- College of Instrumentation and Electrical Engineering, Jilin University, Changchun, China
Exercise fatigue is a common physiological phenomenon in human activities. The occurrence of exercise fatigue can reduce human power output and exercise performance, and increased the risk of sports injuries. As physiological signals that are closely related to human activities, surface electromyography (sEMG) signals have been widely used in exercise fatigue assessment. Great advances have been made in the measurement and interpretation of electromyographic signals recorded on surfaces. It is a practical way to assess exercise fatigue with the use of electromyographic features. With the development of machine learning, the application of sEMG signals in human evaluation has been developed. In this article, we focused on sEMG signal processing, feature extraction, and classification in exercise fatigue. sEMG based multisource information fusion for exercise fatigue was also introduced. Finally, the development trend of exercise fatigue detection is prospected.
Introduction
Exercise fatigue is a physiological phenomenon that originates from human activities and results in decreased physical performance (Nijs et al., 2011). The main manifestation of exercise fatigue is muscle fatigue which was defined as the “failure to maintain the force output, leading to a reduced performance” (Asmussen, 1993). Muscle strength declines progressively during exercise, so fatigue occurs before the task failure (Gandevia, 2001). There are many examples of application fields involving muscle fatigue, including sports (Simsek, 2017; Kuniszyk-Jozkowiak et al., 2018; Liu et al., 2019; Hedayatpour et al., 2021; Liu and Li, 2021; Rodriguez-Rosell et al., 2021), rehabilitation (Gaudet et al., 2018; Kim et al., 2018; Meng et al., 2019; Na et al., 2020; Fundaro et al., 2021; Sato et al., 2021), and occupation (Alberto et al., 2018; Fang et al., 2021; Ji and Huang, 2021; Yu et al., 2021; Gonzalez-Zamora et al., 2022). Physiological signals, biochemical assessments, and questionnaires are used to monitor exercise fatigue (Halson and Shona, 2014). Questionnaires are subjective. Invasive biochemical tests cause discomfort to the subjects. Noninvasive physiological testing with scientific and statistical approaches can provide confidence and certainty.
Muscle fatigue is divided into central and peripheral components. Peripheral fatigue is caused by changes in the neuromuscular junction. Central fatigue originates in the central nervous system (CNS). The production of skeletal muscle force depends on contractile mechanisms, and failure of nervous, ion, vascular, and energy systems can contribute to the development of muscle fatigue (Wan et al., 2017). During sustained contractions, metabolic changes in the muscle affect the propagation of action potential. These changes result in a progressive reduction of muscle fiber conduction velocity (CV). This is one of the main causes of the changes in amplitude and spectral EMG variables during fatigue. This physiological variable provides a relevant means to describe and quantify the muscle fatigue (Marco et al., 2017).
Exercise fatigue can be detected through surface electromyography (sEMG) (Chang et al., 2012). Constant exercise load results in the rise of EMG activity during fatigue (Chlif et al., 2018). Electrical currents generated by muscle contractions can be monitored in the form of EMG signals and displayed on a computer (Barszap et al., 2016). Bioelectricity is detectable when muscle contracts (Tang et al., 2020). Electromyographic techniques are used in sports and rehabilitation accepted by researchers (Cortez et al., 2017; Pakosz and Konieczny, 2020; Quittmann et al., 2020). EMG can be recorded by needles inserted into the muscle (Kwon et al., 2018) or electrodes placed over the skin surface (Zeng et al., 2021). Compared with invasive EMG, sEMG is more popular among researchers (Khan et al., 2019; Yamagishi et al., 2019; Silva et al., 2020).
This review offers an overall summary of the assessment of human exercise fatigue based on sEMG signals and highlights signal processing, feature extraction, and classification. The possibilities for future work on exercise fatigue with sEMG will also be discussed in this study.
Acquisition of Surface Electromyography and Preprocessing
The sEMG is a biological electric signal generated by muscle contraction that can be harvested by electrodes. The sEMG signals are the most intuitive physiological signals of muscle activity and the best means to detect muscle fatigue. The sEMG signal is a kind of pseudorandom physiological signal that is very weak. The voltage of the sEMG signal range from 50 μV to 100 mV and the frequency is varied from 10 to 500 Hz (Pancholi and Joshi, 2018). The electrode skin impedance which is one of the noises that affects the quality of EMG signals must be as low as possible to obtain effective signals (Sae-Lim et al., 2019). Pancholi and Joshi (2018) obtained sEMG signals from five different arm muscles using hardware based on ADS1298 IC (Texas Instruments) and ARM cortex M4 series processor with 4,000 Hz sampling frequency. De la Pena et al. (2019) recorded sEMG-related muscle fatigue in sports training using a portable prototype with a 5,000 Hz sampling rate. Zhao et al. (2020) acquired sEMG data based on a software platform for visualizing sEMG information on muscle fatigue during upper limb rehabilitation training. In Makaram et al. (2021), Biopac MP 36 (Biopac Systems Inc. CA, United States) was used to acquire brachii muscle of 52 healthy participants’ sEMG during dynamic contractions at an acquisition rate of 10,000 Hz. Wang L. et al. (2021) used wearable sampling electrodes that the sampling frequency is 200 Hz to collect sEMG signals in real-time during the driving tasks. Chen et al. (2021b) used the MP160 physiological record analysis system produced by the American company BIOPAC to analyze the fatigue of miners.
