The Biorepositories and Biospecimen Research Branch (BBRB) at the National Cancer Institute (NCI) has sponsored various initiatives for conducting biospecimen research. Through these initiatives, NCI seeks to advance biospecimen science and improve research reproducibility by investigating how different biospecimen collection, handling and processing procedures affect biospecimen molecular profiles. BBRB is seeking collaborators to extend these studies.
Pre-clinical radiotracer biomedical research involves the use of compounds labeled with radioisotopes, including radio-ligand bio-distribution studies, cell binding studies, immune cell labeling techniques, and α-based therapies. Before this Micro-Dose Calibrator, measurement of pre-clinical level dosage for small animal studies was inaccurate and unreliable. This dose calibrator is a prototype ready for customer testing and scale-up. It is designed to accurately measure radioactive doses in the range of 50 nCi (1.8 kBq) to 100 µCi (3.7 MBq) with 99% precision. The NCI seeks co-development or licensing to commercialize it. Alternative uses will be considered.
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.
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.
Scientists at the National Cancer Institute (NCI) developed a novel stealth lipid-based nanoparticle formulation comprising phospholipid, DC8,9PC and a polyethylene glycol-ated (PEGylated) lipid – such as DSPE-PEG2000 – that efficiently package a high amounts of hydrophobic photodynamic drug (PDT) – such as HPPH – in stable vesicles. This HPPH-loaded liposome system demonstrates higher serum stability and ambient temperature stability upon storage. It exhibits increased tumor accumulation and improved animal survival in mice tumor models compared to the formulation in current clinical trials. The NCI seeks co-development partners and/or corporate licensees for the application of the technology as an anti-cancer therapeutic.
Surgery specialists from Johns Hopkins University, in collaboration with researchers at the National Cancer Institute (NCI), developed peptide hydrogel compositions and methods to suture blood vessels during microsurgery. The hydrogels particularly benefit surgeons in whole tissue transplant procedures. The NCI seeks co-development research collaborations for further development of this technology.
Researchers at the National Cancer Institute (NCI) seek research & co-development and/or licensees for a novel, ex vivo method by which stem cell-like memory T cells (Tscm) can be generated by stimulating naïve T cells in the presence of inhibitors of GSK-3beta, which are capable of activating the Wnt pathway. These Tscm cells, generated using GSK-3beta inhibitors, display enhanced survival and proliferation upon transfer, have multipotent capacity to generate all memory and effector T cell subsets, and show increased anti-tumor activity in a humanized mouse tumor model.
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.
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.
Scientists at the National Cancer Institute (NCI) have developed a novel delivery platform in which the scaffold of an anionic hydrogel (AcVES3) can be attenuated to deliver therapeutic small molecules, peptides, proteins, nanoparticles, or whole cells. The NCI seeks collaborators and licensees for the development of this technology in various clinical and laboratory applications.
Researchers at the National Cancer Institute (NCI) developed a potential nucleic acid-based therapy using an inducible activation nucleic acid hybrid switch for conditional generation of oligonucleotides. The NCI is looking for innovative companies interested in co-developing and/or licensing this technology.
Pluripotent stem cells are a promising source of T cells for a variety of clinical applications. However, current in vitro methods of T cell differentiation result in the generation of cells with aberrant phenotypes. Researchers at the National Cancer Institute (NCI) have now developed methodology for generating induced pluripotent stem cell thymic emigrants (iTE). Antigen-specific CD8αβ+ iTEs exhibited functional properties in vitro that were almost indistinguishable from natural naïve CD8αβ+ T cells, including vigorous expansion and robust anti-tumor activity. iTEs recapitulated many of the transcriptional programs of naïve T cells in vivo and revealed a striking capacity for engraftment, memory formation, and efficient tumor destruction. The NCI seeks licensing and/or co-development research collaborations for this invention.