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基于肌电图和机器学习的多体位睡眠磨牙症的先进感应系统。

Advanced Sensing System for Sleep Bruxism across Multiple Postures via EMG and Machine Learning.

机构信息

Department of Electronic Engineering, Maynooth University, W23A3HY Maynooth, Ireland.

Department of Biomedical Engineering, AIR University, Islamabad 44000, Pakistan.

出版信息

Sensors (Basel). 2024 Aug 22;24(16):5426. doi: 10.3390/s24165426.

DOI:10.3390/s24165426
PMID:39205120
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11358964/
Abstract

Diagnosis of bruxism is challenging because not all contractions of the masticatory muscles can be classified as bruxism. Conventional methods for sleep bruxism detection vary in effectiveness. Some provide objective data through EMG, ECG, or EEG; others, such as dental implants, are less accessible for daily practice. These methods have targeted the masseter as the key muscle for bruxism detection. However, it is important to consider that the temporalis muscle is also active during bruxism among masticatory muscles. Moreover, studies have predominantly examined sleep bruxism in the supine position, but other anatomical positions are also associated with sleep. In this research, we have collected EMG data to detect the maximum voluntary contraction of the temporalis and masseter muscles in three primary anatomical positions associated with sleep, i.e., supine and left and right lateral recumbent positions. A total of 10 time domain features were extracted, and six machine learning classifiers were compared, with random forest outperforming others. The models achieved better accuracies in the detection of sleep bruxism with the temporalis muscle. An accuracy of 93.33% was specifically found for the left lateral recumbent position among the specified anatomical positions. These results indicate a promising direction of machine learning in clinical applications, facilitating enhanced diagnosis and management of sleep bruxism.

摘要

磨牙症的诊断具有挑战性,因为并非所有咀嚼肌的收缩都可以归类为磨牙症。用于睡眠磨牙症检测的常规方法在有效性上存在差异。有些方法通过肌电图、心电图或脑电图提供客观数据;而其他方法,如牙种植体,则在日常实践中不太可行。这些方法针对的是磨牙症检测的关键肌肉——咬肌。然而,需要注意的是,颞肌在咀嚼肌的磨牙症中也很活跃。此外,研究主要检查了仰卧位的睡眠磨牙症,但其他解剖位置也与睡眠有关。在这项研究中,我们收集了肌电图数据,以检测与睡眠相关的三个主要解剖位置(即仰卧位和左侧、右侧侧卧位)中颞肌和咬肌的最大随意收缩。共提取了 10 个时域特征,并比较了 6 个机器学习分类器,随机森林的表现优于其他分类器。在检测睡眠磨牙症时,这些模型使用颞肌可实现更高的准确性。在指定的解剖位置中,左侧侧卧位的准确率达到了 93.33%。这些结果表明,机器学习在临床应用中具有广阔的前景,可以促进睡眠磨牙症的诊断和管理。

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Cannabidiol Intervention for Muscular Tension, Pain, and Sleep Bruxism Intensity-A Randomized, Double-Blind Clinical Trial.大麻二酚对肌肉紧张、疼痛和睡眠磨牙症强度的干预——一项随机双盲临床试验
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Classification of bruxism based on time-frequency and nonlinear features of single channel EEG.
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