Exact electrode positioning is vital for obtaining reliable EMG signals. A study showed high correlations between all electrode sites and clavicular movements. The traditional electrode site record more informative signals in subjects (Zanca et al., 2014). All trunk muscles were affected by electrode position changes, but the abdominal muscles were more affected than the back muscles (Huebner et al., 2015). Ghapanchizadeh et al. (2016) found that the optimal signal from the flexor carpi radialis muscles was presented at 90% and for the extensor carpi radialis muscles was shown at 90% of the electrode position over the forearm length. The muscle moves away from its uncontracted position directly under the EMG electrode when contracts. Elsais et al. (2020) used ultrasound to track the relative motion between skin and muscle to quantify the magnitude of the movement between them and inform protocols for surface EMG placement.
The raw sEMG data collected will inevitably be mixed with power line interference and motion artifacts (Zheng and Hu, 2019). Therefore, effective preprocessing is required before feature extraction of these signals (Ahmadizadeh et al., 2021). Common methods of sEMG preprocessing include filtering (Zhao et al., 2020), normalization, and windowing (Fang et al., 2020). Tapia et al. (2017) used independent component analysis (ICA) and empirical mode decomposition (EMD) to process sEMG signals. (Wu et al., 2017) achieved better accuracy for the diagnosis of muscular fatigue through ensemble empirical mode decomposition (EEMD) by Hilbert transform (HT). Zhang et al. (2019) decomposed sEMG signals by principal component analysis (PCA) into principal components and weight vectors that improve the validity of parameters. In Avian et al. (2022), Discrete Wavelet Transform (DWT) is used to process the sEMG signal to increase model performance.
The increase from baseline represents the onset of muscle activity. Muscle activity onset can be estimated from EMG and ultrasound (Dieterich et al., 2017). Gupta et al. (2014) determined the onset of medial gastrocnemius muscle activity using visual and automated methods during a stretch-shorten-cycle muscle action. Zhang and Zhou (2012) proposed a novel method of muscle activity onset detection based primarily on the sample entropy (SampEn) analysis of the surface EMG. Liu et al. (2015) presented an unsupervised EMG learning framework based on a sequential Gaussian mixture model (GMM) to detect muscle activity onsets. Appropriate signal preprocessing method is helpful to improve the effectiveness of feature extraction.
Feature Extraction
Feature extraction from the sEMG signal plays an important role in the accuracy of fatigue detection. Time domain, frequency domain, time-frequency domain, and nonlinear parameters are four major types in sEMG-based signal processing (Too et al., 2018b; Yousif et al., 2019; Bukhari et al., 2020).
Time-Domain Feature Analysis
The calculation of time-domain features is the most popular approach for sEMG feature extraction that is directly calculated with time as the independent variable. In the time domain, the sEMG signal is usually regarded as a random signal whose mean value is zero and variance varies with signal intensity. As the calculation of time-domain features is simple and intuitive, it is a widely used feature extraction method of sEMG signal in human movement (Harmon et al., 2021). The typical time-domain features of sEMG signals mainly include the root mean square (RMS) (Cui et al., 2021), integrated EMG (iEMG) (Alam et al., 2020), zero-crossing rate (ZCR) (Kim et al., 2018), waveform length (WL), variance of electromyography (VAR) (Whittaker et al., 2019), and mean absolute value (MAV) (Chapman et al., 2019).
With the occurrence of muscle fatigue, the time domain features of sEMG generally show an upward trend over time (Goubault et al., 2022). RMS and iEMG not only reflect the amplitude changes of the sEMG signal in the time domain but also clearly reflect the biomechanical properties and muscle energy changes in the exercise process (Silvetti et al., 2017; Wu et al., 2017). Therefore, RMS and iEMG are often used to indicate muscle activation intensity and human motion state (Triwiyanto et al., 2018).
Frequency-Domain Feature Analysis
The frequency-domain features are spectrum or power spectrum (PS) features that are obtained by fast Fourier transform (FFT) to the original sEMG signals, thus the frequency band distribution of the signals can be observed directly (Chandra et al., 2020). Researchers believe that frequency domain analysis is more meaningful than time domain analysis in both static and dynamic motion. To quantitatively describe the spectrum and PS features of sEMG signals, the mean frequency (MF) (Hou et al., 2021) and median frequency (MDF) (Park and Park, 2021) are generally used that decrease linearly over time. The deeper the muscle fatigue, the faster the MF decreases. Both MF and MDF can represent the frequency of measured muscle CV, but in practical application, MDF is more sensitive than MF in reflecting muscle activity and functional state. MF can also get good results in muscle fatigue detection (Chai et al., 2019). Significant changes in the PS indicate muscle fatigue, and the PS drifts from high frequency to low frequency. For example, after maximum weight training, the peak value of the sEMG signal will increase and drift to the lower frequency band. During extreme contraction, there is a decrease in muscle fiber action potential and possible emission frequency.
