触觉生物反馈对脑瘫儿童平衡控制的影响

IF 0.8 4区 医学 Q4 BIOPHYSICS Acta of bioengineering and biomechanics Pub Date : 2023-01-01 DOI:10.37190/abb-02245-2023-03
Hande Argunsah, Begum Yalcin
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Pearson Correlation Coefficient and Root Mean Square Error techniques showed that biofeedback regulated the gait parameters and trunk stability of the CP group when biofeedback was given. The extended stance percentage (without BF: 73.91% ± 10.42, with BF: 63.53% ± 2.99), step width (without BF: 0.20m ± 0.05, with BF: 0.18m ± 0.07), and step time (without BF: 1.55s ± 1.07, with BF: 0.73s ± 0.14) parameters decreased; similarly, cadence and walking speed increased. Conclusions Obtained results indicated that this wearable sensor can be integrated into the physical therapy and rehabilitation process of children with balance and postural control impairments to improve motor learning and balance control. 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摘要

目的脑瘫儿童在利用神经信息进行平稳运动和保持行走平衡方面存在局限性。本研究旨在开发一种可穿戴传感器,该传感器可以持续跟踪平衡,并通过实时振动刺激向用户提供触觉生物反馈,以帮助患有平衡和姿势控制障碍的患者,如脑瘫。方法12例脑瘫儿童和12例年龄相匹配的正常发育儿童使用传感器以自行选择的速度行走。在“有”和“无”生物反馈条件下,用Xsens MVN记录下肢关节运动学、质心和时空参数。结果该传感器对正常步态无干扰。Pearson相关系数和均方根误差分析表明,生物反馈对CP组的步态参数和躯干稳定性有调节作用。扩步率(无BF: 73.91%±10.42,有BF: 63.53%±2.99)、步宽(无BF: 0.20m±0.05,有BF: 0.18m±0.07)、步长(无BF: 1.55s±1.07,有BF: 0.73s±0.14)参数降低;同样,节奏和步行速度也增加了。本研究结果有助于更好地理解创新工程应用与康复过程的适应性,从而帮助平衡障碍患者并促进他们融入社会。
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Balance Control via Tactile Biofeedback in Children with Cerebral Palsy
Purpose Children with Cerebral Palsy have limitations in utilizing neural information to perform smooth movement and maintain balance during walking. This study aimed to develop a wearable sensor that tracks balance continuously and provides haptic biofeedback to its user through real-time vibration stimulus to assist patients with balance and postural control impairments such as cerebral palsy. Methods Twelve children with cerebral palsy and 12 age-matched typically developed children used the sensor during walking at a self-selected speed. The lower extremity joint kinematics, center of mass, and spatial-temporal parameters were recorded with Xsens MVN during “with” and “without” biofeedback conditions. Results The sensor did not disturb healthy gait. Pearson Correlation Coefficient and Root Mean Square Error techniques showed that biofeedback regulated the gait parameters and trunk stability of the CP group when biofeedback was given. The extended stance percentage (without BF: 73.91% ± 10.42, with BF: 63.53% ± 2.99), step width (without BF: 0.20m ± 0.05, with BF: 0.18m ± 0.07), and step time (without BF: 1.55s ± 1.07, with BF: 0.73s ± 0.14) parameters decreased; similarly, cadence and walking speed increased. Conclusions Obtained results indicated that this wearable sensor can be integrated into the physical therapy and rehabilitation process of children with balance and postural control impairments to improve motor learning and balance control. The present findings contribute to a better understanding of the adaptation of innovative engineering applications with rehabilitation processes, which in turn could assist patients with balance impairments and facilitate their integration into society.
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来源期刊
Acta of bioengineering and biomechanics
Acta of bioengineering and biomechanics BIOPHYSICS-ENGINEERING, BIOMEDICAL
CiteScore
2.10
自引率
10.00%
发文量
0
期刊介绍: Acta of Bioengineering and Biomechanics is a platform allowing presentation of investigations results, exchange of ideas and experiences among researchers with technical and medical background. Papers published in Acta of Bioengineering and Biomechanics may cover a wide range of topics in biomechanics, including, but not limited to: Tissue Biomechanics, Orthopedic Biomechanics, Biomaterials, Sport Biomechanics.
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