Abstract: The invention provides a method for genetic analysis in individuals that reveals both the genetic sequences and chromosomal copy number of targeted and specific genomic loci in a single assay. The present invention further provide methods for the sensitive and specific detection of target gene sequences and gene expression profiles.

Abstract: Present invention disclosed a novel method for detecting and quantifying target DNA from the biological sample. It provides a method of amplification of DNA sequences with loop-mediated isothermal amplification (LAMP) and its easy and accurate detection and quantification by electrochemiluminescence (ECL) technique. The target LAMP DNA is bound electrostatically with [Ru(bpy)3]+2 on the carbon electrode surface, and an ECL reaction is triggered by tripropylamine (TPrA) to yield luminescence. This is a highly sensitive strategy for the detection of sequence-specific DNA from different biological samples at picogram levels. The target DNA of Sus scrofa (pork) meat was detected as low as 1 pg/?L (3.43×10?1 copies/?L) and for Bacillus subtilis DNA samples the detection limit of 10 pg/?L (2.2×103 copies/?L) was achieved.

Abstract: The invention provides methods for pairwise sequencing of a double-stranded polynucleotide template, which methods result in the sequential determination of nucleotide sequences in two distinct and separate regions of the polynucleotide template.

Abstract: An assay kit of reagents including a nucleic acid capable of acting as substrate for polymerase microorganism activity useful in a method of detecting polymerase activity as an indicator of the presence of a micro-organism in a sample are disclosed. The disclosed embodiments also relate to reagents for use in such methods, and to test kits comprising such reagents for carrying out the methods.

Abstract: The present disclosure relates to a rapid diagnostic test system that includes the prospective collection of whole blood, preservation of circulating nucleic acids at ambient temperature, and the reproducible detection of nucleic acids including DNA and mRNA (including fusion transcripts and differentially expressed transcripts) by different genomic methodologies.

Abstract: Systems and methods for the high yield extraction and recovery of higher quality target molecule(s) (e.g., DNA, RNA, protein, lipids, metabolites) from blood spots. High quality DNA recovered from dried blood spots can be an input source for high throughput analytical methods, such as for polymerase chain reaction (e.g., qPCR) and/or next generation sequencing (NGS). In various embodiments, at least 20.0 nanograms of nucleic acid (e.g., DNA, RNA), or at least 8.0 milligrams of protein, may be extracted and recovered per an amount of dried blood corresponding to approximately 5 microliters of fresh blood. In some embodiments, a majority (e.g., greater than 50%, greater than 60%, up to 95-100%) of the nucleic acid that is extracted and recovered from the blood spot via focused acoustics may be of a quality suitable for amplification via PCR or NGS.

Abstract: Primers and probes for detecting an RNA virus, including HIV, HIV-1 subtypes of the M and O groups, and HCV, in a sample. The primers and probes can be used for monitoring the efficacy of anti-retroviral treatment in a subject infected with HIV and/or HCV, and for detecting acute HIV-1 infection, and/or acute HCV infection, in a subject. Included are inner, middle and outer primers that can be used in PCR, including triple nested PCR in a single tube. The methods are highly sensitive and specific, allowing for detection of as few as 4 copies of virus in a sample.

Abstract: A method for rapidly isolating a biological molecule for a nucleic acid amplification reaction from a biological sample, the method comprising: putting a cubical shaped-porous solid phase having a plurality of pores varied in size in contact with a biological sample to get the biological molecule present in the biological sample sucked into pores of the cubical shaped-porous solid phase, wherein the cubical shaped-porous solid phase is made of ceramic having oxide material, which is selected from the group consisting of Al2O3, Fe2O3, low temperature co-fired ceramic (LTCC), PbO, and ZnO.

Abstract: The disclosed invention is related to compositions, kits and methods comprising one or more oligomers targeting 16S rRNA target nucleic acid from Campylobacter species jejuni, coli and/or lari. Compositions include amplification oligomers, detection probe oligomers and/or target capture oligomers. Kits and methods comprise at least one of these oligomers.

Abstract: Improved methods for amplifying target nucleic acid sequences are provided by 1) first amplifying the number of copies of target nucleic acid sequences in a sample by a first nucleic acid amplification method, and then 2) applying a second nucleic amplification method to the amplified sample, or aliquot thereof, further amplifying the number of copies of target sequences. In embodiments, a first nucleic acid amplification method is a thermocycling method, and a second nucleic acid amplification method is an isothermal method.