Time-Frequency Distributions
To make up for the deficiency of Fourier transform analysis of non-stationary signals, time-frequency features of sEMG signals are introduced. The analysis of time-frequency features is important to the estimation of muscle fatigue state, and it is usually necessary to analyze both the time-domain and frequency-domain features of sEMG signals to obtain comprehensive information of muscle physiological changes. Traditional sEMG time domain and frequency domain analysis methods only describe the time domain or frequency domain features, but the time-frequency domain feature analysis method can overcome this limitation. At present, the available time-frequency analysis methods for sEMG signal mainly include Short-time Fourier Transform (STFT), Wavelet Transform (WT), Choi William distribution (CWD), and Wigner-Ville distribution (WVD), used for visual observation of signal frequency content evolution over time. WVD is a common bilinear time-frequency distribution, which is the most common type of Cohen’s time-frequency distribution. Instantaneous frequency parameters commonly used are instantaneous mean frequency (IMNF) (Triwiyanto et al., 2017) and instantaneous median frequency (IMDF) (Yousif et al., 2019), which show a downward trend with the deepening of fatigue degree. Average instantaneous MF has higher stability and sensitivity than frequency-domain features. Yousif et al. (2019) applied IMNF and IMDF to assess the muscles fatigue of the male runner during 400 m running with three types of running strategies.
Non-Linear Parameters
The sEMG complexity and entropy decrease linearly with the increase of fatigue degree. The complexity of Lempel-Ziv [C (n)] (Jo et al., 2018) is the speed at which new patterns appear with the increase of the length of time series, indicating the degree of randomness of the series, which decreases linearly in the process of dynamic motion. In dynamic motion, approximate entropy rises first and then decreases for most people. Marginal spectrum entropy (MSE) (Jero and Ramakrishnan, 2019) is a useful real-time muscle fatigue assessment method with the advantages of fast, reliable assessment of muscle fatigue and anti-noise. Compared with approximate entropy and MDF, MSE can be calculated quickly, the data length robustness is better, and muscle fatigue can be assessed reliably. It has high stability for different individuals and good noise resistance. SampEn (Cui et al., 2017), proposed by Richman and Moorman in 2000, measures the probability of generating new patterns in signals by measuring the complexity of time series. SampEn has a strong anti-noise ability and can reduce data deviation. The higher the complexity of the sequence, the higher the entropy. The multi-scale entropy (Fan et al., 2018) of sEMG signals decreases as the load increases, which more accurately represents the complexity of the muscle system. Compared with the traditional SampEn, it can more objectively reflect the working status and fatigue grade of the muscle. Multi-scale entropy analysis has a small amount of calculation and can adapt to the complexity of dynamic muscle contraction under time-varying loads. In practical work, normalized average multi-scale entropy can be used as a quantitative index to measure the dynamic fatigue degree of muscles. Recurrence quantification analysis (RQA) (Chen et al., 2018) is used to determine the percentage of line segments (%DET) reflecting the periodicity of signals. The RQA software is used to calculate and determine the percentage of line segments. Under dynamic and static loads, %DET increases linearly with the occurrence of muscle fatigue. Lejun et al. (2018) used C(n) to evaluate fatigue in all-out cycling exercises. Cui et al. (2017) used SampEn to investigate the fatiguing features of muscle-tendon units (MTUs) within skeletal muscles during static isometric contraction tasks. Hernandez and Camic (2019) investigated the effect of fatigue status and contraction type on the complexity of the sEMG signal, using SampEn and Detrended Fluctuation Analysis (DFA). Kahl and Hofmann (2016) compared the performance of different fatigue detection algorithms quantifying muscle fatigue based on sEMG signals. Fatigue detection algorithms including spectral moments ratio (SMR), SampEn, fuzzy approximate entropy (fApEn), and RQA (%DET) were calculated. After identifying the extracted features from the sEMG signal, the next important step is classification to detect the fatigue state.
Classification
With the development of machine learning, machine learning algorithms were widely applied to exercise fatigue classification. Classification in this article normally refers to supervised learning where individuals are classified based on their features. Some classification algorithms based on sEMG are listed in Table 1, mainly including fuzzy logic (FL) (Li, 2017), hidden Markov model (HMM) (Shahmoradi et al., 2017), k-nearest neighbor (KNN) (Bukhari et al., 2020), support vector machine (SVM) (Chen et al., 2021b), linear discriminant analysis (LDA) (Ahmed et al., 2020), and artificial neural network (ANN) (Subasi and Kiymik, 2010).
Support vector machine is a popular machine learning classification method because it is simple, fast, and stable, and shows better accuracy than other methods (Karthick et al., 2018; Wang et al., 2018; Greco et al., 2019; Wang, 2021). Since the features extracted from the sEMG signal are the input of the classifier, the accuracy of classification results is closely related to the feature extraction method. Dimension reduction plays a crucial role in index extraction, which can reduce the calculation time. Common dimension reduction methods include PCA (Qi et al., 2020) and ICA (Too et al., 2018a).
