神经形态工程学
适体
生物芯片
纳米技术
多路复用
计算机科学
纳米孔
信号(编程语言)
信号处理
多路复用
材料科学
人工神经网络
DNA
纳米器件
纳米流体学
融合
人工智能
A-DNA
信息处理
DNA纳米技术
化学
分子识别
作者
Yonghuan Chen,Xinru Yue,Yixin Ling,Yang Liu,Weihua Yu,Qi Zhu,Zilong He,Minrui Long,Xin-Qi Hao,Xu Hou,Fengyu Li
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-02-03
卷期号:20 (6): 4855-4865
标识
DOI:10.1021/acsnano.5c16862
摘要
Bioinspired nanofluidic systems that utilize ions as signal carriers hold great promise for emulating neural processing in biochemical sensing and neuromorphic computing. However, achieving parallel, brain-like processing of multiple biochemical signals remains a significant challenge. Herein, we present a nanofluidic artificial postsynaptic membrane (APM) functionalized with confined DNA aptamers to construct a neuromorphic signal processing platform. Target-induced conformational switching of DNA aptamers dynamically modulates ionic transport through nanochannels, effectively mimicking synaptic information transmission. The integration of cross-responsive aptamer-based APM units into a cascaded logic system enables signal processing without relying on the physical series network of nanochannels. By independently addressing and reading each unit, dendritic multi-input integration and brain-like information fusion are achieved at the signal-algorithm level, and 100% accurate discrimination of multiple targets is reached. This approach marks a conceptual shift from the traditional "one-probe-one-target" model toward a brain-inspired, multitarget recognition architecture. The fusion of DNA probes with nanofluidic logic and their cascade at the signal level enables the development of neuromorphic biochips with integrated processing capabilities for multiplexed signals.
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