The present invention relates to monoclonal antibodies for the detection of HCV antigen. More specifically, the invention describes antibodies against HCV core antigen lipid binding domain and immunoassay methods, kits and compositions for use in detecting HCV infection.

Synthetic representative HCV subtypes, including a 1a and 1b genome, dubbed Bole1a and Bole1b, are provided using an inventive method of Bayesian phylogenetic tree analysis, ancestral sequence reconstruction and covariance analysis. Bole1a branches centrally among 390 full-genome sequences used in its design, a carefully curated 143 sequence full-genome dataset, and separate genomic regions including an independent set of 214 E1E2 sequences from a Baltimore cohort. Bole1a is phylogenetically representative of widely circulating strains. Full genome non-synonymous diversity comparison and 9-mer peptide coverage analysis showed that Bole1a is able to provide more coverage (94% and 78% respectively) than any other sequence in the dataset including H77, a traditional reference sequence. Bole1a also provides unsurpassed epitope coverage when compared to all known T cell epitopes.

The present invention can induce stronger cellular immunity to hepatitis C and provide a treatment means and a prevention means that are effective in completely eliminating the hepatitis C virus (HCV). Provided is a pharmaceutical composition for the treatment and/or prevention of hepatitis C, said composition comprising a recombinant vaccinia virus (a) and a recombinant vector (b) and characterized in that after one of the recombinant vaccinia virus (a) and the recombinant vector (b) is administered for initial immunity, the other is administered for additional immunity. The recombinant vaccinia virus (a) contains an expression promoter and all or a portion of the cDNA of the HCV genome. The recombinant vector (b) contains an expression promoter and all or a portion of the cDNA of the HCV (where the cDNA contained in the recombinant vector (b) has a different base sequence than that included in the recombinant vaccinia virus (a)).

The present disclosure in some aspects relates to HCV core antigen polypeptides. In some aspects, the present disclosure further relates to HCV antibodies, including camelid antibodies that specifically bind to HCV core antigen, and antibody fragments. The disclosure further relates to methods of detecting an analyte in a sample using a camelid antibody, such as a camelid VHH antibody or fragments thereof. In one aspect, provided herein is a technology platform for isolating highly specific antibodies and applying these antibodies in an immunoassay, such as a lateral flow immunoassay (LFIA). In some aspects, this technology is used to develop HCV core antigen specific antibodies and to produce LFIA devices for rapid and early diagnosis of HCV. In other aspects, a rapid test is provided for screening and detection of hepatitis C virus infection to improve the diagnosis rate and effectively prevent HCV infection transmission.

The present disclosure provides methods, kits, and compositions for detecting subject anti-HCV antibodies in a sample using NS3 capture peptides. In certain embodiments, at least two NS3 helicase (NS3h) capture peptides and at least two conjugate peptides (e.g., NS3h conjugate peptides) are employed together, which allows for a broad dynamic range of subject antibody detection in a one-step type assay. In other embodiments, methods are provided of detecting NS3-specific subject antibodies without the use of a reducing agent. In some embodiments, NS3-specific subject antibodies are detected with a double shot of NS3 conjugate peptide (e.g., conjugate peptide added to a sample both before and after washing).

Trapping devices and methods are provided for capturing a medical analyte, in blood or another biological fluid. The device may include a structural substrate and a binding agent, such as an antibody, affixed to the structural substrate, wherein the binding agent is capable of binding or attaching with a medical analyte, such as a viral particle, and the device is configured for placement in a biological cavity or vessel (containing a biological fluid) in a patient. The trapping device, which may be in a twisted coil shape, is configured to trap at least some of the medical analyte, such a viral particle, present in the biological fluid. The method may include deploying a trapping device into the patient's blood vessel; after a period following the deployment, removing the trapping device from the biological cavity or blood vessel; and then analyzing the trapping device for the presence of the medical analyte.

The present invention is directed to combination immunoassays, reagents and kits for simultaneous detection of HCV antigens and anti-HCV antibodies in a sample. The combination immunoassays of the present invention employ a non-ionic detergent that effectively exposes or releases the HCV core antigen from virions in a sample without interfering with the performance of other reagents such as the capture of anti-HCV antibodies by recombinant HCV antigens.

The present disclosure provides rapid and non-invasive methods for determining whether a patient will benefit from treatment with therapeutic agents that inhibit Hepatitis C virus (HCV). These methods are based on detecting HCV RNA and/or anti-HCV antibodies in small-volume dried biological fluid samples that are collected using a microsampling device. Kits for use in practicing the methods are also provided.

The present invention is directed to combination immunoassays, reagents and kits for simultaneous detection of HCV antigens and anti-HCV antibodies in a sample. The combination immunoassays of the present invention employ a non-ionic detergent that effectively exposes or releases the HCV core antigen from virions in a sample without interfering with the performance of other reagents such as the capture of anti-HCV antibodies by recombinant HCV antigens.

The present invention concerns materials and methods for characterizing monoclonal immunoglobulin specificity of a Monoclonal Gammopathy of Undetermined Significance (MGUS) or Myeloma patients using a protein microarray comprising (a) a substrate, (b) antigens immobilized on the substrate, said antigens being selected from a defined group consisting of infectious agent antigens and/or self-antigens. In particular said protein microarray may be used to improve diagnosis, for the prognosis of myeloma or MGUS, for preventing transformation of MGUS toward myeloma, for adapting treatment of MGUS and myeloma or for monitoring the response to therapy of MGUS and myeloma patients.