Please login to create your UC TechAlerts.
Request a new password for
Required
Find technologies available for licensing from all ten University of California (UC) campuses.
No technologies match these criteria. Schedule UC TechAlerts to receive an email when technologies are published that match this search. Click on the Save Search link above
Engineered Botulinum Neurotoxin for Therapeutic and Cosmetic Applications
This technology offers a significant improvement in the therapeutic application of type E botulinum neurotoxin (BoNT/E) by introducing rationally designed mutations into the receptor binding domain.
Ultrafast Light-Induced Inactivation of both Bacteria and Virus based on Bio-Affinity Ligands
Researchers at the University of California, Davis have developed an approach for the rapid inactivation of bacteria and virus using photo-active matrices enhanced with bio-affinity ligands under daylight irradiation conditions.
Polyphenol Infusions to Improve Gastro-Intestinal Stability of Probiotics
Researchers at the University of California, Davis have developed a method for improving probiotic resistance to conditions in the gastrointestinal tract by simultaneously delivering probiotics and extracts of fruit and vegetables rich in polyphenols which fight inflammation and improves health in the GI tract.
Time Varying Electric Circuits Of Enhanced Sensitivity Based On Exceptional Points Of Degeneracy
Sensors are used in a multitude of applications from molecular biology, chemicals detection to wireless communications. Researchers at the University of California Irvine have invented a new type of electronic circuit that utilizes exceptional points of degeneracy to improve the sensitivity of signal detection.
Tertiary Structure Of The Chlamydia Major Outer Membrane Protein (MOMP)
Researchers at UCI have discovered the tertiary structure of the Chlamydia major outer membrane protein (MOMP). Despite historical challenges in formulating an effective vaccine, recent advancements in understanding MOMP's structure offer new pathways for vaccine development against urogenital and ocular infections caused by C. trachomatis.
Adaptive Detection of the Stance Phases in Human Gait Cycles
This technology introduces a novel, cost-effective solution for improving the accuracy of pedestrian navigation systems under extreme conditions.
(SD2024-149) Strategy for pooled nuclear expressed antisense RNAs to identify consequential RNA processing events
Researchers from UC San Diego developed a new technology that facilitates pooling of nuclear expressed antisense RNAs (NEARs) to identify consequential RNA processing events such as alternative or constitutive RNA splicing or polyadenylation.This technology will identify a phenotype of interest and/or a group of RNA processing events (for example RNA splicing sites of interest or alternatively spliced exons), and transduce cells with a library of NEARs targeting these events. Applications include: Normal 0 false false false EN-US X-NONE X-NONE MicrosoftInternetExplorer4 /* Style Definitions */ table.MsoNormalTable {mso-style-name:"Table Normal"; mso-tstyle-rowband-size:0; mso-tstyle-colband-size:0; mso-style-noshow:yes; mso-style-priority:99; mso-style-parent:""; mso-padding-alt:0in 5.4pt 0in 5.4pt; mso-para-margin:0in; mso-pagination:widow-orphan; font-size:10.0pt; font-family:"Times New Roman",serif;} Research tool. As screens to identify exons of phenotypic relevance in a high throughput manner.Therapeutic target identification. To identify therapeutic targets of cancer cell suppression, such as poison exons in cancer specific transcripts.Therapeutic discovery. As a therapeutic agent to identify therapeutic NEARs for splicing related disorders.
Multilayer Pouch Robot And Manufacturing Method
Inflatable pouches are attractive as actuators and structural links in soft robots due to their low deflated profile and high deformation ratio. Particularly compelling for minimally invasive surgery, deflated robots/actuators may be deployed in small form factors and maneuver delicately in tight spaces once inflated. However, current fabrication methods do not readily scale for production of actuators with less than 1 mm feature sizes; they often require precision handling of separator films; and/or there are limited multilayer integration capabilities. Fully miniaturized, high degree-of-freedom surgical pouch robots and actuators have not yet been realized.To overcome these challenges, UC Berkeley researchers have developed a rapid, monolithic, and scalable manufacturing method for fabricating thin-film-based pneumatic pouch soft robots. Small features (less than 0.3 mm) can be patterned at high speeds and using commercially available manufacturing tools while maintaining film planarity. Resulting robots can have complex, multilayer structures including single- and bi-directional joint actuators, structural links, integrated in-plane air channels, through-holes for interlayer connectivity, and air inlets to a supply manifold—from a single integrated processing step. Researchers have demonstrated a miniature four finger hand which can dexterously manipulate a cube (8 degrees of freedom), as well as an 10 degree-of-freedom planar arm with a gripper which can maneuver around obstacles. Entire pouch robot structures can have un-inflated thickness of less than 300 um and be inherently soft, allowing the robots to be used in tight spaces with fragile tissues for surgical applications.