Owing to its close resemblance to biological systems and materials, soft matter has been
successfully implemented in numerous bioelectronic and biosensing applications, as well as …

Memristors have recently become powerful competitors toward artificial synapses and
neuromorphic computation, arising from their structural and electrical similarity to biological …

Neuromorphic electronics has demonstrated great promise in mimicking the sensory and
memory functions of biological systems. However, synaptic devices with desirable …

Flexible organic bioelectronic devices, which extract electronic signals from living systems,
have been developed for sensing, recording, and monitoring various physiological states of …

Bioinspired tactile devices can effectively mimic and reproduce the functions of the human
tactile system, presenting significant potential in the field of next‐generation wearable …

Herein we report a high-gain signal-on poly (3, 4-ethylenedioxythiophene): poly (styrene
sulfonate)(PEDOT: PSS) organic electrochemical transistor (OECT) biosensing using an …

Organic electrochemical transistors (OECTs) belong to the class of electrolyte gated organic
transistors (EGOTs) that offer a smooth interface with biology in combination with high …

The aqueous electrolyte can be a deformable and stretchable liquid material for iontronic
resistive memory devices. An aqueous medium makes a device closer to the brain‐like …

Neuromorphic devices that aim to revolutionize diverse fields, such as artificial intelligence
systems, brain-inspired computing, and neuroprosthetics, by efficiently processing complex …

The emulation of tactile sensory nerves to achieve advanced sensory functions in robotics
with artificial intelligence is of great interest. However, such devices remain bulky and lack …