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Method for Targeted Therapeutic Delivery of Proteins into Cells

The Protein Expression Laboratory at the National Cancer Institute in Frederick, MD is seeking statements of capability or interest from parties interested in collaborative research to further develop a platform technology for the targeted intra-cellular delivery of proteins using virus-like particles (VLPs).

Methods of preventing tissue ischemia

The National Cancer Institute's Laboratory of Pathology seeks parties interested in licensing or collaborative research to co-develop therapeutics targeting vasodialation.

Synthetic Bacterial Nanoparticles as Drug and Vaccine Delivery Vehicles

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.

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

Researchers at the National Institutes of Health have identified a collection of TCRs that specifically target mutated KRAS antigen. These TCRs exclusively recognize the G12D or G12V variants of mutated KRAS, which are common hotspot driver mutations 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 HLA-A*11:01 or HLA-C*08:02. These TCRs can be used for a variety of experimental therapeutic, diagnostic and research applications.

T Cell Receptors Targeting p53 Hotspot Mutations and Methods of Isolating the Same

Researchers at the National Cancer Institute (NCI) identified a collection of T Cell Receptors (TCRs) that target specific mutations in the p53 tumor suppressor protein. These TCRs recognize “hotspot” mutations, which frequently occur in a variety of unrelated cancers. These TCRs can be used for a variety of therapeutic, diagnostic and research applications. Researchers at the NCI seek licensing and/or co-development research collaborations for these novel T cell receptors that recognize p53 mutations and methods for identifying p53 mutation-reactive T cell receptors.

RP2 and RPGR Vectors For Treating X-linked Retinitis Pigmentosa

The National Eye Institute (NEI) seek research co-development or licensees for advancing AAV8/9-based therapies for X-linked forms of retinitis pigmentosa (XLRP) caused by mutations in RPGR (retinitis pigmentosa GTPase regulator) or RP2 (retinitis pigmentosa 2) gene.

Newly Improved Method and Composition for Treating Genetically Linked Diseases of the Eye

To improve the transduction efficiency the inventors at the National Eye Institute (NEI) have developed a novel, non-invasive approach of applying electric current in combination with a gene therapy vector. This minimally invasive strategy significantly improves the transduction efficiency of AAV vectors in the mouse retina. This represents an improved method for restoring high levels of RS1 expression in the retina of X-linked retinoschisis (XLRS) patients. The NEI seeks a licensing and/or co-development partner to commercialize its AAV-RS1 Gene Therapy for XLRS.

Design and Biological Activity of Novel Stealth Polymeric Lipid Nanoparticles for Enhanced Delivery of Hydrophobic Photodynamic Therapy Drugs

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.

Topical Antibiotic for Faster Wound Healing

Currently available topical antibiotic formulations effectively eliminate bacteria at a wound site. Eliminating bacteria in the wound also eliminates the molecular signals present in bacterial DNA that stimulate the immune system's wound healing processes. Without these signals, the rate of wound healing is diminished.  The National Cancer Institute Laboratory of Experimental Immunology seeks parties interested in licensing or collaborative research to further co-develop a topical antibiotic formulation to accelerate wound healing.

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