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Knockout and Conditional Knockout Mice-GPR116

Pulmonary surfactant plays a critical role in preventing alveolar collapse by decreasing surface tension at the alveolar air-liquid interface. Surfactant deficiency contributes to the pathogenesis of acute lung injury (ALI) and acute respiratory distress syndrome (ARDS), common disorders that can afflict patients of all ages and carry a mortality rate greater than 25%. Excess surfactant leads to pulmonary alveolar proteinosis. NCI investigators created a G-protein coupled receptor GPR116 mutant mouse model and showed that GPR116 plays a previously unexpected, essential role in maintaining normal surfactant levels in the lung. The National Cancer Institute seeks partners interested in collaborative research to license surfactant modulating agents for the treatment of surfactant related lung disorders.

Assays for Measuring and Quantifying DNA Damage

The National Cancer Institute seeks partners interested in licensing or co-development of assays for determining the levels of gamma-H2AX/H2AX to measure and quantify DNA damage.

Modulating Chemotherapeutic Cytotoxicity

The NCI seeks partners interested in in-licensing or co-development collaboration on CD47-targeting therapeutics for cardioprotection and autophagy modulation.

Multifunctional RNA Nanoparticles as Cancer and HIV Therapeutics

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.

Mouse Xenograft Model for Mesothelioma

The National Cancer Institute is seeking parties interested in collaborative research to co-develop, evaluate, or commercialize a new mouse model for monoclonal antibodies and immunoconjugates that target malignant mesotheliomas. Applications of the technology include models for screening compounds as potential therapeutics for mesothelioma and for studying the pathology of mesothelioma.

Synthetic lipopeptide inhibitors of RAS oncoproteins

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.

Optical Microscope Software for Breast Cancer Diagnosis

Researchers from NCI and Rudgers University developed  methods of detecting abnormal cells in a sample using the spatial position of one or more genes within the nucleus of a cell, as well as a kit for detecting abnormal cells using such methods. The invention also provides methods of identifying gene markers for abnormal cells using the spatial position of one or more genes within the nucleus of a cell. The National Cancer Institute seeks parties interested in collaborative research to co-develop diagnostic methods for detection of cancer using spatial genome organization.

Novel Fixative for Improved Biomolecule Quality from Paraffin-Embedded Tissue

Researchers in the National Cancer Institute’s Laboratory of Pathology have developed an improved tissue fixative solution that is formaldehyde-free. This novel fixative, BE70, significantly improves DNA, RNA, and protein biomolecule integrity in histological samples compared to traditional fixatives. Additionally, BE70 is compatible with current protocols and does not alter tissue processing. NCI seeks partners to license this technology.

Device to guide oxygen over cells for photo-oxidation

Device is used to guide a stream of oxygen or carbon dioxide over a dish of cells during fluorescence microscopy. Invention includes the 3D printing software to create the device. The device makes it possible to easily provide a steady source of oxygen or carbon dioxide to cells while operating a fluorescent microscope to oxidize fluorophores for later visualization in electron microscopy. NCI seeks commercial partners to license this technology.

A Gene-Based Prognostic for Hepatocellular Carcinoma Patient Response to Adjuvant Transcatheter Arterial Chemoembolization

The gold standard of care for hepatocellular carcinoma patients with intermediate- to locally advanced tumors is transcatheter arterial chemoembolization (TACE), a procedure whereby the tumor is targeted both with local chemotherapy and restriction of local blood supply. NCI scientists have identified a 14-gene signature predictive of response to TACE, and NCI seeks licensees or co-development partners to develop the technology toward commercialization.

A549 Cells: Lung Carcinoma Cell Line for Adenovirus

Scientists at the National Cancer Institute have developed a cell line designated A549 that was derived from explanted cultures of human lung cancer tissue. The A549 cell line has been tested under the guidance of the United States Food and Drug Administration (FDA) so, under current Good Manufacturing Practices (GMP), these cells may be suitable for use in manufacturing constructs for use in clinical trials. The National Cancer Institute seeks parties to non-exclusively license this research material.

Genetically Engineered Mouse-Derived Allograft for Preclinical Studies of Metastatic Melanoma

Researchers at NCI have developed a means of more closely simulating in mouse models both melanoma cancer itself and the resulting physiological an immunological response by creating a genetically engineered mice (GEM)-derived allograft (GDA).  This allograft both resembles human-like melanoma and has features that will stimulate a normal immunological response in the mouse.

Anti-CD133 Monoclonal Antibodies as Cancer Therapeutics

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.

Anti-Py1235-Met Immunological Binding Reagent as Cancer Diagnostic

This technology consists of highly specific rabbit monoclonal antibodies reactive with phosphorylated tyrosine located at amino acid 1235 in the human MET sequence. Binding to this pYl235 residue is independent of the phosphorylation of other tyrosines in the vicinity (1230 and 1234), does not cross-react with these nearby phosphotyrosine residues, and does not occur when Y1235 is unphosphorylated. Researchers at the NCI seek licensing and/or co-development research collaborations  to commercialize and develop a companion diagnostic for selective MET inhibitors.

New T-Cell Immunotherapy that Targets Aggressive Epithelial Tumors

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.

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.

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