Amazing talks by Prof. Wei Gao, Prof. Sahika Inal, and Prof. Shiming Zhang at the iCanX HK Summit! It was an honor to host the session. Looking ahead to the next event! #Bioelectronics, #iCanX

Great to host Prof. Sahika Inal @InalSahika for an inspiring lecture on mixed-conducting polymers and OECTs for bioelectronics! @KAUST @HKUniversity

Truly a focused symposium visioning the future of BME in different views. During our plenary talk, we share our views on wearable bioelectronics: materials, devices, and AI-embedded hardware-software co-design.

New therapeutic brain implants could defy the need for surgery MIT researchers have developed microscopic, wireless bioelectronics that could travel through the body’s circulatory system and autonomously self-implant in a target region of the brain, where they would provide

Happy to share our paper published in Biosensors and Bioelectronics: X, showing a wireless, face-wearable, bioelectronic system designed to continuously capture electrooculograms and electromyograms for for diagnosis of blepharospasm; https://t.co/uDa4mHOtF4

Happy to share our paper published in Biosensors and Bioelectronics. With @EmoryMedicine collaborators, this work develops a battery-free, implantable arteriovenous graft featuring a wireless pressure sensor designed for real-time stenosis detection; https://t.co/SHInUf5mMx

AI-based system offers insights on how polymers can be engineered for use in next-generation bioelectronics “…such as light-harvesting devices and implantable electronics that interact with the nervous system.” https://t.co/5lI1woVmR0

UK researchers developing glucose-powered bioelectronics https://t.co/pNQsYYQD8F #medtech #bioelectronics

📣 New Podcast! "Fungal Computers, Hydrogen Tractors, and Restoring Sight w/ Ralph Bond" on @Spreaker #ai #autonomous #batteries #bioelectronics #computers

Excited to share our paper published in Biosensors and Bioelectronics, "Advances in Flexible High-Density Microelectrode Arrays for Brain-Computer Interfaces" https://t.co/SLTofAPc2o. We discuss recent advances and the challenges associated with brain-computer interface systems.

⚡ This Is Big: A Breakthrough in Wireless Bioelectronics MIT scientists have developed the world’s tiniest injectable antenna — small enough to fit through a syringe yet powerful enough to wirelessly energize deep-tissue implants. The device, a sub–0.5 mm magnetoelectric

InnoLAE 2026 Invited Speaker Prof Róisín Owens, University of Cambridge, will give a talk entitled "Conducting polymer devices to study the gut-brain axis". See more at: https://t.co/YtlhJe0mrO #bioelectronics

MIT researchers have developed microscopic, wireless bioelectronics that could travel through the body’s circulatory system and autonomously self-implant in a target region of the brain to provide focused treatment. This work used facilities at MIT.nano!

The Merging of Biological and Electronic Circuits 2020 Oct 15 https://t.co/mcgRid3tuk Keywords: Bioelectronics, Engineering, Electrical Engineering

Bioelectronics: Bridging Biology and Technology for Next- generation Healthcare https://t.co/cvz0vESLAl

Design and Manufacturing of Piezoelectric Biomaterials for Bioelectronics and Biomedical Applications https://t.co/zndlhov1JQ

Call For Papers Deadline Extended! Due to a number of requests, we have extended our Call for Papers deadline. Submit your abstract for innoLAE 2026 by 14 November 2025 for the opportunity to present your work. https://t.co/KMYuHoL8gm #flexibleelectronics #bioelectronics

Fungal Memristors: Mushroom Networks Power the Future of Bioelectronics https://t.co/2H8T403l86 #MaterialInspiration #Materials #Bioelectronics #MaterialInnovation #BiobasedDesign #SustainableTechnology #CircularDesign #FungalMaterials #SmartMaterials #MushroomTech

Wonderful day and a half here in Cagliari, Sardinia (Italy) for the BE-Flex (Bioelectronics in Flexible Technologies) conference, where I delivered a keynote presentation titled “Bioelectronics Technologies as Epidermal and Neural Interfaces,” covering our work on two classes of