*Schools currently available: Cummings School of Veterinary Medicine, School of Dental Medicine, School of Engineering, The Fletcher School of Law and Diplomacy, Friedman School of Nutrition Science and Policy, School of Medicine, and Graduate School of Biomedical Sciences.
Silk-based injectable ceramic materials have been created. Due to their excellent biocompatibility and mechanical properties, they show great promise as injectable ceramic materials for orthopedic
JR-100 as a Novel Therapeutic Strategy for Tissue Repair in Chronic Neurodegenerative and Inflammatory DiseasesTufts cases: T001848-T000724-T001712Business Opportunity: Mercio (Pereira) Perrin, MD PhD
Tufts University investigators have developed a lithography resist that eliminates minimizes the use of harsh chemicals without sacrificing resolution. Optical-grade silk fibroin aqueous solution
HOMOPOLYMER TAIL MEDIATED LIGATION PCRInventors: David Lazinski and Andrew CamilliTufts Case # T001804InventionDrs. David Lazinski and Andrew Camilli, Tufts University School of Medicine, have
Download a .pdf version of this invention hereSummaryResearchers at Tufts University have developed an injectable silk biopolymer device to treat joint disease which incorporates the 1,2-Dioleoyl-sn
SummaryTufts University researcher, Jeff Hopwood, has developed a low-cost and high-efficiency source that allows plasma surface treatment at atmospheric pressure.SolutionsNon-thermal atmospheric
Identification of a novel therapeutic target for regeneration of the olfactory epitheliumLead Inventor: Dr. James E. SchwobTufts case T001754Business Opportunity: Olfactory dysfunction affects 25% of
Researchers at Tufts University have created a new class of high permeability polymeric membranes with anti-fouling properties. These thin film composite membranes feature a self-assembling copolymer
DESCRIPTIONDr. Charles Mace has designed a novel multilayered paper device. First, liquid sample is transported to chambers within the device with stored reagents. Then the liquid mixtures from the
DESCRIPTIONTufts investigator, Joshua Kritzer, has developed a novel high throughput assay, Chloroalkane Penetration Assay (CAPA), to quantitatively measure the compartment-specific cell penetration