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Researchers at the University of Maryland have created hundreds of innovations that are available for licensing. Our Discovery Portfolio contains an exciting mix of vaccines, drug targets, therapeutics, devices and cutting edge techniques that promise to make a quantifiable impact on human health and the environment.
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Real Time in-situ Monitoring of Drug Product Degradation Using Water Proton NMR
Published Wednesday, May 17, 2023Summary This technology uses NMR spectroscopy to measure changes in the NMR signal of water, which is sensitive to changes in the chemical environment of the drug molecules it interacts with. This patented method allows for...
Investigator(s): Bruce Yu, Marc Taraban, Katharine Briggs
Categories: Devices, Diagnostics, Therapeutics, Small molecules, Biologics, Vaccines, Vaccine, Other
Keyword(s): NMR, Quality Control, vaccine, Drug Manufacturing, Freeze-Thaw
Docket: BY-2020-079
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Noninvasive Quantitation of Full Versus Empty Capsids Using Water Proton NMR
Published Wednesday, May 17, 2023Summary This invention proposes a method for using NMR relaxation rates to determine whether capsid preparations contain empty or full viral capsids and to quantify the capsid content of the preparation....
Investigator(s): Bruce Yu, Marc Taraban
Categories: Devices, Diagnostics, Therapeutics, Small molecules, Biologics, Vaccines, Vaccine, Other
Keyword(s): NMR, Quality Control, vaccine, Drug Manufacturing, Freeze Thaw
Docket: BY-2020-059
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Detection of Pharmaceutical Product Freezing History using Water Proton NMR
Published Wednesday, May 17, 2023Summary Researchers at UMB have created an innovative method that employs water proton nuclear magnetic resonance (NMR) spectroscopy to detect the freezing history of pharmaceutical products. This technology compares the...
Investigator(s): Bruce Yu, Marc Traban, Katharine Briggs
Categories: Devices, Therapeutics, Biologics, Vaccines, Vaccine, Other
Keyword(s): NMR, Quality Control, vaccine, Drug Manufacturing, Freeze-Thaw
Docket: BY-2019-081
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Selective RARγ Ligand-loaded Nanoparticles for Manipulation of Targeted Bone Growth
Published Wednesday, June 27, 2018Imbalance in bone length, caused by congenital conditions or fractures, can result in progressive deformity and physical problems. To date, the only way to adjust these bone length problems are surgical procedures. UMB researchers have identified a nuclear retinoid receptor, RARγ, which controls the rate of transition from cartilage to...
Investigator(s): Masahiro Iwamoto, Michael Chorny
Categories: Therapeutics, Other
Keyword(s): Orthopedics, Therapeutics Drug Delivery System
Docket: MI-2017-124