Researchers at the National Cancer Institute (NCI) have developed nucleic-acid-based nanoparticle that can be adapted for RNA interference (RNAi), molecular imaging, or a combination thereof. The invention nanoparticles can be used as therapeutics in the treatment of cancer, whichthe NCI seeks parties to license or co-develop.
Testing for biological activity of glucocorticoids and many other steroid endocrine-disrupting chemicals (EDCs) has not been previously performed. An automated, highly reproducible, and low cost assay detects biologically active steroidal EDCs and is suitable for wide application in testing water samples. The National Cancer Institute seeks partners for collaborative co-development research and/or licensing to move this technology into the public domain.
To improve the therapeutic effectiveness of PE-based immunotoxins through multiple rounds of drug administration, NIH inventors have sought to identify and remove the human B cell epitopes within PE. Previous work demonstrated that the removal of the murine B cell and T cell epitopes from PE reduced the immunogenicity of PE and resulted in immunotoxins with improved therapeutic activity. The National Cancer Institute's Laboratory of Molecular Biology seeks interested parties to co-develop and commercialize immunotoxins using toxin domains lacking human B cell epitopes.
The National Cancer Institute (NCI) seeks licensing and/or co-development of an adoptive cellular therapeutic modality that targets CCR4, which is overexpressed in certain lymphoid malignancies as well as solid tumors.
This licensing opportunity from the National Cancer Institute concerns the development of CARs comprising an antigen-binding fragment derived from the MGA271 antibody. The resulting CARs can be used in adoptive cell therapy treatment for neuroblastoma and other tumors that express CD276.
Chimeric Antigen Receptors (CARs) are engineered proteins that can be used in a therapeutic capacity when expressed by an immune cell (e.g., a T cell). Specifically, CARs comprise a targeting domain (such as an antibody or binding fragment thereof) as well as domains that activate immune cells. By selecting a targeting domain that binds to a protein that is selectively expressed on a cancer cell, it is possible to target immune cells to the cancer cells. Upon binding to the target cell, the immune cells are activated, leading to the destruction of the cancer cell. This therapeutic approach holds great promise, as evidenced by the recent FDA-approval of CAR-T cell therapies, KYMRIAH and YESCARTA, both of which target CD19.
Investigators at the National Cancer Institute have discovered fluoroquinolone derivatives as specific Tdp1 inhibitors that could potentiate the pharmacological action of Top1 inhibitors currently used in cancer treatment.
Cancer therapies that specifically target Glypican 2 (GPC2) are strong therapeutic candidates for pediatric patients with neuroblastoma and other GPC2 expressing cancers. The inventors at the National Cancer Institute (NCI) have developed and isolated two new antibodies that target GPC2 (CT3 and CT5) that are available for licensing and co-development.
Researchers at the National Cancer Institute (NCI) developed novel analogs of the natural product schweinfurthins to treat neurofibromatosis type 1 (NF1). The compounds demonstrate effective growth inhibition in malignant peripheral nerve sheath tumor cell lines and mouse models of astrocytomas. Researchers seek licensing and/or co-development research collaboration opportunities to further develop the schweinfurthin analogs.
Researchers at the National Cancer Institute (NCI) have developed peptidomimetic inhibitors that disrupt Polo-like kinase 1 (Plk1)-mediated protein interactions by targeting polo-box domain (PBD). These compounds are designed to selectively cause mitotic arrest in cancer cells with abnormal Plk1 expression. Researchers seek licensing and/or co-development research collaborations to further develop the inhibitors.
Investigators at the NCI discovered an Anti-TNF Induced Apoptosis (ATIA) protein, which protects cells against apoptosis. ATIA is highly expressed in glioblastoma and astrocytomas and its inhibition results in increased cell sensitivity to TNF-related apoptosis-inducing ligand induced cell death. The National Cancer Institute seeks parties interested in licensing or collaborative research to further develop, evaluate, or commercialize glioblastoma diagnostics and therapeutics.
Researchers at the National Cancer Institute (NCI) have developed an engineered storage unit for frozen tissue, that provides a permanent base on which to mount tissue frozen in OCT and an enclosure for storage. The unit provides for chain-of-custody labeling and acts as an insulating container to protect the specimen. Other elements include devices for freezing the tissue to the base, as well as a holder for the base to facilitate cryosectioning. Application of the storage system allows a frozen tissue specimen to be moved between storage and cryosectioning without loss of label, deformation of tissue, or thermal alterations.