Real-time locomotion mode detection in individuals with transfemoral amputation and osseointegration.

IF 5.2 2区医学 Q1 ENGINEERING, BIOMEDICAL

Journal of NeuroEngineering and Rehabilitation Pub Date : 2025-06-24 DOI:10.1186/s12984-025-01672-2

Bahareh Ahkami, Morten B Kristoffersen, Max Ortiz-Catalan

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引用次数: 0

Abstract

Background: Despite notable advancements in prosthetic leg technology, commercially available devices with embedded algorithms utilizing bioelectric signals for prosthetic leg control are lacking. This untapped potential could enhance current prosthetic leg capabilities, enabling more natural movements. However, individuals with short residual limbs have limited available muscle and it has not been investigated if different locomotion modes can be predicted in real-time in this population. Here, we explored the feasibility of using electromyographic signals in individuals with short residual limbs and osseointegrated implants to infer locomotion modes.

Methods: We recorded data from five participants with transfemoral amputation and osseointegration while walking on level ground, stairs, and ramps. Electromyography, acceleration, angular velocity, and ground reaction force were collected using wireless sensors. Two sessions of recordings for offline and real-time evaluation were conducted, with 30 rounds and 15 rounds, respectively. Decoding was performed using a mode-specific, phase-dependent classifier. The method was implemented in LocoD, an existing open-source platform, allowing for further development by the community and allowing easy comparison between different classification algorithms. The evaluation of the platform and prediction algorithm relies on quantifying the transition error, signifying instances where the algorithm falls short in predicting shifts between different walking surfaces.

Results: In this study, a participant exhibited an average error as low as 1.2%, indicating precise predictions. Conversely, the highest average error was found at 23% in a different participant. This variation could be the result of factors related to the amputation such as residual limb length, remaining muscles, and the surgical technique used while performing the amputation, as well as differences in performing the movements. On average, offline classification resulted in a mean error of 5.7%, while the corresponding mean error during online (real-time) evaluation was 11.6%.

Conclusion: Our findings suggest that myoelectric signals can be potentially used in the control of prosthetic legs for individuals with short residual limbs with osseointegrated implants. Further research into understanding and compensating for variations in the locomotion detection accuracy for different participants is crucial.

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经股截肢和骨整合患者的实时运动模式检测。

背景：尽管义肢技术取得了显著进步，但商用设备缺乏利用生物电信号进行义肢控制的嵌入式算法。这种尚未开发的潜力可以增强目前假肢的功能，使其能够更自然地运动。然而，残肢短的个体可用肌肉有限，并且尚未研究是否可以实时预测这些人群的不同运动模式。在这里，我们探索了在残肢短和骨整合植入物个体中使用肌电图信号来推断运动模式的可行性。方法：我们记录了5名经股骨截肢和骨整合患者在平地、楼梯和坡道上行走时的数据。用无线传感器收集肌电图、加速度、角速度和地面反作用力。进行了两次录音，分别为30轮和15轮，用于离线和实时评估。解码是使用特定模式，相位依赖分类器执行的。该方法在现有的开源平台LocoD上实现，允许社区进一步开发，并且可以方便地比较不同的分类算法。对平台和预测算法的评估依赖于对过渡误差的量化，这表明算法在预测不同行走表面之间的转移方面存在不足。结果：在本研究中，参与者的平均误差低至1.2%，表明预测准确。相反，另一位参与者的平均误差最高，为23%。这种差异可能是截肢相关因素的结果，如残肢长度、剩余肌肉、进行截肢时使用的手术技术，以及执行动作的差异。离线分类的平均误差为5.7%，在线（实时）评价的平均误差为11.6%。结论：我们的研究结果表明，肌电信号可以潜在地用于控制残肢短的人的义肢骨整合植入物。进一步研究理解和补偿不同参与者运动检测精度的变化是至关重要的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of NeuroEngineering and Rehabilitation 工程技术-工程：生物医学

CiteScore

9.60

自引率

3.90%

发文量

122

审稿时长

24 months

期刊介绍： Journal of NeuroEngineering and Rehabilitation considers manuscripts on all aspects of research that result from cross-fertilization of the fields of neuroscience, biomedical engineering, and physical medicine & rehabilitation.