舌骨上肌和舌骨下肌的多通道表面肌电信号吞咽模式分类方法

IF 0.8 Q4 ENGINEERING, BIOMEDICAL
Masahiro Suzuki, M. Sasaki, Katsuhiro Kamata, Atsushi Nakayama, Isamu Shibamoto, Yasushi Tamada
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引用次数: 16

摘要

调节与吞咽有关的器官的运动和改变吞咽模式以适应丸剂的体积、质地和吞咽食物的物理性质的能力被称为吞咽储备。换句话说,它是吞咽食物以避免窒息和误吸的反应能力。在此,我们将重点研究与吞咽运动密切相关的舌骨上肌和舌骨下肌活动的协调性,作为建立吞咽储备评估方法的第一步,吞咽储备因神经肌肉疾病、衰老引起的肌肉无力而下降,仅举几例。首先,我们使用两个22通道电极,测量了舌骨上肌和舌骨下肌在以下四种吞咽条件下的表面肌电图(sEMG)信号:两种吞咽方式(正常吞咽和用力吞咽):两种剂量(3 mL和15 mL水)。然后,我们使用三种机器学习方法验证了基于吞咽条件的吞咽模式差异是否可以从表面肌电信号中分类;即实时分类法、综合分类法和图像识别法。在实时分类方法中,四种吞咽状态的平均分类准确率(MCA)低至81.5%,表明该方法无法对大约1 s时间内发生的吞咽状态之间的差异进行充分分类。在每16 ms对吞咽开始至结束的所有分类结果进行多数决策的综合分类方法中,MCA为95.1%。在图像识别方法中,将吞咽运动中一系列表面肌电信号的变化转化为吞咽模式图像,并结合深度卷积神经网络和支持向量机(SVM)对图像进行分类。与综合分类方法相比,图像识别方法的训练样本数量仅为1 / 26,但MCA达到95.7%。这种方法可以无创地评估吞咽模式,吞咽模式可以根据吞咽情况轻微改变,可以应用于早期检测老年人吞咽功能下降或虚弱状态(吞咽困难潜在)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Swallowing Pattern Classification Method Using Multichannel Surface EMG Signals of Suprahyoid and Infrahyoid Muscles
The ability to fine-tune the movement of swallowing-related organs and change the swallowing pattern to fit the volume of a bolus, texture and the physical properties of the food to be swallowed is referred to as the swallowing reserve. In other words, it is the response capability of food swallowing to avoid choking and aspiration. Herein, we focus on the coordination of the suprahyoid and infrahyoid muscles activities, which are closely related to swallowing movement, as a first step to develop a method to evaluate swallowing reserve, which declines due to neuromuscular disease, muscle weakness caused by aging, to mention a few. First, using two 22-channel electrodes, we measured the surface electromyography (sEMG) signals of suprahyoid and infrahyoid muscles during the following four swallowing conditions: combining two bolus volumes (3 and 15 mL water) and two techniques (normal and effortful swallow). Then, we verified whether the difference in swallowing patterns based on swallowing conditions can be classified from sEMG signals using three machine learning methods; namely, the real-time classification, comprehensive classification, and image recognition method. In the real-time classification method, the mean classification accuracy (MCA) for the four swallowing conditions was as low as 81.5%, indicating that the difference between swallowing conditions performed in a period of approximately 1 s cannot be classified sufficiently by this method. In the comprehensive classification method that applies a majority decision to all the classification results from the start to the end of swallowing, which can be obtained every 16 ms, MCA was 95.1%. Furthermore, in the image recognition method, the change of a series of sEMG signals in the swallowing movement was converted into swallowing pattern image, and the images were classified using a combination of deep convolutional neural networks and support vector machine (SVM). Compared with the comprehensive classification method, the number of training samples for the image recognition method was only 1 / 26, but the MCA reached 95.7%. This method, which can noninvasively evaluate swallowing patterns that change slightly based on swallowing conditions, could be applied to early detection of reduced swallowing function or a state of frailty (dysphagia potential) in aged individuals.
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来源期刊
Advanced Biomedical Engineering
Advanced Biomedical Engineering ENGINEERING, BIOMEDICAL-
CiteScore
1.40
自引率
10.00%
发文量
15
审稿时长
15 weeks
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