Provided herein are methods and systems for detection of nucleic acids for single cell samples. As part of the detection, a unique step of normalization of different single cell samples is included. One embodiment of the method includes i) selecting one or more target nucleic acid sequence of interest in an individual cell, where the target nucleic acid sequence is complementary to a nucleic acid in a cell; ii) providing a sample having a plurality of individual single cells and encapsulating one or more individual cell(s); iii) providing a sample normalization component to one or more encapsulated cell, where the normalization component comprises an exogenous nucleic acid having a known sequence; iv) providing nucleic acid primers for the target nucleic acid and the exogenous nucleic acid; v) providing a protease to each encapsulated cell and incubating the encapsulated cell with the protease in the drop to produce a cell lysate; vi) performing a nucleic acid amplification reaction to form an amplification product from the nucleic acid of a single cell, where the amplification product comprise amplicons of one or more target nucleic acid sequence and an amplicon for the exogenous nucleic acid; and vii) comparing the amplification products from the target amplicons and the exogenous nucleic acid amplicons and determining the copy number or sequence of the target nucleic acid in a single cell.

An object of the present invention is to provide methods for amplifying and detecting a nucleic acid that allow efficient hybridization, and devices and kits for use in the methods. The present invention includes amplifying a target nucleic acid into a double-stranded nucleic acid having a single-stranded region at each end, and detecting this nucleic acid. The present invention also provides detection devices and kits that make use of these methods.

An object of the present invention is to provide methods for amplifying and detecting a nucleic acid that allow efficient hybridization, and devices and kits for use in the methods. The present invention includes amplifying a target nucleic acid into a double-stranded nucleic acid having a single-stranded region at each end, and detecting this nucleic acid. The present invention also provides detection devices and kits that make use of these methods.

This disclosure relates to a circulating tumour cell typing and identification kit, comprising a capture probe, an amplification probe, and a labeled probe for each marker gene mRNA, wherein the marker gene mRNA comprises the following two types: at least two epithelial cell marker gene mRNAs selected from the group consisting of EPCAM, E-cadherin, CEA, KRT5, KRT7, KRT17, and KRT20 mRNAs; and, at least two mesenchymal cell marker gene mRNAs selected from the group consisting of VIMENTIN, N-cadherin, TWIST1, AKT2, ZEB2, ZEB1, FOXC1, FOXC2, SNAI1 and SNAI2 mRNAs. This disclosure prevents false-positive results caused by, for example, possible presence of a number of non-neoplastic epithelial cells in peripheral blood, introduction of normal epithelial cells during blood sampling, and the like. Accordingly, it may be assured that cells detected with epithelial cell marker genes and/or mesenchymal cell marker genes are indeed circulating tumour cells, further improving accuracy and reliability of the detection results.

This disclosure relates to a circulating tumour cell typing and identification kit, comprising a capture probe, an amplification probe, and a labeled probe for each marker gene mRNA, wherein the marker gene mRNA comprises the following two types: at least two epithelial cell marker gene mRNAs selected from the group consisting of EPCAM, E-cadherin, CEA, KRT5, KRT7, KRT17, and KRT20 mRNAs; and, at least two mesenchymal cell marker gene mRNAs selected from the group consisting of VIMENTIN, N-cadherin, TWIST1, AKT2, ZEB2, ZEB1, FOXC1, FOXC2, SNAI1 and SNAI2 mRNAs. This disclosure prevents false-positive results caused by, for example, possible presence of a number of non-neoplastic epithelial cells in peripheral blood, introduction of normal epithelial cells during blood sampling, and the like. Accordingly, it may be assured that cells detected with epithelial cell marker genes and/or mesenchymal cell marker genes are indeed circulating tumour cells, further improving accuracy and reliability of the detection results.

Disclosed are compositions and a method relating to amplifying and detecting nucleic acids.

Disclosed are compositions and a method relating to amplifying and detecting nucleic acids.

The present invention is directed to methods and compositions for generating a pool of oligonucleotides. The invention finds use in preparing a population or subpopulations of oligonucleotides in solution. The pool of oligonucleotides finds use in a variety of nucleic acid detection and/or amplification assays.

The present invention is directed to methods and compositions for generating a pool of oligonucleotides. The invention finds use in preparing a population or subpopulations of oligonucleotides in solution. The pool of oligonucleotides finds use in a variety of nucleic acid detection and/or amplification assays.

The present invention provides compositions, apparatuses and methods for detecting one or more nucleic acid targets present in a sample. Methods of the invention include utilizing two or more ligation probes that reversibly bind a target nucleic acid in close proximity to each other and possess complementary reactive ligation moieties. When such probes have bound to the target in the proper orientation, they are able to undergo a spontaneous chemical ligation reaction that yields a ligation product that is directly detected or that is amplified to produce amplicons that are then detected. The present invention also provides methods to stabilize sample RNA so that degradation does not significantly affect the results of the analysis.