In some aspects, the present disclosure provides methods for enriching amplicons, or amplification products, comprising a concatemer of at least two or more copies of a target polynucleotide. In some embodiments, a method comprises sequencing the amplicons comprising at least two or more copies of a target polynucleotide. In some embodiments, the target polynucleotides comprise sequences resulting from chromosome rearrangement, including but not limited to point mutations, single nucleotide polymorphisms, insertions, deletions, and translocations including fusion genes. In some aspects, the present disclosure provides compositions and reaction mixtures useful in the described methods.

Novel methods of generating a localized population of immobilized clonal amplicons on a support are provided.

Novel methods of generating a localized population of immobilized clonal amplicons on a support are provided.

Compositions, kits, and methods for performing rapid polymerase chain reaction (PCR) to amplify a target nucleic acid in a biological sample are disclosed. The methods include the use of at least one hybridization stabilizer and/or the adjustment of the thermocycling profiles between initiation and propagation phases of the amplification process. Also disclosed are methods of detecting the target nucleic acid following amplification thereof, as well as reaction mixtures that may be utilized in said methods.

Compositions, kits, and methods for performing rapid polymerase chain reaction (PCR) to amplify a target nucleic acid in a biological sample are disclosed. The methods include the use of at least one hybridization stabilizer and/or the adjustment of the thermocycling profiles between initiation and propagation phases of the amplification process. Also disclosed are methods of detecting the target nucleic acid following amplification thereof, as well as reaction mixtures that may be utilized in said methods.

Compositions, kits, and methods for performing rapid polymerase chain reaction (PCR) to amplify a target nucleic acid in a biological sample are disclosed. The methods include the use of at least one hybridization stabilizer and/or the adjustment of the thermocycling profiles between initiation and propagation phases of the amplification process. Also disclosed are methods of detecting the target nucleic acid following amplification thereof, as well as reaction mixtures that may be utilized in said methods.

The present disclosure in some aspects relates to methods and compositions for accurately detecting and quantifying multiple analytes present in a biological sample. In some aspects, the methods and compositions provided herein address issues associated with the heterogeneity of analyte abundance (e.g., gene expression levels) and variations among reactions at different locations of a sample (e.g., amplification reaction starting earlier at one location than another location). In some aspects, a method disclosed herein provides a tighter distribution of signal spot size and intensity in a sample, as compared to methods that result in a wide and heterogeneous size and intensity distribution of signal spots.

The present disclosure in some aspects relates to methods and compositions for accurately detecting and quantifying multiple analytes present in a biological sample. In some aspects, the methods and compositions provided herein address issues associated with the heterogeneity of analyte abundance (e.g., gene expression levels) and variations among reactions at different locations of a sample (e.g., amplification reaction starting earlier at one location than another location). In some aspects, a method disclosed herein provides a tighter distribution of signal spot size and intensity in a sample, as compared to methods that result in a wide and heterogeneous size and intensity distribution of signal spots.

Kits and methods for detecting pathogens without the need for laboratory equipment are disclosed. The kits and methods described herein allow for near-room temperature amplification of pathogen polynucleotides in a biological sample in a one-compartment reaction vessel. The kits and methods may be used to detect any target nucleic acid, such as DNA or RNA from a bacterial, fungal, or viral pathogen.

Kits and methods for detecting pathogens without the need for laboratory equipment are disclosed. The kits and methods described herein allow for near-room temperature amplification of pathogen polynucleotides in a biological sample in a one-compartment reaction vessel. The kits and methods may be used to detect any target nucleic acid, such as DNA or RNA from a bacterial, fungal, or viral pathogen.