In the book entitled Microfluidic Systems for Cancer Diagnosis, the UPV/EHU’s Microfluidics Cluster group describes the process for building a bioelectronic device consisting of gold electrodes coated ...
The Universitat Autònoma de Barcelona (UAB) and the Institute of Microelectronics of Barcelona (IMB-CNM-CSIC) have developed ...
A chance discovery led a team of scientists from Rice University, University of Cambridge and Stanford University to streamline the production of a material widely used in medical research and ...
Bioelectronics, such as implantable health monitors or devices that stimulate brain cells, are not as soft as the surrounding tissues due to their metal electronic circuits. A team of scientists from ...
Plants convert light into energy efficiently through photosynthesis—an ability that scientists and engineers still struggle to match with electronic devices. Recently, researchers have looked beyond ...
Peripheral nerves—the network connecting the brain, spinal cord, and central nervous system to the rest of the body—transmit sensory information, control muscle movements, and regulate automatic ...
Early bioelectronics were rigid, bulky devices like pacemakers that did their jobs but didn’t mesh well with flesh. In recent years, scientists have created bioelectronic sensors and stimulators made ...
Bioelectronic devices, neural interfaces, biosensors and AI hardware are now easier to make thanks to a streamlined method for fabricating a key material. A chance discovery led a team of scientists ...
Metastasis is the leading cause of death in cancer, occurring when a cell leaves the primary tumour, passes into the bloodstream and lymphatic system and reaches distant organs. Non-invasive ...