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 ...

Soft bioelectronic devices can be interfaced with anatomically curved organs, such as the heart, brain and skin, to provide continuous analysis of physiological information. However, body movements ...

The autonomic nervous system (ANS) dynamically regulates vasomotor function to maintain vascular homeostasis, yet current clinical tools lack the capacity to capture its electrophysiological basis, ...

Breakthrough recorded neural activity with high clarity and remained safely functional for 18 months without a drop in ...

The rapidly advancing field of neuroimmunology has revealed that the nervous, immune, and endocrine systems maintain continuous, bidirectional communication ...

A new hydrogel electrolyte enables fast, low-power solid-state circuits for implantable bioelectronics, offering high precision, stability, and compatibility with complex neural systems. (Nanowerk ...

Brain–computer interfaces are technologies that enable direct communication between brain activity and external devices, enabling researchers to monitor and interpret brain signals in real time. These ...

Bioengineering researchers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) have developed a soft, thin, stretchable bioelectronic device that can be implanted into a ...