Provided herein is a method for mapping rolling circle amplification (RCA) products that contain unique identifier sequences. The method generally involves (a) producing a complex comprising population of grid oligonucleotide molecules and a population of RCA products that each have a unique RCA product identifier sequence, wherein the grid oligonucleotides are hybridized directly or indirectly via a splint to complementary sites in the RCA products; (b) extending the grid oligonucleotide molecules that are hybridized to two RCA products to add the complements of the unique RCA product identifier sequences from the two RCA products to the grid oligonucleotide molecules; (c) sequencing the extended grid oligonucleotides; (d) analyzing the sequences to identify which pairs of unique RCA product identifier sequence complements have been added onto the grid oligonucleotides; and (e) making one or more physical maps of the immobilized RCA products using the pairs of sequences identified in (d).

Provided herein is a method for mapping rolling circle amplification (RCA) products that contain unique identifier sequences. The method generally involves (a) producing a complex comprising population of grid oligonucleotide molecules and a population of RCA products that each have a unique RCA product identifier sequence, wherein the grid oligonucleotides are hybridized directly or indirectly via a splint to complementary sites in the RCA products; (b) extending the grid oligonucleotide molecules that are hybridized to two RCA products to add the complements of the unique RCA product identifier sequences from the two RCA products to the grid oligonucleotide molecules; (c) sequencing the extended grid oligonucleotides; (d) analyzing the sequences to identify which pairs of unique RCA product identifier sequence complements have been added onto the grid oligonucleotides; and (e) making one or more physical maps of the immobilized RCA products using the pairs of sequences identified in (d).

This disclosure provides riboregulators specific for particular viruses or for particular human transcription factors. The viral-specific riboregulators may be used to detect the presence of the particular virus, and this may enable diagnosis of an infection. The transcription factor specific riboregulators may be used to detect the presence and/or measure the level of the particular transcription factor, and this may enable diagnosis or prognosis of a particular condition such as cancer.

This disclosure provides riboregulators specific for particular viruses or for particular human transcription factors. The viral-specific riboregulators may be used to detect the presence of the particular virus, and this may enable diagnosis of an infection. The transcription factor specific riboregulators may be used to detect the presence and/or measure the level of the particular transcription factor, and this may enable diagnosis or prognosis of a particular condition such as cancer.

An assay is provided for the rapid detection of nucleic acids via a modified LAMP reaction coupled with colorimetric reporter utilizing a gold nanoparticle—peptide nucleic acid (AuNP-PNA) probe system.

An assay is provided for the rapid detection of nucleic acids via a modified LAMP reaction coupled with colorimetric reporter utilizing a gold nanoparticle—peptide nucleic acid (AuNP-PNA) probe system.

The present invention relates to a method of detecting a genetic event, the method comprising steps of partitioning a sample from a subject into a plurality of partitions, and carrying out a digital polymerase chain reaction (dPCR) assay, to determine occurrence of said genetic event.

The present invention relates to a method of detecting a genetic event, the method comprising steps of partitioning a sample from a subject into a plurality of partitions, and carrying out a digital polymerase chain reaction (dPCR) assay, to determine occurrence of said genetic event.

The relative abundance of bacterial species in a patient’s microbiome is quantified using DNA nanostructures that fluoresce multiple colors. Immobilizing binders have binding sites with nucleotide sequences complementary to those at a primary site on rRNA subunits of each selected bacterial species. Fluorophore binders have binding sites with nucleotide sequences complementary to those at a secondary site on the rRNA subunits. The fluorophore binders for each bacterial species are attached to nanostructures that fluoresce a particular color for each bacteria. The immobilizing binders are attached to the surface of a microscopy chamber. RNA subunits are extracted from a microbiome sample of the patient and are attached to the corresponding immobilizing binders and fluorophore binders such that the RNA subunits of each bacterial species fluoresce a color unique to the species. DNA nanostructures emitting the same color are counted to determine the relative concentration of the bacterial species in the sample.

The relative abundance of bacterial species in a patient’s microbiome is quantified using DNA nanostructures that fluoresce multiple colors. Immobilizing binders have binding sites with nucleotide sequences complementary to those at a primary site on rRNA subunits of each selected bacterial species. Fluorophore binders have binding sites with nucleotide sequences complementary to those at a secondary site on the rRNA subunits. The fluorophore binders for each bacterial species are attached to nanostructures that fluoresce a particular color for each bacteria. The immobilizing binders are attached to the surface of a microscopy chamber. RNA subunits are extracted from a microbiome sample of the patient and are attached to the corresponding immobilizing binders and fluorophore binders such that the RNA subunits of each bacterial species fluoresce a color unique to the species. DNA nanostructures emitting the same color are counted to determine the relative concentration of the bacterial species in the sample.