The National Cancer Institute's Urologic Oncology Branch seeks interested parties to co-develop antagonists to VEGF-A and hepatocyte growth factor (HGF) that block signal transduction and associated cellular responses.
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.
There is a need to develop compounds that can sensitize cancer cells to apoptosis inducing ligands, such as poly I:C and TRAIL. In collaboration with the University of Arizona, NCI investigators discovered a series of compounds in the withanolide family that synergistically enhance the response of cancer cells to treatment with an apoptosis-inducing ligand. The NCI seeks licensing and/or co-development research collaborations for development of withanolide E analogues for the treatment of cancer.
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 present invention describes novel virus-like particles (VLPs) that are capable of binding to and replicating within a target mammalian cell, including human cells. The claimed VLPs are safer than viral delivery because they are incapable of re-infecting target cells. The National Cancer Institute's Protein Expression Laboratory seeks parties interested in licensing the novel delivery of RNA to mammalian cells using virus-like particles.
T cell receptors (TCRs) are proteins that recognize antigens in the context of infected or transformed cells and activate T cells to mediate an immune response and destroy abnormal cells. The National Cancer Institute's Surgery Branch seeks interested parties to license or co-develop the use of T cell receptors (TCRs) cloned against the SSX-2 antigen for the treatment of cancer.
The National Cancer Institute’s Laboratory of Immune Cell Biology seeks partners interested in licensing or collaborative research to co-develop peptide-based therapeutics for inflammatory autoimmune conditions or inflammatory cancers.
It is well known that overactive Ras signaling is linked to many forms of cancer, and despite intensive efforts worldwide to develop effective inhibitors of Ras, to date there is no anti-Ras inhibitor in clinical use.
Researchers at the NCI’s Cancer and Inflammation Program, in collaboration with scientists at Vanderbilt University and the University of Illinois in Chicago, have identified a number of small peptidomimetic compounds that bind to Ras proteins with nanomolar affinity. NCI’s Cancer and Inflammation Program seeks partners interested in licensing or co-development of synthetic, highly potent cell-permeable inhibitors of Ras that bind to the protein directly.
The National Cancer Institute’s Laboratory of Experimental Immunology seeks partners interested in licensing or collaborative research to co-develop monoclonal antibodies and ADCs, and methods of making them.
The promise of RNA interference based therapeutics is made evident by the recent surge of biotechnological drug companies that pursue such therapies and their progression into human clinical trials. The present technology discloses novel RNA and RNA/DNA nanoparticles including multiple siRNAs, RNA aptamers, fluorescent dyes, and proteins. The National Cancer Institute sees parties interested licensing this technology or in collaborative research to co-develop RNAi-based nanoparticle therapeutics for cancer and HIV.
Researchers at NCI developed a rabbit monoclonal antibody that recognizes the marker for CD133 and is useful in pharmacodynamic testing to inform targeted anti-cancer chemotherapy development and clinical monitoring. CD133 is a cell surface glycoprotein used as a marker and expressed in stem cells such as hematopoietic stem cells, endothelial progenitor cells and neural stem cells. The NCI seeks collaborative co-development or licensing partners for this technology.
Researchers at the National Cancer Institute’s Experimental Transplantation and Immunology Branch (NCI ETIB) developed a T Cell receptor that specifically targets the Kita-Kyushu Lung Cancer Antigen 1 (KK-LC-1) 52-60 epitope that is highly expressed by several common and aggressive epithelial tumor types.
Engineered bacterial spores can provide many useful functions such as the treatment of infections, use as an adjuvant for the delivery of vaccines, and the enzymatic degradation of environmental pollutants. Researchers at the National Cancer Institute’s Laboratory of Molecular Biology have developed a novel, synthetic spore husk-encased lipid bilayer (SSHEL) particle that is uniquely suited for a variety of these functions. NCI seeks partners to license and/or co-develop this technology toward commercialization.
Researchers at the National Cancer Institute (NCI) have developed a technology that provides methods of performing adoptive cell transfer (ACT), an immunotherapeutic approach for cancer treatment, by administering a heterodimeric Interleukin 15/Interleukin 15 receptor alpha (IL-15/IL-15Rα) complex (hetlL-15) in the absence of lymphodepletion, thereby eliminating any lymphodepletion-associated detrimental side effects.
The National Cancer Institute Laboratory of Molecular Biology is seeking statements of capability or interest from parties interested in licensing or collaborative research to further develop, evaluate, or commercialize antibody-based treatments of mesothelin-expressing cancers.
Researchers at the National Cancer Institute (NCI) RNA Biology Laboratory have developed nanoparticles that can deliver an agent (i.e., therapeutic or imaging) and release the agent upon targeted photoactivation allowing for controlled temporal and localized release of the agent.