Disclosed is a probe for use in biological assays. The probe includes a fluorescent dye bound to a quencher compound through an oligonucleotide linker. Also disclosed are methods of using the probe, such as for a polymerase chain reaction (PCR), such as in a quantitative PCR reaction (qPCR), as well as kits including the probe.

Disclosed is a probe for use in biological assays. The probe includes a fluorescent dye bound to a quencher compound through an oligonucleotide linker. Also disclosed are methods of using the probe, such as for a polymerase chain reaction (PCR), such as in a quantitative PCR reaction (qPCR), as well as kits including the probe.

The invention relates to methods of detecting and/or quantifying analytes in a sample, as well as methods of detecting mutations and/or polymorphisms in nucleic acid molecules. The methods include: providing at least one carrier nucleic acid molecule comprising at least one single-stranded region; providing at least one detection element comprising: at least one fluorophore, at least one fluorescence quencher that quenches spectroscopic detection of the fluorophore; at least one analyte-binding moiety; and at least one nucleic acid moiety that binds to a single stranded region on the carrier nucleic acid molecule; wherein the detection element is configured such that in the absence of the analyte the fluorophore is quenched by the fluorescence quencher and upon analyte binding to the analyte-binding moiety fluorescence is restored; binding these with an analyte to form a complex; translocating the complex through a nanopore via voltage-driven translocation and monitoring time-dependent current response; irradiating the nanopore with radiation that excites the fluorophore and monitoring radiation emissions of the fluorophore over time; and comparing the signals from time-dependent current response and emission over time.

The invention relates to methods of detecting and/or quantifying analytes in a sample, as well as methods of detecting mutations and/or polymorphisms in nucleic acid molecules. The methods include: providing at least one carrier nucleic acid molecule comprising at least one single-stranded region; providing at least one detection element comprising: at least one fluorophore, at least one fluorescence quencher that quenches spectroscopic detection of the fluorophore; at least one analyte-binding moiety; and at least one nucleic acid moiety that binds to a single stranded region on the carrier nucleic acid molecule; wherein the detection element is configured such that in the absence of the analyte the fluorophore is quenched by the fluorescence quencher and upon analyte binding to the analyte-binding moiety fluorescence is restored; binding these with an analyte to form a complex; translocating the complex through a nanopore via voltage-driven translocation and monitoring time-dependent current response; irradiating the nanopore with radiation that excites the fluorophore and monitoring radiation emissions of the fluorophore over time; and comparing the signals from time-dependent current response and emission over time.

The present invention relates to the evaluation of the performance of a component using a pair of dimer-forming primers. The method using the pair of dimer-forming primers according to the present invention can be used not only for evaluating the performance of components including a nucleic acid polymerase but also as an internal control in the detection of a target nucleic acid sequence.

The present invention relates to the evaluation of the performance of a component using a pair of dimer-forming primers. The method using the pair of dimer-forming primers according to the present invention can be used not only for evaluating the performance of components including a nucleic acid polymerase but also as an internal control in the detection of a target nucleic acid sequence.

A method and system to decode information stored on a polymer sequence, such as a DNA strand, is described herein. The method and system use molecular probes to label sections of the polymer sequence. Each molecular probe includes a fluorophore and a quencher. The fluorophore produces light with a color and wavelength corresponding to the information stored on the section of the polymer sequence the molecular probe labels. The quencher inhibits the production of light by an adjacent fluorophore. When adjacent sections of the polymer sequence are labeled with molecular probes, the fluorophore of the leading molecular probe produces light while the trailing molecular probe's light is quenched. The method and system then sequentially unbind the molecular probes from the sections of the polymer sequence within a waveguide, producing a sequence of observable fluorescence signals. The sequence can be used to determine the information stored on a polymer sequence.

A method and system to decode information stored on a polymer sequence, such as a DNA strand, is described herein. The method and system use molecular probes to label sections of the polymer sequence. Each molecular probe includes a fluorophore and a quencher. The fluorophore produces light with a color and wavelength corresponding to the information stored on the section of the polymer sequence the molecular probe labels. The quencher inhibits the production of light by an adjacent fluorophore. When adjacent sections of the polymer sequence are labeled with molecular probes, the fluorophore of the leading molecular probe produces light while the trailing molecular probe's light is quenched. The method and system then sequentially unbind the molecular probes from the sections of the polymer sequence within a waveguide, producing a sequence of observable fluorescence signals. The sequence can be used to determine the information stored on a polymer sequence.

The present disclosure provides methods, systems, and kits for processing nucleic acid molecules. A method may comprise providing a template nucleic acid fragment (e.g., within a cell, cell bead, or cell nucleus) within a partition (e.g., a droplet or well) and subjecting the template nucleic acid fragment to one or more processes including a barcoding process and a single primer extension or amplification process. The processed template nucleic acid fragment may then be recovered from the partition and subjected to further amplification to provide material for subsequent sequencing analysis. The methods provided herein may permit simultaneous processing and analysis of both DNA and RNA molecules originating from the same cell, cell bead, or cell nucleus.

The present invention provides a use of a Cas protein, and a method and a kit for detecting target nucleic acid molecules. The method for detecting target nucleic acid molecules comprises adding a guide RNA, a Cas12a, and a nucleic acid probe into a reaction system containing target nucleic acid molecules to be detected, and detecting it after the reaction is completed.