A nucleic acid (NA) detection method combines ultra-specific probe, on-chip isotachophoresis (ITP) which can separate single strand and double strand NAs, and enzyme amplification. The ITP device has a sieving matrix between the LE (leading electrolyte) and TE (trailing electrolyte) reservoirs, for separating double-strand and single-strand NAs. The LE or TE reservoir also contains a spacer ion having a mobility between the LE and the TE. The sample and a double-strand NA probe is added to the TE reservoir, the probe being formed of a protector strand modified with a fluorescent molecule and a complement strand, where the protector strand is released in the presence of the target NA. Fluorescent signal is detected downstream of the sieving matrix. Alternatively, the protector strand is modified with an enzyme and a single-strand NA modified with a substrate of the enzyme is added to the reaction mixture downstream of the sieving matrix.

A nucleic acid (NA) detection method combines ultra-specific probe, on-chip isotachophoresis (ITP) which can separate single strand and double strand NAs, and enzyme amplification. The ITP device has a sieving matrix between the LE (leading electrolyte) and TE (trailing electrolyte) reservoirs, for separating double-strand and single-strand NAs. The LE or TE reservoir also contains a spacer ion having a mobility between the LE and the TE. The sample and a double-strand NA probe is added to the TE reservoir, the probe being formed of a protector strand modified with a fluorescent molecule and a complement strand, where the protector strand is released in the presence of the target NA. Fluorescent signal is detected downstream of the sieving matrix. Alternatively, the protector strand is modified with an enzyme and a single-strand NA modified with a substrate of the enzyme is added to the reaction mixture downstream of the sieving matrix.

The present disclosure relates to methods of enzymatic treatment of double-stranded PCR amplified products for eliminating or minimizing primer-dimers in multiplex PCR reactions and for the efficient ligation of adapters. The present disclosure relates to methods and compositions that allow more efficient highly multiplex target amplification compared to conventional methods, compositions and kits by minimizing laboratory steps, eliminating primer-dimers and increasing the efficiency of adapter ligation. The disclosed methods use multiple target-specific primers for specific and selective amplification of targets in a subject's genome. The disclosed methods can be used for numerous downstream procedures and analysis, including DNA sequencing.

The present disclosure relates to methods of enzymatic treatment of double-stranded PCR amplified products for eliminating or minimizing primer-dimers in multiplex PCR reactions and for the efficient ligation of adapters. The present disclosure relates to methods and compositions that allow more efficient highly multiplex target amplification compared to conventional methods, compositions and kits by minimizing laboratory steps, eliminating primer-dimers and increasing the efficiency of adapter ligation. The disclosed methods use multiple target-specific primers for specific and selective amplification of targets in a subject's genome. The disclosed methods can be used for numerous downstream procedures and analysis, including DNA sequencing.

The method includes obtaining a sample including a target nucleic acid, contacting the sample with a quantification primer, adding a quantity of blocking primer to the sample, and repeating the contacting and adding steps until the total quantity of blocking primer present in the sample meets or exceeds the amount of target present in the sample. Each repetition utilizes a quantification primer having a different unique identifying feature assigned to sequentially increasing quantification levels, and the quantity of blocking primer added at each repetition establishes numerical spacing between the quantification levels. The method further includes identifying the unique identifying feature present in any bound quantification primers that remain in the sample, where the presence of a unique identifying feature assigned to a particular quantification level indicates the approximate amount of the target present in the sample.

The method includes obtaining a sample including a target nucleic acid, contacting the sample with a quantification primer, adding a quantity of blocking primer to the sample, and repeating the contacting and adding steps until the total quantity of blocking primer present in the sample meets or exceeds the amount of target present in the sample. Each repetition utilizes a quantification primer having a different unique identifying feature assigned to sequentially increasing quantification levels, and the quantity of blocking primer added at each repetition establishes numerical spacing between the quantification levels. The method further includes identifying the unique identifying feature present in any bound quantification primers that remain in the sample, where the presence of a unique identifying feature assigned to a particular quantification level indicates the approximate amount of the target present in the sample.

A nucleic acid sequence measuring method includes measuring fluorescence from the nucleic acid sequence measuring device supplied with a sample solution. The device includes a fluorescent probe added with a fluorescent molecule, and a quenching probe added with a quenching substance. The fluorescent probe and/or the quenching probe has a detection part detecting a predetermined nucleic acid sequence. Fluorescence from the fluorescent molecule is quenched by the quenching substance coupled with the fluorescent molecule when the hybridization between the detection target nucleic acid and the detection part has not occurred, and fluorescence is emitted from the fluorescent molecule separated from the quenching substance when the hybridization has occurred.

A nucleic acid sequence measuring method includes measuring fluorescence from the nucleic acid sequence measuring device supplied with a sample solution. The device includes a fluorescent probe added with a fluorescent molecule, and a quenching probe added with a quenching substance. The fluorescent probe and/or the quenching probe has a detection part detecting a predetermined nucleic acid sequence. Fluorescence from the fluorescent molecule is quenched by the quenching substance coupled with the fluorescent molecule when the hybridization between the detection target nucleic acid and the detection part has not occurred, and fluorescence is emitted from the fluorescent molecule separated from the quenching substance when the hybridization has occurred.

Probe systems and methods are provided for detecting nucleic acid targets using labeled polynucleotide probes and antiprobes that interact together and with complementary targets. These interactions result in signaling changes that indicate target frequency and provide error-checking functions that facilitate single base discrimination. These probe:antiprobe compositions enable real-time PCR detection, end-point detection and microarray detection of microbial species, drug resistant mutants, and cancer related variants. The probe:antiprobe may be an internal probe between two primers or may be a primer-probe. The probe also may be modified by introducing a base mismatch to increase thermodynamic discrimination of a correct versus incorrect target differing by a single base. Probe systems also are provided for use in methods of increasing target amplification and detecting specific single base variants.

Probe systems and methods are provided for detecting nucleic acid targets using labeled polynucleotide probes and antiprobes that interact together and with complementary targets. These interactions result in signaling changes that indicate target frequency and provide error-checking functions that facilitate single base discrimination. These probe:antiprobe compositions enable real-time PCR detection, end-point detection and microarray detection of microbial species, drug resistant mutants, and cancer related variants. The probe:antiprobe may be an internal probe between two primers or may be a primer-probe. The probe also may be modified by introducing a base mismatch to increase thermodynamic discrimination of a correct versus incorrect target differing by a single base. Probe systems also are provided for use in methods of increasing target amplification and detecting specific single base variants.