The invention relates to methods for the preparation of method of preparation of cDNA library based on one or many RNA samples useful for efficient RNA sequencing and uses thereof. The invention further relates to related tools and kits useful in said method.

The invention relates to methods for the preparation of method of preparation of cDNA library based on one or many RNA samples useful for efficient RNA sequencing and uses thereof. The invention further relates to related tools and kits useful in said method.

This disclosure provides methods and compositions for analyzing nucleic acids such as DNA and RNA, and including determination of absolute numbers of such nucleic acids and/or detection and localization of lesions or other modifications on such nucleic acids.

This disclosure provides methods and compositions for analyzing nucleic acids such as DNA and RNA, and including determination of absolute numbers of such nucleic acids and/or detection and localization of lesions or other modifications on such nucleic acids.

High-fidelity, high-throughput nucleic acid sequencing enables healthcare practitioners and patients to gain insight into genetic variants and potential health risks. However, previous methods of nucleic acid sequencing often introduce sequencing errors (for example, mutations that arise during the preparation of a nucleic acid library, during amplification, or sequencing). Provided herein are methods and compositions for sequencing nucleic acids. Further provided are methods of identifying an error in a nucleic acid sequence.

High-fidelity, high-throughput nucleic acid sequencing enables healthcare practitioners and patients to gain insight into genetic variants and potential health risks. However, previous methods of nucleic acid sequencing often introduce sequencing errors (for example, mutations that arise during the preparation of a nucleic acid library, during amplification, or sequencing). Provided herein are methods and compositions for sequencing nucleic acids. Further provided are methods of identifying an error in a nucleic acid sequence.

Systems, methods, and apparatus for determining a fractional concentration of fetal DNA in a biological sample are provided. The biological sample may be enriched for nucleic acid molecules in a target region. A plurality of nucleic acid molecules from the enriched biological sample may be sequenced specific to the target region. One or more first loci may be determined. The fetal genome is heterozygous at each first loci such that the fetal genome has a respective first and second allele at that first loci. The maternal genome is homozygous at each first loci such that the maternal genome. For at least one of the first loci, a first number of counts of the respective first allele and a second number of counts of the respective second allele may be determined. The fractional concentration may be determined based on the first and second numbers.

Systems, methods, and apparatus for determining a fractional concentration of fetal DNA in a biological sample are provided. The biological sample may be enriched for nucleic acid molecules in a target region. A plurality of nucleic acid molecules from the enriched biological sample may be sequenced specific to the target region. One or more first loci may be determined. The fetal genome is heterozygous at each first loci such that the fetal genome has a respective first and second allele at that first loci. The maternal genome is homozygous at each first loci such that the maternal genome. For at least one of the first loci, a first number of counts of the respective first allele and a second number of counts of the respective second allele may be determined. The fractional concentration may be determined based on the first and second numbers.

This invention provides a process for sequencing nucleic acids using 3′ modified deoxynucleotide analogues or 3′ modified deoxyinosine triphosphate analogues, and 3′ modified dideoxynucleotide analogues having a detectable marker attached thereto.

Provided herein are compositions and methods for accurate and scalable Primary Template-Directed Amplification (PTA) nucleic acid amplification and sequencing methods, and their applications for mutational analysis in research, diagnostics, and treatment. Such methods and compositions facilitate highly accurate amplification of target (or “template”) nucleic acids, which increases accuracy and sensitivity of downstream applications, such as Next-Generation Sequencing.