Khan et al. (2019) used the random forest trained by distributive power frequency of the sEMG signal of the vastus-lateralis muscle to predict muscle fatigue. They obtained a high accuracy in fatigue classification. Wang et al. (2020) proposed a muscle fatigue classification method based on sEMG signals to detect muscle fatigue by the Convolutional Neural Network–Support Vector Machine (CNN-SVM), Support Vector Machine, Convolutional Neural Network, and Particle Swarm Optimization–Support Vector Machine algorithms. CNN-SVM algorithm achieves the highest accuracy rate in muscle fatigue classification.
Zhang et al. (2021) detected muscle fatigue based on the Multidimensional Feature Fusion Network (MFFNet), which is composed of Attention Frequency domain Network (AFNet) and Attention Time-domain Network (ATNet). The result shows 77.37% higher than other classifiers. Bharathi et al. (2022) developed an automated muscle fatigue detection system and acquired 58 healthy volunteers’ signals under dynamic muscle fatiguing contractions. The extreme learning machine (ELM) model performs well with a 94.09% result. Wang J. H. et al. (2021) proposed a new muscle fatigue recognition model based on the long short-term memory (LSTM) network. Rejith et al. (2016) estimated the elbow kinematics under fatigue using sEMG by Multi-layered Perceptron Neural Network (MLPNN) which gave a classification accuracy of 60.12%. Chen et al. (2021a) studied fatigue of miners with physiological signals by extreme gradient boosting (XG-Boost).
Surface Electromyography Based Multisource Information Fusion for Exercise Fatigue
Multi-sensor fusion based on sEMG can collect more dimensions of human activities from multiple dimensions. Thus, it is more comprehensive than fusion methods that use data from a single sensor. Qi et al. (2018) proposed a method for driving fatigue assessment based on the electroencephalogram (EEG) and EMG. Zhao et al. (2020) proposed a wearable monitoring device by integrating electrocardiogram and electromyogram (ECG/EMG) sensors to acquire data for monitoring fatigue during rehabilitation training. Martinez-Aguilar and Gutierrez (2019) analyzed cortico-muscular and cortico-cardiac coupling to study the development of muscular fatigue by electromyography (EMG), electrocardiography (ECG), and electroencephalography (EEG). Bilgin et al. (2015) presented a muscle fatigue detection method based on the frequency spectrum of EMG and mechanomyogram (MMG). Scano et al. (2020) studied the combined use of NIRS and sEMG in muscle fatigue assessment.
Discussion and Conclusion
Fatigue detection based on surface EMG has important application value in sports training, rehabilitation treatment, and movement recognition. This article aimed to provide an overview of sEMG signal processing, feature extraction, and classification in exercise fatigue. In real-time detection, portability of the device, removal of artifacts, feature extraction, and classification techniques should be properly investigated. Using appropriate methods can remove noise to improve EMG signal quality. With the increase in the number of EMG channels and features, it is necessary to choose a reasonable dimensionality reduction method. The methods should greatly reduce the computational complexity of the classifier and preserve maximum information of the signal. Classification techniques have been extensively studied, but their timeliness and generalization still have research significance. A combination of processing methods and pattern recognition techniques may be helpful to increase the classification speed and accuracy. And the adaptability of good algorithms to fresh samples needs further study. Finally, we propose that the current review can be used as a guide for further improving exercise fatigue assessment based on sEMG for various applications of the human body.
Author Contributions
JS mainly wrote the manuscript under the guidance of GL and JC. YS, KL, and ZZ participated in the analysis. All authors contributed to the article and approved the submitted version.
Funding
This work described in this manuscript was supported by the National Key Research and Development Program of China (2018YFF0300806-1) and the Science and Technology Development Plan Project of Jilin Province (20200404205YY).
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s Note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
References
Ahmadizadeh, C., Khoshnam, M., and Menon, C. (2021). Human machine interfaces in upper-limb prosthesis control: a survey of techniques for preprocessing and processing of biosignals. IEEE Signal Proc. Magaz. 38, 12–22. doi: 10.1109/msp.2021.3057042
Ahmed, S. F., Joyo, M. K., Mahdi, H. F., and Kiwarkis, I. J. (2020). “Muscle fatigue detection and analysis using EMG sensor,” in Proceedings of the 2020 IEEE 7th International Conference on Engineering Technologies and Applied Sciences (ICETAS), Kuala Lumpur. doi: 10.1109/ICETAS51660.2020.9484230
Alam, M. M., Khan, A. A., and Farooq, M. (2020). Effects of vibration therapy on neuromuscular efficiency & features of the EMG signal based on endurance test. J. Bodywork Movement Ther. 24, 325–335. doi: 10.1016/j.jbmt.2020.06.037
Alberto, R., Draicchio, F., Varrecchia, T., Silvetti, A., and Iavicoli, S. (2018). Wearable monitoring devices for biomechanical risk assessment at work: current status and future challengesa systematic review. Int. J. Environ. Res. Public Health 15:26. doi: 10.3390/ijerph15092001
Avian, C., Prakosa, S. W., Faisal, M., and Leu, J. S. (2022). Estimating finger joint angles on surface EMG using manifold learning and long short-term memory with attention mechanism. Biomed. Signal Proc. Control 71:15. doi: 10.1016/j.bspc.2021.103099
Barszap, A. G., Skavhaug, I.-M., and Joshi, S. S. (2016). Effects of muscle fatigue on the usability of a myoelectric human-computer interface. Hum. Movement Sci. 49, 225–238. doi: 10.1016/j.humov.2016.06.009
Bharathi, K. D., Karthick, P. A., and Ramakrishnan, S. (2022). Automated detection of muscle fatigue conditions from cyclostationary based geometric features of surface electromyography signals. Comput. Methods Biomechan. Biomed. Eng. 25, 320–332. doi: 10.1080/10255842.2021.1955104
Bilgin, G., Hindistan, I. E., Özkaya, Y. G., Köklükaya, E., Polat, Ö, and Çolak, ÖH. (2015). Determination of fatigue following maximal loaded treadmill exercise by using wavelet packet transform analysis and MLPNN from MMG-EMG data combinations. J. Med. Syst. 39:108. doi: 10.1007/s10916-015-0304-5
Bukhari, W. M., Yun, C. J., Kassim, A. M., and Tokhi, M. O. (2020). Study of K-nearest neighbour classification performance on fatigue and non-fatigue EMG signal features. Int. J. Adv. Comput. Sci. Appl. 11, 41–47.
