Researchers at the University of California, Davis have developed a framework that enables autonomous systems to plan paths while accounting for how their actions influence surrounding actors. Unlike existing approaches that rely on reactive planning with fixed predictions or on computationally intensive multi-agent formulations, this technology uses a structured, data-driven interaction model within a tractable theoretical framework. The approach is designed for real-time deployment and supports analyzable performance and safety behavior under defined conditions. It enables more adaptive navigation in environments shared with people or other intelligent machines, improving operational efficiency, safety margins, and integration potential across a range of autonomous products.

Researchers at the University of California, Davis have developed a system and method to continuously separate granular material mixtures based on differences in their frictional properties using non-antiperiodic vibratory excitation.

Professor Iman Noshadi at the University of California, Rivrside, has developed the BIJEL-integrated PORous Engineered System (BIPORES), a novel biomaterial platform that overcomes the limitations of conventional tissue engineering scaffolds. The BIPORES system is a PEGDA-based material engineered to exhibit an unrestricted, highly bicontinuous interconnected porous framework characterized by uniform pore diameter and optimal surface contour. This technology is potentially advantageous because the distinctive structural characteristics of these PEGDA‐BIPORES‐based biomaterials promote cell homing, attachment, infiltration, proliferation, differentiation, and tissue integration without immune reaction. Fig. 1: Scanning electron micrographs of the UCR BIOPORES porous meshwork. Arrangement of the fabricated multi-fibrous scaffolds is shown (top)along with the characteristic bicontinuous interconnected porous ultrastructure (bottom).

Researchers at the University of California, Davis have developed a modular CRISPR activation platform that enables precise upregulation of the haploinsufficient gene FOXG1 to address neurodevelopmental disorders without DNA cleavage.

A mechanistic discovery linking amyloid beta (Aβ)-associated neurodegeneration with chronic pain after peripheral nerve injury, revealing Aβ as a novel therapeutic target.

Researchers at the University of California, Davis have developed a modular, containerized cooling solution designed to support high‑density computing environments such as data centers and AI clusters. The system combines efficient air‑to‑liquid heat exchange, integrated energy storage options, and intelligent controls to reduce operating costs, improve deployment speed, and enhance system uptime.

Brief description not available

Brief description not available