脑刺激试验变异性中三种机制不同的变异性和噪声源的提取。

IF 6.6 2区 医学 Q2 ENGINEERING, BIOMEDICAL IEEE Transactions on Neural Systems and Rehabilitation Engineering Pub Date : 2024-12-25 DOI:10.1109/TNSRE.2024.3522681
Ke Ma;Siwei Liu;Mengjie Qin;Stephan M. Goetz
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引用次数: 0

摘要

运动诱发电位(MEPs)是少数可直接观察到的对外部脑刺激的反应之一,具有多种应用,通常以输入-输出(IO)曲线的形式出现。先前具有两个变异性源的统计模型固有地将低侧平台上的小mep视为神经招募特性的一部分。然而,最近的研究表明,静息条件下的小MEP响应受到主要是技术质量的背景噪声的污染和过度遮蔽,例如由放大器引起的背景噪声,并建议神经补充曲线应继续低于该噪声水平。这项工作旨在将生理变异从背景噪声中分离出来,并改进对招募行为的描述。我们围绕一个没有低平台的对数逻辑函数开发了一个三变量源模型,并纳入了一个额外的背景噪声源。与具有两个或更少可变性源的模型相比,我们的方法更好地描述了IO特征,所有受试者和脉冲形状的贝叶斯信息标准得分较低。该模型独立提取受刺激神经系统的隐藏变异性信息,并将其从背景噪声中分离出来,从而准确估计出IO曲线参数。这个新模型提供了一个强大的工具来分析临床和实验神经科学中的脑刺激IO曲线,并减少了不适当的统计方法产生虚假结果的风险。该模型和相应的校准方法更准确地表征了MEP反应和变异性来源,促进了我们对皮层兴奋性的理解,并可能改善神经调节效应的评估。
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Extraction of Three Mechanistically Different Variability and Noise Sources in the Trial-to-Trial Variability of Brain Stimulation
Motor-evoked potentials (MEPs) are among the few directly observable responses to external brain stimulation and serve a variety of applications, often in the form of input–output (IO) curves. Previous statistical models with two variability sources inherently consider the small MEPs at the low-side plateau as part of the neural recruitment properties. However, recent studies demonstrated that small MEP responses under resting conditions are contaminated and over-shadowed by background noise of mostly technical quality, e.g., caused by the amplifier, and suggested that the neural recruitment curve should continue below this noise level. This work intends to separate physiological variability from background noise and improve the description of recruitment behaviour. We developed a triple-variability-source model around a logarithmic logistic function without a lower plateau and incorporated an additional source for background noise. Compared to models with two or fewer variability sources, our approach better described IO characteristics, evidenced by lower Bayesian Information Criterion scores across all subjects and pulse shapes. The model independently extracted hidden variability information across the stimulated neural system and isolated it from background noise, which led to an accurate estimation of the IO curve parameters. This new model offers a robust tool to analyse brain stimulation IO curves in clinical and experimental neuroscience and reduces the risk of spurious results from inappropriate statistical methods. The presented model together with the corresponding calibration method provides a more accurate representation of MEP responses and variability sources, advances our understanding of cortical excitability, and may improve the assessment of neuromodulation effects.
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来源期刊
CiteScore
8.60
自引率
8.20%
发文量
479
审稿时长
6-12 weeks
期刊介绍: Rehabilitative and neural aspects of biomedical engineering, including functional electrical stimulation, acoustic dynamics, human performance measurement and analysis, nerve stimulation, electromyography, motor control and stimulation; and hardware and software applications for rehabilitation engineering and assistive devices.
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