The present invention relates to detection of target nucleic acid sequences using different detection temperatures and reference values. The present invention employing different detection temperatures and reference values enables to detect a plurality of target nucleic acid sequences in conventional real-time manners even with a single type of label in a single reaction vessel.

Provided in the present invention is a composition capable of detecting and typing novel coronavirus 2019-nCoV, coronavirus 229E, coronavirus NL63, coronavirus OC43, coronavirus HKU1, coronavirus MERSr-CoV, and coronavirus SARSr-CoV. At the same time, further provided is a kit comprising the composition and a method for detecting and typing coronaviruses. The composition of the present invention in combination with a fluorescent probe method and a melting curve method can perform simultaneous detection and typing of seven coronaviruses in one tube.

Provided in the present invention is a composition capable of detecting and typing novel coronavirus 2019-nCoV, coronavirus 229E, coronavirus NL63, coronavirus OC43, coronavirus HKU1, coronavirus MERSr-CoV, and coronavirus SARSr-CoV. At the same time, further provided is a kit comprising the composition and a method for detecting and typing coronaviruses. The composition of the present invention in combination with a fluorescent probe method and a melting curve method can perform simultaneous detection and typing of seven coronaviruses in one tube.

The present disclosure relates to a method including exposing a composition comprising a wax-microsphere matrix to a first melt-condition, wherein said wax-microsphere matrix comprises a wax component and a plurality of lyophilised microspheres, wherein said plurality of lyophilised microspheres comprise one or more reagent, whereby exposing said composition comprising said wax-microsphere matrix to said first melt-condition melts the wax component; exposing said composition to a first release-condition to rehydrate at least one lyophilised microsphere; and exposing said at least one rehydrated lyophilised microsphere to a separation-condition to separate said wax component from said at least one rehydrated lyophilised microsphere. Also disclosed are methods of preparing a wax-microsphere matrix and releasing one or more reagent from a wax-microsphere matrix as well as compositions. Also disclosed are cartridges with a reagent reservoir including the compositions described herein. Also disclosed are systems for controlling release of one or more reagent including the compositions described herein.

The present disclosure relates to a method including exposing a composition comprising a wax-microsphere matrix to a first melt-condition, wherein said wax-microsphere matrix comprises a wax component and a plurality of lyophilised microspheres, wherein said plurality of lyophilised microspheres comprise one or more reagent, whereby exposing said composition comprising said wax-microsphere matrix to said first melt-condition melts the wax component; exposing said composition to a first release-condition to rehydrate at least one lyophilised microsphere; and exposing said at least one rehydrated lyophilised microsphere to a separation-condition to separate said wax component from said at least one rehydrated lyophilised microsphere. Also disclosed are methods of preparing a wax-microsphere matrix and releasing one or more reagent from a wax-microsphere matrix as well as compositions. Also disclosed are cartridges with a reagent reservoir including the compositions described herein. Also disclosed are systems for controlling release of one or more reagent including the compositions described herein.

High-fidelity, high-throughput nucleic acid sequencing enables healthcare practitioners and patients to gain insight into genetic variants and potential health risks. However, previous methods of nucleic acid sequencing often introduces sequencing errors (for example, mutations that arise during the preparation of a nucleic acid library, during amplification, or sequencing). Provided herein are sequencing adapters comprising a nondegenerate or variable length molecular barcode and compositions comprising a plurality of sequencing adapters, which can be useful for sequencing nucleic acids. Further provided are methods of using the sequencing adapters, including methods of sequencing nucleic acids, methods of identifying an error in a nucleic acid sequence, and methods of determining the number of nucleic acid molecules in a library.

High-fidelity, high-throughput nucleic acid sequencing enables healthcare practitioners and patients to gain insight into genetic variants and potential health risks. However, previous methods of nucleic acid sequencing often introduces sequencing errors (for example, mutations that arise during the preparation of a nucleic acid library, during amplification, or sequencing). Provided herein are sequencing adapters comprising a nondegenerate or variable length molecular barcode and compositions comprising a plurality of sequencing adapters, which can be useful for sequencing nucleic acids. Further provided are methods of using the sequencing adapters, including methods of sequencing nucleic acids, methods of identifying an error in a nucleic acid sequence, and methods of determining the number of nucleic acid molecules in a library.

The present invention relates to methods and systems for genome scanning using high resolution melting analysis for identifying mutations and/or variants in genes of interest.

The present invention relates to methods and systems for genome scanning using high resolution melting analysis for identifying mutations and/or variants in genes of interest.

The invention generally relates to methods for increasing the amount of DNA available for analysis when using partitioned samples and parallel processing. For example, double-stranded DNA can be dissociated into two single-stranded components, and the single strands partitioned into different droplets prior to analysis. The disclosed methods are useful for performing digital PCR analysis on samples where the target DNA is not in abundance, for example when the sample originates from a body fluid or an FFPE sample.