The invention provides a method for determining copy number variations (CNV) of a sequence of interest in a test sample that comprises a mixture of nucleic acids that are known or are suspected to differ in the amount of one or more sequence of interest. The method comprises a statistical approach that accounts for accrued variability stemming from process-related, interchromosomal and inter-sequencing variability. The method is applicable to determining CNV of any fetal aneuploidy, and CNVs known or suspected to be associated with a variety of medical conditions. CNV that can be determined according to the method include trisomies and monosomies of any one or more of chromosomes 1-22, X and Y, other chromosomal polysomies, and deletions and/or duplications of segments of any one or more of the chromosomes, which can be detected by sequencing only once the nucleic acids of a test sample.

This disclosure provides methods for determining relative abundance of one or more non-host species in a sample from a host. Also provided are methods involving addition of known concentrations of synthetic nucleic acids to a sample and performing sequencing assays to identify non-host species such as pathogens. Also provided are methods of tracking samples, tracking reagents, and tracking diversity loss in sequencing assays.

This disclosure provides methods for determining relative abundance of one or more non-host species in a sample from a host. Also provided are methods involving addition of known concentrations of synthetic nucleic acids to a sample and performing sequencing assays to identify non-host species such as pathogens. Also provided are methods of tracking samples, tracking reagents, and tracking diversity loss in sequencing assays.

Described herein are kits and methods for quantifying the amount of at least one nucleic acid of interest in a sample. The kits include a mixture of synthetic spike-in internal standards (IS) reagents, where the spike-in IS reagents comprise a complexity calibration ladder (CCL) that includes synthetic internal standard competitors for at least one target gene.

Described herein are kits and methods for quantifying the amount of at least one nucleic acid of interest in a sample. The kits include a mixture of synthetic spike-in internal standards (IS) reagents, where the spike-in IS reagents comprise a complexity calibration ladder (CCL) that includes synthetic internal standard competitors for at least one target gene.

A nucleic acid or peptide detection system that includes a carrier with at least two areas is provided. A method and kit that use and/or include the nucleic acid peptide detection system are also provided.

A nucleic acid or peptide detection system that includes a carrier with at least two areas is provided. A method and kit that use and/or include the nucleic acid peptide detection system are also provided.

The present invention relates to a method to determine bisulfite conversion of unmethylated cytosine to uracil in genomic DNA, comprising the steps of providing a first set of amplification primers for amplifying bisulfite converted copies of a repetitive DNA element by qPCR and a second set of amplification primers for amplifying unconverted copies of said repetitive DNA element by qPCR, performing a multiplex qPCR with said first and second set of amplification primers to generate amplicons, and determining the bisulfite conversion efficiency by comparing the amounts of said first and second amplicon.

The present invention relates to a method to determine bisulfite conversion of unmethylated cytosine to uracil in genomic DNA, comprising the steps of providing a first set of amplification primers for amplifying bisulfite converted copies of a repetitive DNA element by qPCR and a second set of amplification primers for amplifying unconverted copies of said repetitive DNA element by qPCR, performing a multiplex qPCR with said first and second set of amplification primers to generate amplicons, and determining the bisulfite conversion efficiency by comparing the amounts of said first and second amplicon.

This disclosure provides methods and systems for single-extracellular (EV), multi-omic analysis of target EVs without microfluidic devices. The disclosed methods involve the use of template particles to template the formation of monodisperse droplets to generally capture a single target EV from a population of EVs in an encapsulation, derive a plurality of distinct mRNA molecules from the single target EV, and quantify the distinct mRNA molecules to generate an expression profile. Nucleic-acid-tagged antibody conjugates are used for simultaneous proteomic analysis along with the gene expression profiling, which enables classification of an EV in a sample.