The invention relates to methods of assessing a patient's risk of developing Progressive multifocal leukoencephalopathy (PML).

Disclosed are methods of diagnosis of a pathogen-associated disease. These methods comprise: providing a biological sample from a human subject; determining presence, absence and/or quantity of a bacterial pathogen, a viral pathogen, or a combination thereof, by a pathogen culture, a serum antibody detection test, a pathogen antigen detection test, a pathogen DNA and/or RNA detection test, or a combination thereof; determining in the sample, expression levels of at least one endogenous gene in which aberrant expression levels are associated with infection with a pathogen, by a microarray hybridization assay, RNA-seq assay, polymerase chain reaction assay, a LAMP assay, a ligase chain reaction assay, a Southern, Northern, or Western blot assay, an ELISA or a combination thereof. The subject can be diagnosed with the disease if the subject comprises the pathogen and an aberrant level of expression of an endogenous gene.

A method for diagnosing hepatitis virus infection or a hepatitis disease condition in a subject based on hepatitis virus-associated biomarkers present on exosomes in a bodily fluid sample from the subject is disclosed. Also disclosed are a method for monitoring the course of a hepatitis virus infection or a hepatitis disease condition in a subject and a method for monitoring effectiveness of treatment to a subject with an anti-hepatitis virus agent based on hepatitis virus-associated biomarkers present on exosomes in bodily fluid samples from the subject, as well as a kit for diagnosing hepatitis virus infection and/or a hepatitis disease condition in a subject based on hepatitis virus-associated biomarkers on exosomes in bodily fluid samples from the subject.

This invention provides compositions and methods to treat a condition or disease without the use of exogenous targeting sequences or chemical compositions. The present invention relates to single-domain antibodies (sdAbs), proteins and polypeptides comprising the sdAbs that are directed against targets that cause a condition or disease. The invention also includes nucleic acids encoding the sdAbs, proteins and polypeptides, and compositions comprising the sdAbs. The invention includes the use of the compositions, sdAbs, and nucleic acids encoding the sdAbs for prophylactic, therapeutic or diagnostic purposes.

A process for assaying viral vector manufactured by large-scale viral vector manufacturing processes to assure the resulting vector has acceptable purity and potency. The process entails three different types of assays, each one of which is optionally useful on a stand-alone basis, and which together provide the first system able to assure the quality of viral vector produced by large-scale vector manufacturing processes,

In various embodiments devices and methods for the detection and/or quantification of clinically relevant pathogens (e.g., bacteria, fungi, viruses, etc.) are provided. In certain embodiments the device comprises a lateral-flow assay that detects the bacterium at a concentration of less than about 6×10.sup.6 cells/mL, less than about 3×10.sup.6 cells/ml, less than about 1×10.sup.6 CFU/mL, or less than about 50 μg/mL. In certain embodiments the device comprises an aqueous two-phase system (ATPS) comprising a mixed phase solution that separates into a first phase solution and a second phase solution; and a lateral-flow assay (LFA). In certain embodiments the device comprises a flow-through system comprising a concentration component comprising an aqueous two-phase system (ATPS) comprising a mixed phase solution that separates into a first phase solution and a second phase solution; and a detection component disposed beneath said concentration component.

Provided is a method of detecting the presence of an anti-Zika virus (ZIKV) antibody in a sample, including contacting a sample with a suspension having a plurality of microspheres wherein individual microspheres are conjugated to a peptide and the peptide includes a ZIKV peptide selected from the group including ZIKV NS1, ZIKV NS5, and ZIKV envelope protein, forming a first incubated suspension by incubating said sample with said suspension to permit binding of anti-ZIKV antibodies present in the sample to said microspheres, forming a second incubated suspension by contacting said first incubated suspension with an anti-ZIKV antibody detecting-reagent to permit binding of the anti-ZIKV antibody detecting reagent to said microspheres, removing from the second incubated suspension anti-ZIKV antibody detecting-reagent molecules that are not bound to said microspheres, and detecting the presence of anti-ZIKV antibody detecting-reagent molecules in the second incubated suspension. Also provided is a kit containing reagents and compositions for performing the foregoing method.

The disclosure relates to a polypeptide suitable for detecting antibodies against a flavivirus in an isolated biological sample having a flavivirus NS1 wing domain specific amino acid sequence, wherein no amino acid sequences from the NS1 ß-ladder domain of said flavivirus are present in the polypeptide. In an embodiment, the flavivirus is selected from Zika virus (ZIKV), West-Nile virus (WNV), Dengue virus types 1-4 (DENV1-4), tick-borne encephalitis virus (TBEV), yellow fever virus (YFV) and Japanese encephalitis virus (JEV). Also disclosed is a method for producing said flaviviral NS1 wing domain specific polypeptides, a method for detecting antibodies specific for a first flavivirus species, the use of said flaviviral NS1 wing domain specific polypeptides for detecting antibodies as well as a reagent kit for detecting said flavivirus antibodies that has a flavivirus NS1 wing domain polypeptide.

Methods for diagnosis of bacterial and viral infections are disclosed. In particular, the invention relates to the use of biomarkers that can determine whether a patient with acute inflammation has a bacterial or viral infection.

Chikungunya virus (CHIKV) has caused recent outbreaks associated with severe morbidity. Currently no vaccine or treatment exists to protect humans from CHIKV infection. Treatment is therefore purely symptomatic and is based on non-steroidal anti-inflammatory drugs. Accordingly, there is a high medical need exists to have new methods of screening of compounds which could inhibit chikungunya virus. Further to a CRISPR-Cas9 genetic screen the inventors now identify the four and a half LIM domains protein 1 (FHL1) has an essential host factor for CHIKV infection. In particular, they show that primary myoblast and fibroblast from FHL1 deficient patient are resistant to CHIKV infection. They also demonstrate that depletion of FHL1 prevents CHIKV replication. Finally, they show that CHIKV non-structural protein 3 interacts specifically with FHL1A through its hypervariable domain. Thus compounds that are capable of inhibiting the interaction between the non-structural protein 3 and FHL1 would be suitable for inhibiting the replication capacity of the virus. Determining the expression level of FHL1 and/or identifying some genetic variant would also be suitable for determining whether some subjects are predisposed to CHIKV infection.