Researchers at the NCI have developed a urine-based diagnostic platform capable of predicting the onset of cancer. This high-throughput screening method quantifies metabolites to assess cancer risk, determine disease prognosis and monitor response to therapy.
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.
This invention identifies two polymorphic genetic markers in the SLCO1B3 (formerly SLC21A8) gene, called 334T>G and 699G>A, that can be measured in genomic DNA obtained from a blood sample to predict survival from diagnosis of prostate cancer in that individual patient.
The NCI Radiation Oncology Branch and the NHLBI Laboratory of Single Molecule Biophysics seek parties to co-develop fluorescent nanodiamonds for use as in vivo and in vitro optical tracking probes toward commercialization.
The NCI seeks licensees or co-development partners for this technology, which describes compositions, methods and kits for identifying, characterizing biomolecules expressed in a sample that are associated with the presence, the development, or progression of cancer.
Researchers at the NICHD seek licensing and/or co-development research collaborations for a Magnetic Resonance Imaging (MRI) method to quantitatively measure in vivo the estimated conduction time of nerve impulses in the brain.
Investigators at the National Cancer Institute discovered a set of biomarkers that can identify patients with early stage lung cancer who are at a high risk of relapse. These prognostic methods can guide physicians to select appropriate treatment and follow-up while sparing other patients of unnecessary treatment and negative side-effects of chemotherapy. The NCI seeks parties to license or co-develop the invention.
The National Cancer Institute seeks licensees and/or co-development partners for methods that provide significant improvements in examining clinically relevant tissue samples, by improving spatial resolution and tissue depth using optical trapping.
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.
Researchers at the NCI developed a non-invasive method for distinguishing benign from malignant adrenocortical tumors using urine samples. The NCI seeks parties to co-develop a non-invasive, diagnostic method of distinguishing between benign and malignant adrenocortical tumors through the analysis of metabolites using urine samples.
Scientists from the Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD) have developed a novel diffusion Magnetic Resonance Imaging (MRI) experimental and modeling framework to measure new and useful microanatomical features of white matter (and gray matter), which are closely related to the function of the central nervous system (CNS) or peripheral nervous system (PNS). This invention is available for licensing or co-development partners.
NCI scientists developed a method that uses urine samples to detect early-stage cancers and that could supplement low-dose computed tomography (LD-CT) to significantly decrease its expensive false negative/false positive results, and the NCI seeks co-developers or licensees to commercialize this technology.
Researchers at the National Cancer Institute (NCI) developed novel groups of cyanine (Cy) based antibody-drug conjugate (ADC) chemical linkers that undergo photolytic cleavage upon irradiation with near-IR light. By using the fluorescent properties of the Cy linker to monitor localization of the ADC, and subsequent near-IR irradiation of cancerous tissue, drug release could be confined to the tumor microenvironment.