Chai, G., Wang, Y., Wu, J., Yang, H., Tang, Z., and Zhang, L. (2019). Study on the recognition of exercise intensity and fatigue on runners based on subjective and objective information. Healthcare 7:4.
Chandra, S., Hayashibe, M., and Thondiyath, A. (2020). Muscle fatigue induced hand tremor clustering in dynamic laparoscopic manipulation. IEEE Trans. Syst. Man Cybernet. Syst. 50, 5420–5431. doi: 10.1109/tsmc.2018.2882957
Chang, K.-M., Liu, S.-H., and Wu, X.-H. (2012). A wireless sEMG recording system and its application to muscle fatigue detection. Sensors 12, 489–499. doi: 10.3390/s120100489
Chapman, M., Larumbe-Zabala, E., Gosss-Sampson, M., Colpus, M., Triplett, N. T., and Naclerio, F. (2019). Perceptual, mechanical, and electromyographic responses to different relative loads in the parallel squat. J. Stren. Condit. Res. 33, 8–16. doi: 10.1519/jsc.0000000000001867
Chen, L. L., Zhang, C., Liu, Z. J., and Zhang, T. Y. (2018). Evaluation of muscle fatigue based on CRP and RQA for upper limb exoskeleton. Chin. Automat. Cong. 2018, 4210–4215.
Chen, S. K., Xu, K. L., Yao, X. W., Zhu, S. Y., Zhang, B. H., Zhou, H. D., et al. (2021b). Psychophysiological data-driven multi-feature information fusion and recognition of miner fatigue in high-altitude and cold areas. Comput. Biol. Med. 133:14. doi: 10.1016/j.compbiomed.2021.104413
Chen, S. K., Xu, K. L., Yao, X. W., Ge, J., Li, L., Zhu, S. Y., et al. (2021a). Information fusion and multi-classifier system for miner fatigue recognition in plateau environments based on electrocardiography and electromyography signals. Comput. Methods Prog. Biomed. 211:17. doi: 10.1016/j.cmpb.2021.106451
Chlif, M., Keochkerian, D., Temfemo, A., Choquet, D., and Ahmaidi, S. (2018). Relationship between electromyogram spectrum parameters and the tension-time index during incremental exercise in trained subjects. J. Sports Sci. Med. 17, 509–514.
Cortez, L., Mackay, K., Contreras, E., and Penailillo, L. (2017). Acute effect of caffeine ingestion on reaction time and electromyographic activity of the dollyo chagi round kick in taekwondo fighters. Ricyde Rev. Int. De Cien. Del Dep. 13, 52–62. doi: 10.5232/ricyde2017.04704
Cui, C. H., Xin, E. Q., Qu, M. L., and Jiang, S. (2021). Fatigue and abnormal state detection by using EMG signal during football training. Int. J. Dis. Syst. Technol. 12, 13–23. doi: 10.4018/ijdst.2021040102
Cui, W., Chen, X., Cao, S., and Zhang, X. (2017). Muscle fatigue analysis of the deltoid during three head-related static isometric contraction tasks. Entropy 19:5.
De la Pena, S., Polo, A., and Robles-Algarin, C. (2019). Implementation of a portable electromyographic prototype for the detection of muscle fatigue. Electronics 8:15. doi: 10.3390/electronics8060619
Dieterich, A. V., Botter, A., Vieira, T. M., Peolsson, A., Petzke, F., Davey, P., et al. (2017). Spatial variation and inconsistency between estimates of onset of muscle activation from EMG and ultrasound. Sci. Rep. 7:42011. doi: 10.1038/srep42011
Elsais, W. M., Preece, S. J., Jones, R. K., and Herrington, L. (2020). Could relative movement between the adductor muscles and the skin invalidate surface electromyography measurement? J. Appl. Biomechan. 36, 1–7.