Abstract: The present invention provides a method of amplifying an RNA molecule in a biological sample by reverse transcription PCR (RT-PCR), wherein the RT-PCR is carried out in a solution comprising a polyol, a serum albumin, a non-ionic surfactant and a reducing agent.

Abstract: The invention provides methods for simultaneously amplifying multiple nucleic acid regions of interest in one reaction volume as well as methods for selecting a library of primers for use in such amplification methods. The invention also provides library of primers with desirable characteristics, such as minimal formation of amplified primer dimers or other non-target amplicons.

Abstract: This disclosure provides, among other things, a method for processing a membrane comprising rolling circle amplification (RCA) products. In some embodiments, this method may comprise: (a) obtaining a porous capillary membrane that comprises fluorescently labeled RCA products that are in or on the membrane; (b) depositing a curable polymer onto the membrane; and (c) curing the curable polymer to encapsulate the RCA products in a solid. In some embodiments, the curable polymer may be a silicone and may be transparent in its solid form. A kit for performing the method and a composition made by the method are also provided.

Abstract: This disclosure generally relates to improved methods, compositions, and systems for detecting, quantifying, and characterizing genomic sequences from heterogeneous genomic samples. The disclosed methods include providing a unique molecular identifier to the initial target sequences prior to amplification and addition of indexing barcodes. The methods, compositions, and systems can be employed to accurately detect and quantify operational taxonomic units from heterogeneous samples and further to detect sequencing errors, e.g., chimeric sequences, which may occur during the development and sequencing of the library.

Abstract: Methods of the present disclosure provide for detection of mutations and splice variants of the androgen receptor using a non-invasive approach, RNAseq, for examining circulating tumor cells.

Abstract: Provided are methods of amplifying nucleic acids. The methods include combining a nucleic acid sample and one or more amplification primers adapted to amplify a region of one or more copy number stable genes in a reaction mixture under conditions sufficient to amplify the one or more copy number stable genes. Aspects of the present disclosure further include compositions and kits that find use in practicing embodiments of the methods.

Abstract: Next Generation DNA sequencing promises to revolutionize clinical medicine and basic research. However, while this technology has the capacity to generate hundreds of billions of nucleotides of DNA sequence in a single experiment, the error rate of approximately 1% results in hundreds of millions of sequencing mistakes. These scattered errors can be tolerated in some applications but become extremely problematic when “deep sequencing” genetically heterogeneous mixtures, such as tumors or mixed microbial populations. To overcome limitations in sequencing accuracy, a method Duplex Consensus Sequencing (DCS) is provided. This approach greatly reduces errors by independently tagging and sequencing each of the two strands of a DNA duplex. As the two strands are complementary, true mutations are found at the same position in both strands. In contrast, PCR or sequencing errors will result in errors in only one strand.

Abstract: A method, kit and primers for determining alleles present in a DNA sample that is sourced from either a mouse or a cell line derived from a mouse. A set of STR marker loci are selected that can be amplified together in a multiplex amplification reaction. The set of STR marker loci are selected from the group consisting of: 18-3, 4-2, 6-7, 15-3, 6-4, 12-1, 5-5, X-1, Mo11-1, Mo19-2, Mo1-2, Mo7-1, Mo1-1, Mo3-2, Mo8-1, Mo2-1, Mo11-2, Mo17-2, Mo13-1, D8S1106 and D4S2408. A set of oligonucleotide primer pairs are provided. Each oligonucleotide primer pair flanks a single locus in the set of STR marker loci, which are co-amplified in a multiplex amplification reaction, with the product(s) comprising a mixture of amplified alleles from each of the co-amplified loci in the set of STR marker loci. The products are evaluated to determine the alleles present at each of the loci analyzed.

Abstract: The invention provides methods for simultaneously amplifying multiple nucleic acid regions of interest in one reaction volume as well as methods for selecting a library of primers for use in such amplification methods. The invention also provides library of primers with desirable characteristics, such as minimal formation of amplified primer dimers or other non-target amplicons.

Abstract: Compositions, reaction mixtures, and methods for performing an amplification reaction, including multiplex amplification reaction, wherein the method comprises using one or more amplification oligomer complexes comprising linked first and second amplification oligomer members. In one aspect, the amplification oligomer complex is hybridized to a target nucleic acid, the target nucleic acid with hybridized amplification oligomer complex is then captured, and other components are washed away. Target sequences of the target nucleic acids are pre-amplified to generate a first amplification product. The first amplification product is amplified in one or more secondary amplification reactions to generate second amplification products.