Characterization of perception by transcutaneous electrical Stimulation in terms of tingling intensity and temporal dynamics.

IF 3.2 4区 医学 Q2 ENGINEERING, BIOMEDICAL Biomedical Engineering Letters Pub Date : 2023-08-19 eCollection Date: 2024-01-01 DOI:10.1007/s13534-023-00308-5
Stefan Manoharan, Hangue Park
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Abstract

Electrotactile feedback is a cost-effective and versatile method to provide new information or to augment intrinsic tactile feedback. As tactile feedback provides critical information for human-environment interaction, electrotactile feedback, accordingly, has many purposes to improve the quality of human-environment interaction in both direct and remote settings. However, electrotactile feedback overlays tingling sensation on top of the natural tactile feedback. To better characterize electrotactile feedback and understand the origin of the tingling sensation, a need arises to characterize the human perception of electrotactile feedback qualitatively and quantitatively, while varying the key stimulation parameters, namely amplitude and frequency. This study consists of two experiments. In the first experiment, the voltage for each subject was characterized by setting perception and discomfort thresholds. In the second experiment, subjects received electrical stimulation in 9 different combinations of voltages and frequencies. On delivering stimulation with each parameter combination, subjects reported their perception in two comparative scales-pressure vs. tingling and constant vs. pulsing. Subjects also reported the location of perception for stimulation with every parameter combination. More tingling and less pressure was reported as frequency increased, while the tingling-pressure percept was not affected by the amplitude change. Additionally, less pulsing and more constant was reported as frequency increased, while the pulsing-constant percept was not affected by the amplitude change. Concurrently, the normalized level of voltage thresholds was decreased as frequency increased. Dependency of tingling-pressure percept on stimulation frequency suggests that incongruency between the stimulation frequency and the natural firing rate of the sensory neuron would be an important factor of the tingling sensation. This study is a steppingstone to further demystify the origin of the tingling percept caused by electrical stimulation, thus broadening the use of transcutaneous electrical stimulation as a way of providing tactile cue or augmentation.

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在刺痛强度和时间动力学方面,经皮电刺激感知的表征
电触觉反馈是提供新信息或增强固有触觉反馈的一种具有成本效益的多功能方法。由于触觉反馈为人与环境的互动提供了关键信息,因此电触觉反馈在提高直接和远程环境中人与环境的互动质量方面有很多用途。然而,电触觉反馈会在自然触觉反馈的基础上叠加刺痛感。为了更好地描述电触觉反馈并了解刺痛感的来源,需要在改变关键刺激参数(即振幅和频率)的同时,定性和定量地描述人类对电触觉反馈的感知。本研究包括两个实验。在第一个实验中,通过设定感知和不适阈值来确定每个受试者的电压特征。在第二个实验中,受试者接受了 9 种不同电压和频率组合的电刺激。在使用每种参数组合进行刺激时,受试者用两个比较尺度来报告他们的感觉--压力与刺痛、持续与脉冲。受试者还报告了每种参数组合的刺激感知位置。随着频率的增加,刺痛感增加,压力感减少,而刺痛感和压力感不受振幅变化的影响。此外,随着频率的增加,脉动感减少,恒定感增加,而脉动-恒定感不受振幅变化的影响。同时,电压阈值的正常化水平随着频率的增加而降低。刺痛-压力感觉对刺激频率的依赖性表明,刺激频率与感觉神经元自然发射率之间的不协调是产生刺痛感觉的一个重要因素。这项研究为进一步揭示电刺激引起的刺痛感的起源奠定了基础,从而拓宽了经皮电刺激作为提供触觉提示或增强的一种方法的应用范围。
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来源期刊
Biomedical Engineering Letters
Biomedical Engineering Letters ENGINEERING, BIOMEDICAL-
CiteScore
6.80
自引率
0.00%
发文量
34
期刊介绍: Biomedical Engineering Letters (BMEL) aims to present the innovative experimental science and technological development in the biomedical field as well as clinical application of new development. The article must contain original biomedical engineering content, defined as development, theoretical analysis, and evaluation/validation of a new technique. BMEL publishes the following types of papers: original articles, review articles, editorials, and letters to the editor. All the papers are reviewed in single-blind fashion.
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