Fan, X., Xu, H. B., Huang, W. Y., and Lin, Y. F. (2018). “Muscle fatigue recognition based on sEMG characteristics,” in Proceeding of the International Conference on Electrical, Control, Automation and Robotics, (Lancaster: Destech Publications, Inc), 493–497.
Fang, C. M., He, B. W., Wang, Y. X., Cao, J., and Gao, S. (2020). EMG-centered multisensory based technologies for pattern recognition in rehabilitation: state of the art and challenges. Biosensors Basel 10:30. doi: 10.3390/bios10080085
Fang, N. L., Zhang, C., and Lv, J. (2021). Effects of vertical lifting distance on upper-body muscle fatigue. Int. J. Environ. Res. Public Health 18:17. doi: 10.3390/ijerph18105468
Fundaro, C., Gazzoni, M., Pinna, G. D., Dallocchio, C., Rainoldi, A., and Casale, R. (2021). Is fatigue a muscular phenomenon in parkinson’s disease? Implications for rehabilitation. Eur. J. Phys. Rehabilit. Med. 57, 691–700. doi: 10.23736/s1973-9087.21.06621-1
Gandevia, S. C. (2001). Spinal and supraspinal factors in human muscle fatigue. Physiol. Rev. 81, 1725–1789.
Gaudet, S., Tremblay, J., and Dal Maso, F. (2018). Evolution of muscular fatigue in periscapular and rotator cuff muscles during isokinetic shoulder rotations. J. Sports Sci. 36, 2121–2128. doi: 10.1080/02640414.2018.1440513
Ghapanchizadeh, H., Ahmad, S. A., and Ishak, A. J. (2016). Recommended surface EMG electrode position for wrist extension and flexion. Biomed. Eng. Sci. 108–112.
Gonzalez-Zamora, P., Benitez, V. H., and Pacheco, J. (2022). A feature-based processing framework for real-time implementation of muscle fatigue measurement. Cluster Comput. J. Networks Software Tools Appl. 10:343. doi: 10.1007/s10586-021-03437-7
Goubault, E., Martinez, R., Bouffard, J., Dowling-Medley, J., Begon, M., and Dal Maso, F. (2022). Shoulder electromyography-based indicators to assess manifestation of muscle fatigue during laboratory-simulated manual handling task. Ergonomics 65, 118–133. doi: 10.1080/00140139.2021.1958013
Greco, A., Valenza, G., Bicchi, A., Bianchi, M., and Scilingo, E. P. (2019). Assessment of muscle fatigue during isometric contraction using autonomic nervous system correlates. Biomed. Signal Proc. Control 51, 42–49. doi: 10.1016/j.bspc.2019.02.007
Gupta, A., Mudie, K. L., and Clothier, P. J. (2014). The reliability of determining the onset of medial gastrocnemius muscle activity during a stretch-shorten-cycle action. J. Electr. Kinesiol. 24, 588–592.
Halson, H., and Shona, L. (2014). Monitoring training load to understand fatigue in athletes. Sports Med. 44:S139.
Harmon, K. K., Hamilton, A. S., Johnson, B. D., Bartek, F. J., Girts, R. M., MacLennan, R. J., et al. (2021). Motor unit action potential amplitude during low torque fatiguing contractions versus high-torque non-fatiguing contractions: a multilevel analysis. Eur. J. Appl. Physiol. 121, 1145–1157. doi: 10.1007/s00421-021-04606-7
Hedayatpour, N., Rashid, D. M. S., Izanloo, Z., Seylaneh, H., and Falla, D. (2021). Men and women show different adaptations of quadriceps activity following fatiguing contractions: an explanation for the increased incidence of sports-related knee injuries in women? J. Electr. Kinesiol. 58:6. doi: 10.1016/j.jelekin.2021.102552
Hernandez, L., and Camic, C. (2019). Fatigue-mediated loss of complexity is contraction-type dependent in vastus lateralis electromyographic signals. Sports 7:4.
Hou, X., Wang, X. L., Griffin, L., Liao, F. Y., Peters, J., and Jan, Y. K. (2021). Immediate and delayed effects of cupping therapy on reducing neuromuscular fatigue. Front. Bioeng. Biotechnol. 9:10. doi: 10.3389/fbioe.2021.678153
Huebner, A., Faenger, B., Schenk, P., Scholle, H. C., and Anders, C. (2015). Alteration of Surface EMG amplitude levels of five major trunk muscles by defined electrode location displacement. J. Electr. Kinesiol. 25, 214–223.
Jero, S. E., and Ramakrishnan, S. (2019). “Analysis of muscle fatigue conditions in surface EMG signal with a novel hilbert marginal spectrum entropy method,” in Proceeding of the 41st Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC), (New York: Ieee), 2675–2678.
Ji, D. L., and Huang, Q. C. (2021). Self-maintenance and automatic identification of the fatigue status of the human body based on internet of things technology. Sust. Energy Technol. Assess. 45:9. doi: 10.1016/j.seta.2021.101193
Jo, M., Ahn, S., Kim, J., Koo, B., Jeong, Y., Kim, S., et al. (2018). Mechanomyography for the measurement of muscle fatigue caused by repeated functional electrical stimulation. Int. J. Prec. Eng. Manufact. 19, 1405–1410. doi: 10.1007/s12541-018-0166-0
Kahl, L., and Hofmann, U. G. (2016). Comparison of algorithms to quantify muscle fatigue in upper limb muscles based on sEMG signals. Med. Eng. Phys. 2016, 1260–1269.
Karthick, P., Ghosh, A., Maitra, D., and Ramakrishnan, S. (2018). Surface electromyography based muscle fatigue detection using high-resolution time-frequency methods and machine learning algorithms. Comput. Methods Prog. Biomed. 154, 45–56.
Khan, T., Lundgren, L. E., Jrpe, E., Olsson, M. C., and Viberg, P. (2019). A novel method for classification of running fatigue using change-point segmentation. Sensors 19:21.
Kim, H., Lee, J., and Kim, J. (2018). Electromyography-signal-based muscle fatigue assessment for knee rehabilitation monitoring systems. Biomed. Eng. Lett. 8, 345–353. doi: 10.1007/s13534-018-0078-z
Kuniszyk-Jozkowiak, W., Jaszczuk, J., and Czaplicki, A. (2018). Changes in electromyographic signals and skin temperature during standardised effort in volleyball players. Acta Bioeng. Biomechan. 20, 115–122. doi: 10.5277/abb-01198-2018-02
Kwon, H., Di Cristina, J. F., Rutkove, S. B., and Sanchez, B. (2018). Recording characteristics of electrical impedance-electromyography needle electrodes. Physiol. Measure. 39:aabb8c. doi: 10.1088/1361-6579/aabb8c
Lejun, W., Yuting, W., Aidi, M., Guoqiang, M., Yu, Y., Ruijie, L., et al. (2018). A comparative study of EMG indices in muscle fatigue evaluation based on grey relational analysis during all-out cycling exercise. BioMed Res. Int. 2018, 1–8.
Li, Y. K. (2017). An adaptive muscle fatigue model based on human physiology. Agro Food Industry Hi Tech 28, 2107–2111.
Liu, J., Ying, D., and William, Z. (2015). Robust muscle activity onset detection using an unsupervised electromyogram learning framework. PLoS One 1–15. doi: 10.1371/journal.pone.0127990
Liu, S. H., Lin, C. B., Chen, Y., Chen, W. X., Huang, T. S., and Hsu, C. Y. (2019). An EMG patch for the real-time monitoring of muscle-fatigue conditions during exercise. Sensors 19:15. doi: 10.3390/s19143108
Liu, X. L., and Li, Z. B. (2021). Influence mechanism of running sportswear fatigue based on BP neural network. Eurasip J. Adv. Signal Proc. 2021:15. doi: 10.1186/s13634-021-00778-8
Makaram, N., Karthick, P. A., and Swaminathan, R. (2021). Analysis of dynamics of EMG signal variations in fatiguing contractions of muscles using transition network approach. IEEE Trans. Instrument. Measure. 70:8. doi: 10.1109/tim.2021.3063777
Marco, G., Alberto, B., and Taian, V. (2017). Surface EMG and muscle fatigue: multi-channel approaches to the study of myoelectric manifestations of muscle fatigue. Physiol. Meas. 38, R27–R60. doi: 10.1088/1361-6579/aa60b9
Martinez-Aguilar, G. M., and Gutierrez, D. (2019). Using cortico-muscular and cortico-cardiac coherence to study the role of the brain in the development of muscular fatigue. Biomed. Signal Proc. Control 48, 153–160. doi: 10.1016/j.bspc.2018.10.011
Meng, Q., Zhang, J. J., and Yang, X. (2019). Virtual rehabilitation training system based on surface EMG feature extraction and analysis. J. Med. Syst. 43:11. doi: 10.1007/s10916-019-1166-z
Na, Y. J., Lee, H. J., and Kwon, S. (2020). Investigating the effects of long-term contractions on myoelectric recognition of wrist movements from stroke patients. Int. J. Precis. Eng. Manufact. 21, 1771–1779. doi: 10.1007/s12541-020-00364-2
Nijs, J., Aelbrecht, S., Meeus, M., Van Oosterwijck, J., Zinzen, E., and Clarys, P. (2011). Tired of being inactive: a systematic literature review of physical activity, physiological exercise capacity and muscle strength in patients with chronic fatigue syndrome. Disabili. Rehabilit. 33, 1493–1500. doi: 10.3109/09638288.2010.541543
Pakosz, P., and Konieczny, M. (2020). Training induced fatigability assessed by sEMG in pre-olympic ice-skaters. Sci. Rep. 10:1052. doi: 10.1038/s41598-020-71052-4
Pancholi, S., and Joshi, A. M. (2018). Portable EMG data acquisition module for upper limb prosthesis application. IEEE Sen. J. 18, 3436–3443. doi: 10.1109/JSEN.2018.2809458
Park, S. Y., and Park, C. H. (2021). Diagnosis of muscle fatigue using surface electromyography and analysis of associated factors in type 2 diabetic patients with neuropathy: a preliminary study. Int. J. Environ. Res. Public Health 18:8. doi: 10.3390/ijerph18189635
Qi, L. P., Ma, X. C., Zhou, D. D., Guan, S., Gao, F. S., and Cong, P. X. (2020). Wavelet and principal component analysis of electromyographic activity and slow component of oxygen uptake during heavy and severe cycling exercise. Appl. Physiol. Nutr. Metab. 45, 187–192. doi: 10.1139/apnm-2019-0037
Qi, M. S., Xie, P., Zhang, Y. Y., Yang, W. J., Liu, Z. J., Cheng, S. C., et al. (2018). Driver fatigue assessment based on the feature fusion and transfer learning of EEG and EMG. Chin. Automat. Cong. 2018, 1314–1317.
Quittmann, O. J., Abel, T., Albracht, K., and Struder, H. K. (2020). Biomechanics of all-out handcycling exercise: kinetics, kinematics and muscular activity of a 15-s sprint test in able-bodied participants. Sports Biomechan. [Epub ahead of print]. doi: 10.1080/14763141.2020.1745266
Rejith, R., Raj, R., and Sivanandan, K. S. (2016). “Estimation of elbow kinematics under fatigue and non-fatigue conditions using MLPN network based on sEMG signal,” in Proceeding of the 2016 International Conference on Inventive Computation Technologies (ICICT)), 1–5.
Rodriguez-Rosell, D., Yanez-Garcia, J. M., Mora-Custodio, R., Sanchez-Medina, L., Ribas-Serna, J., and Gonzalez-Badillo, J. J. (2021). Effect of velocity loss during squat training on neuromuscular performance. Scand. J. Med. Sci. Sports 31, 1621–1635. doi: 10.1111/sms.13967
Sae-Lim, W., Phukpattaranont, P., and Thongpull, K. (2019). “Effect of electrode skin impedance on electromyography signal quality,” in Proceeding of the 2018 15th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON)).
Sato, H., Nishimura, Y., Tsuboi, H., Minoshima, Y., Sakata, T., Umezu, Y., et al. (2021). Differences in fatigability of vastus medialis muscle between patients with limb symmetry index of 90% and 90% after chronic anterior cruciate ligament reconstruction. KNEE 31, 39–45. doi: 10.1016/j.knee.2021.05.005
Scano, A., Pirovano, I., Manunza, M. E., Spinelli, L., and Re, R. (2020). Sustained fatigue assessment during isometric exercises with time-domain near infrared spectroscopy and surface electromyography signals. Biomed. Opt. Exp. 11:7357.
Shahmoradi, S., Zare, A., and Behzadipour, S. (2017). “Fatigue status recognition in a post-stroke rehabilitation exercise with sEMG signal,” in Proceeding of the 24th National Iranian Conference on Biomedical Engineering/2nd International Iranian Conference on Biomedical Engineering (ICBME)), 162–166.
Silva, M. F., Dias, J. M., Dela Bela, L. F., Pelegrinelli, A. R. M., Lima, T. B., Carvalho, R. G. D., et al. (2020). A review on muscle activation behaviour during gait in shallow water and deep-water running and surface electromyography procedures. J. Bodywork Movement Ther. 24, 432–441. doi: 10.1016/j.jbmt.2020.06.005
Silvetti, A., Chini, G., Ranavolo, A., and Draicchio, F. (2017). “Upper limb repetitive movement risk assessment by means of sEMG parameters,” in Proceeding of the International Conference on Social& Occupational Ergonomics/8th International Conference on Applied Human Factors and Ergonomics (AHFE), (CHAM: Springer International Publishing Ag), 213–221.
Simsek, D. (2017). Different fatigue-resistant leg muscles and EMG response during whole-body vibration. J. Electr. Kinesiol. 37, 147–154. doi: 10.1016/j.jelekin.2017.10.006
Subasi, A., and Kiymik, M. K. (2010). Muscle fatigue detection in EMG using time-frequency methods, ICA and neural networks. J. Med. Syst. 34, 777–785. doi: 10.1007/s10916-009-9292-7
Tang, D. X., Yu, Z., He, Y., Asghar, W., Zheng, Y. N., Li, F. L., et al. (2020). Strain-insensitive elastic surface electromyographic (sEMG) electrode for efficient recognition of exercise intensities. Micromachines 11:12. doi: 10.3390/mi11030239
Tapia, C., Daud, O., and Ruiz-Del-Solar, J. (2017). EMG signal filtering based on independent component analysis and empirical mode decomposition for estimation of motor activation patterns. J. Med. Biol. Eng. 37, 140–155. doi: 10.1007/s40846-016-0201-5
Too, J., Abdullah, A. R., Saad, N. M., Ali, N. M., and Tee, W. (2018b). A new competitive binary grey wolf optimizer to solve the feature selection problem in EMG signals classification. Computers 7:18. doi: 10.3390/computers7040058
Too, J., Abdullah, A. R., Saad, N. M., and Ali, N. M. (2018a). Feature selection based on binary tree growth algorithm for the classification of myoelectric signals. Machines 6:65. doi: 10.3390/machines6040065
Triwiyanto, T., Wahyunggoro, O., Adi Nugroho, H., and Herianto, H. (2017). Continuous wavelet transform analysis of surface electromyography for muscle fatigue assessment on the elbow joint motion. Adv. Electr. