use with the predetermined order of nucleotide flows, and (ii) capable of distinguishing any codeword in the error-correcting code from the other codewords in the error-correcting code in the presence of zero, one, and two errors.

Provided herein, in some embodiments, are devices, systems and methods for high-throughput single-cell polyomics (e.g., genomic, epigenomic, proteomic and/or phenotypic profile) analyses.

Apparatuses, compositions and processes for DNA barcode deconvolution are described herein. A DNA barcode may be used to provide a bead specific identifier, which may be detected in situ using hybridization strategies. The DNA barcode provides identification by sequencing analysis. The dual mode of detection may be used in a wide variety of applications to link positional information with assay information including but not limited to genetic analysis. Methods are described for generation of barcoded single cell sequencing libraries. Isolation of nucleic acids from a single cell within a microfluidic environment can provide the foundation for cell specific sequencing library preparation.

Provided herein are monoliths with attached recognition compounds which selectively bind ligands, methods of preparing such monoliths, arrays thereof and uses thereof. For example, monoliths provided herein can be used in columns and arrays thereof.

Molecular identity tags and methods of marking target nucleic acids with molecular identity tags for identifying intermolecular ligation products. Terminal regions of linear target nucleic acids are marked with pairs of distinguishable molecular identity tags. Each linear target nucleic acid is marked with only one distinguishable pair. The terminal ends of the marked target nucleic acids are joined to generate circularized nucleic acids, thereby juxtaposing two molecular identity tags across the joined terminal ends. Circularized nucleic acids or downstream products thereof comprising juxtaposed unpaired molecular identity tags constitute intermolecular nucleic acid products that can be identified and eliminated from subsequent analyses of the nucleic acids. The molecular identity tags may comprise physically linked and non-physically linked pairs. Physically linked molecular identity tags designed for production and analysis of mate-pair libraries with next-generation sequencing platforms are provided.

Provided herein are monoliths with attached recognition compounds which selectively bind ligands, methods of preparing such monoliths, arrays thereof and uses thereof. For example, monoliths provide herein can be used in columns and arrays thereof.