The present disclosure provides compositions and methods related to the detection of an analyte-of-interest. In particular, the present disclosure provides compositions and methods related to the detection and/or quantification of an analyte-of-interest using a signal detection component in combination with a signal amplification component. By combining these components in a modular format, cell-free synthetic gene circuits can be generated or improved to address a specific biological or biomedical diagnostic need.

The present disclosure provides compositions and methods related to the detection of an analyte-of-interest. In particular, the present disclosure provides compositions and methods related to the detection and/or quantification of an analyte-of-interest using a signal detection component in combination with a signal amplification component. By combining these components in a modular format, cell-free synthetic gene circuits can be generated or improved to address a specific biological or biomedical diagnostic need.

Provided herein are methods of imaging non-repetitive genomic loci using unique guide ribonucleic acids (gRNAs), an RNA-guided nuclease, and a detectable conjugate.

Provided herein are methods of imaging non-repetitive genomic loci using unique guide ribonucleic acids (gRNAs), an RNA-guided nuclease, and a detectable conjugate.

A C9orf72 DNA repeat expansion can be detected using a CRISPR Arrayed Repeat Detection System (CARDS). Based upon the compositions and methods supporting this platform primary cell cultures and/or blood cell smears can be tested under conventional clinical diagnostic laboratory conditions to diagnose genetically-based diseases having DNA repeat expansions, including but not limited to ALS. dCas9 constructs are also contemplated as having fluorescent proteins bound to any or all stem loop sequences, wherein detection of a plurality of dCas9 constructs having different colored fluorescent proteins can simultaneously detect at least six (6) different gene target loci.

A C9orf72 DNA repeat expansion can be detected using a CRISPR Arrayed Repeat Detection System (CARDS). Based upon the compositions and methods supporting this platform primary cell cultures and/or blood cell smears can be tested under conventional clinical diagnostic laboratory conditions to diagnose genetically-based diseases having DNA repeat expansions, including but not limited to ALS. dCas9 constructs are also contemplated as having fluorescent proteins bound to any or all stem loop sequences, wherein detection of a plurality of dCas9 constructs having different colored fluorescent proteins can simultaneously detect at least six (6) different gene target loci.

A method for sequencing a nucleic acid strand, comprising the steps of: providing a solution containing truncated strands having lengths different from one another terminating with a respective dideoxynucleotide from among ddATP, ddTTP, ddGTP, and ddCTP; functionalizing first masses by a donor molecule and second masses by an acceptor molecule such as to generate a light emission when they come into mutual contact; coupling a first mass to a first end of each truncated strand; coupling the second masses to a respective terminal dideoxynucleotide of each strand; applying an AC electrical field having variable frequencies that are such as to generate, on each second mass, a net movement directed towards the first mass; acquiring a plurality of light radiations for each frequency value; and associating each light radiation acquired to a respective dideoxynucleotide and, thus, to a respective nucleotide base.

A method for sequencing a nucleic acid strand, comprising the steps of: providing a solution containing truncated strands having lengths different from one another terminating with a respective dideoxynucleotide from among ddATP, ddTTP, ddGTP, and ddCTP; functionalizing first masses by a donor molecule and second masses by an acceptor molecule such as to generate a light emission when they come into mutual contact; coupling a first mass to a first end of each truncated strand; coupling the second masses to a respective terminal dideoxynucleotide of each strand; applying an AC electrical field having variable frequencies that are such as to generate, on each second mass, a net movement directed towards the first mass; acquiring a plurality of light radiations for each frequency value; and associating each light radiation acquired to a respective dideoxynucleotide and, thus, to a respective nucleotide base.

The present invention relates to a method and kit for amplifying and detecting a quantity of nucleic acid. The invention is particularly relevant to isothermal amplification techniques carried out on a flow based assay device. The amplified nucleic acid may be detected on the device using an optical read-out.

The present invention relates to a method and kit for amplifying and detecting a quantity of nucleic acid. The invention is particularly relevant to isothermal amplification techniques carried out on a flow based assay device. The amplified nucleic acid may be detected on the device using an optical read-out.