Abstract: The present technology relates generally to methods and compositions for targeted nucleic acid sequence enrichment, as well as uses of such enrichment for error-corrected nucleic acid sequencing applications. In some embodiments, highly accurate, error corrected and massively parallel sequencing of nucleic acid material is possible using a combination of uniquely labeled strands in a double-stranded nucleic acid complex in such a way that each strand can be informatically related to its complementary strand, but also distinguished from it following sequencing of each strand or an amplified product derived therefrom. In various embodiments, this information can be used for the purpose of error correction of the determined sequence.

Abstract: The present technology relates generally to methods and compositions for targeted nucleic acid sequence enrichment, as well as uses of such enrichment for error-corrected nucleic acid sequencing applications. In some embodiments, highly accurate, error corrected and massively parallel sequencing of nucleic acid material is possible using a combination of uniquely labeled strands in a double-stranded nucleic acid complex in such a way that each strand can be informatically related to its complementary strand, but also distinguished from it following sequencing of each strand or an amplified product derived therefrom. In various embodiments, this information can be used for the purpose of error correction of the determined sequence.

Abstract: The present technology relates generally to methods and compositions for targeted nucleic acid sequence enrichment, as well as uses of such enrichment for error-corrected nucleic acid sequencing applications. In some embodiments, highly accurate, error corrected and massively parallel sequencing of nucleic acid material is possible using a combination of uniquely labeled strands in a double-stranded nucleic acid complex in such a way that each strand can be informatically related to its complementary strand, but also distinguished from it following sequencing of each strand or an amplified product derived therefrom. In various embodiments, this information can be used for the purpose of error correction of the determined sequence.

Abstract: The invention provides a method for the genetic analysis of biological samples after generation and expansion of subsets representing their nucleic acids. Each subset contains a characteristic but arbitrarily selected representation. Different subsets display complementary representations. The method is specially suitable for the study of gene expression profiles.