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Showing 1-14 of 14 results found

Dual Specific Anti-CD22 Anti-CD19 Bicistronic Chimeric Antigen Receptors (CARs)

Inventors at the National Cancer Institute (NCI) have developed chimeric antigen receptors (CARs) that target two B cell surface antigens, CD19 and CD22, improving treatment of B-cell malignancies, such as acute lymphoblastic leukemia (ALL). NCI is actively seeking parties interested in licensing this invention to commercialize the bicistronic CAR construct targeting CD19 and CD22 for immunotherapy.

SLCO1B3 Genotyping to Predict a Survival Prognosis of Prostate Cancer

This invention identifies two polymorphic genetic markers in the SLCO1B3 (formerly SLC21A8) gene, called 334T>G and 699G>A, that can be measured in genomic DNA obtained from a blood sample to predict survival from diagnosis of prostate cancer in that individual patient.

Non-invasive diagnostic and prognostic assay for early stage lung cancer

NCI scientists developed a method that uses urine samples to detect early-stage cancers and that could supplement low-dose computed tomography (LD-CT) for early-stage cancer detection, and significantly decrease expensive false negative/false positive results. The NCI seeks co-developers or licensees to commercialize this technology.

Clinical Outcome Predictors for Mantle Cell Lymphoma

The invention is a novel methodology for predicting a mantle cell lymphoma (MCL) cancer patient’s survival prognosis. This information is important in helping determine the best course of treatment for the patient.

T Cell Receptors Targeting KRAS Mutants for Cancer Immunotherapy/Adoptive Cell Therapy

Researchers at the National Institutes of Health identified a collection of TCRs that exclusively recognize the common hotspot driver mutations in KRAS antigen, expressed by a variety of epithelial cancers, including pancreatic, colorectal and lung cancer. The mutated KRAS variants are recognized by the TCRs in the context of specific Class I/Class II HLA alleles. These TCRs can be used for a variety of experimental therapeutic, diagnostic and research applications.

Diagnostic Assay for Determining Patient Response to Apoptosis-related Cancer Therapy

Researchers at the National Cancer Institute (NCI) developed a multiplex assay to determine the efficacy of apoptosis-related drugs targeting the Bcl2 family of proteins or aid in the selection of cancer patients likely to respond. The NCI seeks partners for co-development or licensees for commercialization of novel immunoassays for determining or predicting patient response to cancer therapy.

T-Cell Therapy Against Patient-Specific Cancer Mutations

Scientists at the National Cancer Institute developed a method to identify T cells that specifically recognize immunogenic mutations expressed only by cancer cells. NCI seeks parties interested in collaborative research to co-develop or license T-cell therapy against cancer mutations

T-Cell Therapy Against Patient-Specific Cancer Mutations

Scientists at the National Cancer Institute's Surgery Branch developed a method to identify T cells that specifically recognize immunogenic mutations expressed only by cancer cells. The NCI seeks parties interested in collaborative research to co-develop or license T-cell therapy against cancer mutations.

T Cell Receptors Targeting p53 Mutations for Cancer Immunotherapy and Adoptive Cell Therapy

Researchers at the National Cancer Institute identified a collection of TCRs that exclusively recognize the common hotspot driver mutations in p53 tumor suppressor, expressed by a variety of human cancers, including colorectal, breast and lung cancers. The mutated p53 variants are recognized by the TCRs in the context of specific Class I/Class II HLA alleles. These TCRs can be used for a variety of experimental therapeutic, diagnostic and research applications.'

Methods of analyzing virus-derived therapeutics

Researchers at the National Cancer Institute’s Biopharmaceutical Development Program recently developed massively parallel sequencing methods for virus-derived therapeutics such as viral vaccines and oncolytic immunotherapies, for which the NCI seeks licensees or co-development collaborations.

Oligonucleotide Production Process

This technology provides improved processes for production and purification of nucleic acid-containing compositions, such as non-naturally occurring viruses, for example, recombinant polioviruses that can be employed as oncolytic agents. Some of the improved processes relate to improved processes for producing viral DNA template.