Hydrogel electrodes for interfacing with tissue
Conductive and elastic hydrogel-based microelectronic arrays with high current-injection density and low interfacial impedance with tissue enable the localized low-voltage electrical stimulation of the sciatic nerve in live mice.
Published in Bioengineering & Biotechnology
Like
Be the first to like this
Chief Editor, Nature Biomedical Engineering, Nature Research
Follow the Topic
Biotechnology
Life Sciences > Biological Sciences > Biotechnology
-
Nature Biomedical Engineering
This journal aspires to become the most prominent publishing venue in biomedical engineering by bringing together the most important advances in the discipline, enhancing their visibility, and providing overviews of the state of the art in each field.
Related Collections
With Collections, you can get published faster and increase your visibility.
Implantable wireless communication technologies
This collection brings together research that addresses critical engineering challenges in implantable wireless communications. It demonstrates how electromagnetic, optical, acoustic, or hybrid methods can be engineered to achieve reliable wireless communications and power delivery through biological tissues.
Publishing Model: Hybrid
Deadline: Nov 28, 2026
Medical Ultrasound: Emerging Techniques and Applications
This cross-journal Collection showcases the broad and exciting field of emerging techniques and applications in medical ultrasound.
Publishing Model: Hybrid
Deadline: Jan 29, 2027
Please sign in or register for FREE
If you are a registered user on Research Communities by Springer Nature, please sign in
The cover illustrates a hydrogel-based polymer-encapsulated microelectrode array pressed against soft jelly.
See Liu et al.
Image: Amir M. Foudeh, Yuxin Liu, Jia Liu and Zhenan Bao, Stanford University. Cover design: Alex Wing.