Methods, systems, and software are provided for determining whether a subject is afflicted with an oncogenic pathogen. Nucleic acids from a biological sample of the subject are hybridized to a probe set that includes probes for human genomic loci and for genomic loci of oncogenic pathogens. Sequence reads of the hybridized nucleic acid are obtained and it’s determined whether each sequence read aligns to a human reference genome. For each sequence read that fails to align to the human reference genome, it’s determined whether the sequence read aligns to a reference genome of an oncogenic pathogen. Sequence reads that both (i) fail to align to the human reference genome and (ii) align to a reference genome of an oncogenic pathogen are tracked, thereby obtaining a sequence read count for the oncogenic pathogen. The sequence read count is used to ascertain whether the subject is afflicted with the oncogenic pathogen.

This invention relates generally to the field of analyte assays. In particular, the invention provides a device for analyzing an analyte, which device comprises, inter alia, various means for moving analytes and other items to facilitate binding between analytes and their binding reagents immobilized on a surface and to facilitate clearance of undesirable items away from analyte-binding reagent interaction area to reduce background noise in the assay. Methods for analyzing an analyte using the devices are also disclosed.

The present invention relates to a composition comprising a probe for detecting six representative causative viruses of acute enteritis (norovirus genogroup I and genogroup II, rotavirus, hepatitis A virus, coxsackievirus, astrovirus, and adenovirus), and a DNA microarray, a kit, and a detection method comprising the composition. The present invention is effective due to high specificity and sensitivity to viruses. In addition, since the causative viruses can simply be detected at low cost compared to conventional detection methods, without expensive diagnosis devices or specialists, the present invention may be effectively used as a method for diagnosing viruses causing acute enteritis.

Provided herein are methods and systems for identifying chimeric nucleic acid fragments, e.g., organism-pathogen chimeric nucleic acid fragments and chromosomal rearrangement chimeric nucleic acid fragments. Also provided herein are methods and systems relating to determining a pathogen integration profile or a chromosomal rearrangement in a biological sample and determining a classification of pathology based at least in part on a pathogen integration profile or a chromosomal rearrangement in a biological sample. In certain aspects of the present disclosure, cell-free nucleic acid molecules from a biological sample are analyzed.

This application relates to a DNA marker for HBV-HCC detection and the methods, kits for quantitatively measuring the amount of HBV DNA and bisulfite treated HBV DNA, and methylated HBV DNA, and the aberrant methylation of the HBV genome for the used in the chronic HBV infected populations. Detection of the presence or absence of HCC, with elevated methylation levels in the one or more regions of DNA of the mammals as compared to the level of methylation in the one or more regions of DNA in the one or more control body fluids or tissues indicating the presence of the cancer, and the absence of elevated methylation levels indicating the absence of HCC.

Provided herein includes a method for characterizing a target cell-free nucleic acid (cfNA) molecule present in a biological sample such as a urine sample. It comprises isolating total cfNAs from the biological sample without prior preprocessing such as centrifugation to remove cell debris, and characterizing the target cfNA molecule based on the isolated total cfNAs. When the target cfNA is a low molecular weight (LMW) molecule, the method additionally comprises a fractionation step to obtain LMW nucleic acids from the total cfNAs before characterization. The method can detect significantly more copies of the target cfNA molecule compared with existing methods which typically discard the cell debris from the biological sample. Another method is also provided, which substantially recovers cfNAs from the usually discarded cell debris, thus also capable of detecting significantly more copies of the target cfNA molecule.

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.

Provided herein are methods for the obtention of an active HBV RNaseH preparation and its use in screening methods to identify potential inhibitors of the enzyme for possible use as therapeutic agents. Also provided are methods of treatment using agents identified according to the screen.

Provided herein are methods for the obtention of an active HBV RNaseH preparation and its use in screening methods to identify potential inhibitors of the enzyme for possible use as therapeutic agents. Also provided are methods of treatment using agents identified according to the screen.

Disclosed herein are methods of detecting viral nucleic acids in a sample that include contacting the sample with one or more sets of loop-mediated isothermal amplification (LAMP) primers specific for a viral nucleic acid of interest (such as hepatitis B virus, hepatitis C virus, hepatitis E virus, human immunodeficiency virus, West Nile virus, or Dengue virus nucleic acids) under conditions sufficient to produce an amplification product and detecting the amplification product(s). In some examples, the amplification product is detected by gel electrophoresis, while in other examples, the amplification product is detected by detecting signal from a label included in one or more of the LAMP primers. Primers and kits for use for detection of viral nucleic acids by LAMP are also disclosed herein.