Ismail Lina, Karwowski Waldemar
Arab Academy for Science, Technology and Maritime Transports, Department of Industrial and Management Engineering, Alexandria, Egypt.
Computational Neuroergonomics Laboratory, Department of Industrial Engineering and Management Systems, University of Central Florida, Orlando, FL, United States.
Front Neuroergon. 2025 May 30;6:1542393. doi: 10.3389/fnrgo.2025.1542393. eCollection 2025.
The perception of physical comfort is one of the important workplace design parameters. Most comfort perception studies have mainly relied on subjective assessments and biomechanical techniques, with limited exploration of neural brain activity.
The current study investigates this research gap by integrating the rating of perceiving physical comfort (RPPC) with brain network indices in an arm flexion task across different force levels. The applied arm forces, EEG-based neural responses, and the RPPC were measured, and the corresponding network theory indices were calculated. The following correlations were evaluated: (a) RPPC and applied forces, (b) network theory indices and applied forces, and (c) RPPC and network theory indices.
Results for (a) revealed a significant negative correlation between RPPC and the applied force for the arm flexion task. This shows that as the exerted force difficulty increases to an extremely hard level, the perception of physical comfort decreases till it reaches no comfort level. Results for (b) showed a positive correlation between the applied forces and global efficiency for the alpha network coherence during an extremely hard task. In contrast, a negative correlation was found between applied forces and path length for beta coherence during a light task. Findings from (b) suggest that the brain is more efficient in transmitting information related to cognitive functioning during a highly demanding force exertion task than a light task. Results from (c) showed a negative correlation between RPPC and global efficiency for alpha coherence during an extremely hard force exertion task. Moreover, a positive correlation was observed between RPPC and local efficiency for beta coherence during a somewhat hard task. Findings from (c) also indicate that perceiving a low-comfort physical task might increase task alertness, with the corresponding neural network exhibiting a high level of internal brain organization.
The study results contribute valuable knowledge toward understanding the neural responses underlying the perception of physical comfort levels.
身体舒适度的感知是工作场所设计的重要参数之一。大多数舒适度感知研究主要依赖主观评估和生物力学技术,对大脑神经活动的探索有限。
本研究通过在不同力水平的手臂弯曲任务中,将感知身体舒适度评分(RPPC)与脑网络指标相结合,来填补这一研究空白。测量了施加的手臂力、基于脑电图的神经反应和RPPC,并计算了相应的网络理论指标。评估了以下相关性:(a)RPPC与施加的力;(b)网络理论指标与施加的力;(c)RPPC与网络理论指标。
(a)的结果显示,在手臂弯曲任务中,RPPC与施加的力之间存在显著的负相关。这表明,随着施加力的难度增加到极其困难的水平,身体舒适度的感知会降低,直至达到不舒适的程度。(b)的结果表明,在极其困难的任务中,施加的力与α网络相干性的全局效率之间存在正相关。相反,在轻松任务中,施加的力与β相干性的路径长度之间存在负相关。(b)的研究结果表明,在高要求的力施加任务中,大脑在传递与认知功能相关的信息方面比轻松任务更有效。(c)的结果显示,在极其困难的力施加任务中,RPPC与α相干性的全局效率之间存在负相关。此外,在 somewhat hard 任务中,RPPC与β相干性的局部效率之间存在正相关。(c)的研究结果还表明,感知低舒适度的身体任务可能会提高任务警觉性,相应的神经网络表现出高水平的内部大脑组织。
研究结果为理解身体舒适度感知背后的神经反应提供了有价值的知识。
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