Methods and devices are provided herein for surfaces for de novo nucleic acid synthesis which provide for low error rates. In addition, methods and devices are provided herein for increased nucleic acid mass yield resulting from de novo nucleic acid synthesis.

Methods and devices are provided herein for surfaces for de novo nucleic acid synthesis which provide for low error rates. In addition, methods and devices are provided herein for increased nucleic acid mass yield resulting from de novo nucleic acid synthesis.

Disclosed herein is a system and method for increasing the fidelity of measured genetic data, for making allele calls, and for determining the state of aneuploidy, in one or a small set of cells, or from fragmentary DNA, where a limited quantity of genetic data is available. Poorly or incorrectly measured base pairs, missing alleles and missing regions are reconstructed using expected similarities between the target genome and the genome of genetically related individuals. In accordance with one embodiment, incomplete genetic data from an embryonic cell are reconstructed at a plurality of loci using the more complete genetic data from a larger sample of diploid cells from one or both parents, with or without haploid genetic data from one or both parents. In another embodiment, the chromosome copy number can be determined from the measured genetic data, with or without genetic information from one or both parents.

The present invention provides a method for sequencing a nucleic acid using an immersion reaction protocol. The immersion reaction protocol comprises sequentially immersing a solid support having nucleic acid molecules immobilized thereon in different reaction containers to realize nucleic acid sequencing.

The present invention provides a method for sequencing a nucleic acid using an immersion reaction protocol. The immersion reaction protocol comprises sequentially immersing a solid support having nucleic acid molecules immobilized thereon in different reaction containers to realize nucleic acid sequencing.

The present disclosure relates, in part, to improved methods of making single-stranded DNA (ssDNA) from double-stranded DNA (dsDNA), as well as use of the resulting ssDNA for genome engineering. The disclosure also relates, in part, to improved methods of genetic modification using single stranded DNA binding proteins.

The present disclosure relates, in part, to improved methods of making single-stranded DNA (ssDNA) from double-stranded DNA (dsDNA), as well as use of the resulting ssDNA for genome engineering. The disclosure also relates, in part, to improved methods of genetic modification using single stranded DNA binding proteins.

The invention provides various orthogonal nucleotide analogues and methods for using combinations of said various orthogonal nucleotide analogues for sequencing by synthesis.

The invention provides various orthogonal nucleotide analogues and methods for using combinations of said various orthogonal nucleotide analogues for sequencing by synthesis.

The present invention may provide a small RNA detection sensor comprising: at one end thereof, a first sensing region comprising nucleotides having a sequence complementary to target small RNA; and a PCR-capable region that is coupled to the first sensing region, the small RNA detection sensor to synthesize a replication region complementary to the PCR-capable region by a DNA polymerase by using the target small RNA as a primer, and amplify the PCR-capable region and the replication region.