The National Cancer Institute is seeking statements of capability or interest from parties interested in collaborative research to co-develop antibody-based therapeutic against MERS-CoV, including animal studies, cGMP manufacturing, and clinical trials.
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.
NCI seeks partners to commercialize Griffithsin and Griffithsin tandemers as therapeutics for HIV infections that are resistant to native GRFT, specifically, additional studies on stability, toxicity, immunogenicity, and large-scale production.
RNA interference (RNAi) is a naturally occurring cellular post-transcriptional gene regulation process that utilizes small double-stranded RNAs to trigger and guide gene silencing. By introducing synthetic RNA duplexes called small-interfering RNAs (siRNAs), we can harness the RNAi machinery for therapeutic gene control and the treatment of various diseases. The National Cancer Institute seeks partners to license or co-develop RNA, RNA-DNA, and DNA-RNA hybrid nanoparticles consisting of a DNA or RNA core with attached RNA or DNA hybrid duplexes.
IFN-gamma and IL-10 are cytokine signaling molecules that play fundamental roles in inflammation, cancer growth and autoimmune diseases. Unfortunately, there are no specific inhibitors of IFN-gamma or IL-10 on the market to date. The National Cancer Institute seeks parties interested in licensing or collaborative research to co-develop selective IL-10 and IFN-gamma peptide inhibitors.
The National Cancer Institute (NCI) Molecular Targets Laboratory is seeking parties interested in collaborative research to co-develop antiviral tropolone derivatives developed by systematic medicinal chemistry on the lead series.
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.
Scientists at the National Cancer Institute's Molecular Targets Laboratory have discovered that Cnidarins as a novel class of highly potent proteins capable of blocking the HIV virus from penetrating T-cells. The National Cancer Institute seeks parties interested in collaborative research to license or co-develop large-scale recombinant production of cnidarins.
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 the National Cancer Institute discovered small-molecule compounds containing 1-hydroxy-2-oxo-1,8-naphthyridine moieties whose activity against HIV-1 integrase mutants confer resistance to currently approved INSTIs. Preliminary rodent efficacy, metabolic, and pharmacokinetic studies have been completed by the NCI researchers. The National Cancer Institute seeks partners to commercialize this class of compounds through licensing or co-development.
Tuberculosis (TB) is an infectious disease that typically affects the lungs. Current therapies include a panel of antibiotics given over a range of 6-9 months. As a result of the expense of treatment, the extended timeframe needed for effective treatment, and the scarcity of medicines in some developing countries, patient compliance with TB treatment is very low and results in multi-drug resistant TB (MDR-TB). There remains a need for a faster, more effective treatment for TB. NCI researchers seek licensing and/or co-development of peptide inhibitors of STAT3 and IL-10 developed to treat bacterial infections such as tuberculosis. See aslo: NIH inventions E-164-2007 and E-167-2010
Scientists at the National Cancer Institute's Molecular Targets Laboratory have modified the Cnidarin-derived griffithsin compound to have greater storage time and stability. Griffithsin compounds are a class of highly potent proteins capable of blocking the HIV virus from penetrating T cells. The National Cancer Institute seeks parties interested in collaborative research to license or co-develop large-scale recombinant production of the compound.
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 or co-develop this technology toward commercialization.
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.
Researchers at NCI's Cancer and Inflammation Program developed fully human monoclonal antibodies that bind and neutralize dengue type 1, 2, 3 and 4 viruses. The National Cancer Institute's Cancer and Inflammation Program seeks parties interested in licensing fully human monoclonal antibodies as possible therapeutics and prophylactics, as well as a template for a Dengue vaccine.
Researchers at the NCI have developed a method of improving the immune response in cancer immunotherapy by exploiting in the role of the Linker Adapted for T-Cell Signaling (LAT) molecule. The LAT molecular can enhance signaling through TCRs, thus, improving a patient’s own immune response to cancer or infectious diseases.
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.