稳健性(进化)
计算机科学
生物电子学
可扩展性
钥匙(锁)
人工智能
解码方法
人工神经网络
系统集成
控制工程
接口(物质)
信号处理
计算机体系结构
数码产品
机器人学
机电一体化
系统工程
自动化
深度学习
信号(编程语言)
计算机工程
工程类
机器学习
可穿戴计算机
数据交换
一般化
电子工程
神经假体
可用性
混合动力系统
多学科方法
分布式计算
作者
Sheng Wang,Xiaobin Song,Xiaopan Song,Yang Gu,Zhuangzhuang Cong,Yi Shen,Linwei Yu
出处
期刊:Nano-micro Letters
[Springer Science+Business Media]
日期:2026-01-11
卷期号:18 (1): 193-193
被引量:3
标识
DOI:10.1007/s40820-025-02042-2
摘要
The development of non-invasive brain-computer interfaces (BCIs) relies on multidisciplinary integration across neuroscience, artificial intelligence, flexible electronics, and systems engineering. Recent advances in deep learning have significantly improved the accuracy and robustness of neural signal decoding. Parallel progress in electrode design-particularly through the use of flexible and stretchable materials like nanostructured conductors and novel fabrication strategies-has enhanced wearability and operational stability. Nevertheless, key challenges persist, including individual variability, biocompatibility limitations, and susceptibility to interference in complex environments. Further validation and optimization are needed to address gaps in generalization capability, long-term reliability, and real-world operational robustness. This review systematically examines the representative progress in neural decoding algorithms and flexible bioelectronic platforms over the past decade, highlighting key design principles, material innovations, and integration strategies that are poised to advance non-invasive BCI capabilities. It also discusses the importance of multimodal data fusion, hardware-software co-optimization, and closed-loop control strategies. Furthermore, the review discusses the application potential and associated engineering challenges of this technology in clinical rehabilitation and industrial translation, aiming to provide a reference for advancing non-invasive BCIs toward practical and scalable deployment.
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