Self-Adhesive, Stretchable, and Thermosensitive Iontronic Hydrogels for Highly Sensitive Neuromorphic Sensing-Synaptic Systems.
Xuedan ChenLong ChenJianxian ZhouJiajun WuZhixun WangLei WeiShuanglong YuanQichong ZhangPublished in: Nano letters (2024)
Artificial sensory afferent nerves that emulate receptor nanochannel perception and synaptic ionic information processing in chemical environments are highly desirable for bioelectronics. However, challenges persist in achieving life-like nanoscale conformal contact, agile multimodal sensing response, and synaptic feedback with ions. Here, a precisely tuned phase transition poly( N -isopropylacrylamide) (PNIPAM) hydrogel is introduced through the water molecule reservoir strategy. The resulting hydrogel with strongly cross-linked networks exhibits excellent mechanical performance (∼2000% elongation) and robust adhesive strength. Importantly, the hydrogel's enhanced ionic conductance and heterogeneous structure of the temperature-sensitive component enable highly sensitive strain information perception (GF max = 7.94, response time ∼ 87 ms), temperature information perception (TCR max = -1.974%/°C, response time ∼ 270 ms), and low energy consumption synaptic plasticity (42.2 fJ/spike). As a demonstration, a neuromorphic sensing-synaptic system is constructed integrating iontronic strain/temperature sensors with fiber synapses for real-time information sensing, discrimination, and feedback. This work holds enormous potential in bioinspired robotics and bioelectronics.
Keyphrases
- drug delivery
- hyaluronic acid
- health information
- mass spectrometry
- wound healing
- prefrontal cortex
- tissue engineering
- ms ms
- multiple sclerosis
- ionic liquid
- fluorescent probe
- social media
- risk assessment
- regulatory t cells
- immune response
- healthcare
- living cells
- molecularly imprinted
- drug release
- solid state
- human health
- tandem mass spectrometry
- solid phase extraction