神经元尖峰的启发式自适应阈值检测方法

IF 1.1 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

IET Signal Processing Pub Date : 2023-04-24 DOI:10.1049/sil2.12214

Dechun Zhao, Shuyang Jiao, Huan Chen, Xiaorong Hou

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引用次数: 0

摘要

近年来，微电极阵列和多通道记录的发展为信号处理中的高精度检测提供了机会。神经元额叶电位的研究已迅速成为脑机接口和神经科学研究的重要组成部分。神经元棘突检测为神经元放电分析和核簇识别提供了基础；其准确性取决于特征提取和分类，这影响了神经元解码分析。然而，提高高噪声信号中尖峰电位的检测精度仍然是一个问题。作者提出了一种启发式自适应阈值尖峰检测算法，该算法使用零相位巴特沃斯无限脉冲响应滤波器去除噪声并减少相移。接下来，应用启发式阈值来获得尖峰点，去除重复，并实现稳健的尖峰检测。所提出的算法使用细胞外尖峰数据集实现了95.40%的平均准确率，并有效地检测到尖峰。

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Heuristic adaptive threshold detection method for neuronal spikes

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Heuristic adaptive threshold detection method for neuronal spikes

In recent years, the development of microelectrode arrays and multichannel recordings has provided opportunities for high-precision detection in signal processing. The study of neuronal frontal potentials has been rapidly emerging as an important component in brain-computer interface and neuroscience research. Neuronal spike detection provides a basis for neuronal discharge analysis and nucleus cluster identification; its accuracy depends on feature extraction and classification, which affect neuronal decoding analysis. However, improving the detection accuracy of spike potentials in highly noisy signals remains a problem. IThe authors propose a heuristic adaptive threshold spike-detection algorithm that removes noise and reduces the phase shift using a zero-phase Butterworth infinite impulse response filter. Next, heuristic thresholding is applied to obtain spike points, remove repetitions, and achieve robust spike detection. The proposed algorithm achieved an average accuracy of 95.40% using extracellular spiked datasets and effectively detected spikes.

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来源期刊

IET Signal Processing 工程技术-工程：电子与电气

CiteScore

3.80

自引率

5.90%

发文量

审稿时长

9.5 months

期刊介绍： IET Signal Processing publishes research on a diverse range of signal processing and machine learning topics, covering a variety of applications, disciplines, modalities, and techniques in detection, estimation, inference, and classification problems. The research published includes advances in algorithm design for the analysis of single and high-multi-dimensional data, sparsity, linear and non-linear systems, recursive and non-recursive digital filters and multi-rate filter banks, as well a range of topics that span from sensor array processing, deep convolutional neural network based approaches to the application of chaos theory, and far more. Topics covered by scope include, but are not limited to: advances in single and multi-dimensional filter design and implementation linear and nonlinear, fixed and adaptive digital filters and multirate filter banks statistical signal processing techniques and analysis classical, parametric and higher order spectral analysis signal transformation and compression techniques, including time-frequency analysis system modelling and adaptive identification techniques machine learning based approaches to signal processing Bayesian methods for signal processing, including Monte-Carlo Markov-chain and particle filtering techniques theory and application of blind and semi-blind signal separation techniques signal processing techniques for analysis, enhancement, coding, synthesis and recognition of speech signals direction-finding and beamforming techniques for audio and electromagnetic signals analysis techniques for biomedical signals baseband signal processing techniques for transmission and reception of communication signals signal processing techniques for data hiding and audio watermarking sparse signal processing and compressive sensing Special Issue Call for Papers: Intelligent Deep Fuzzy Model for Signal Processing - https://digital-library.theiet.org/files/IET_SPR_CFP_IDFMSP.pdf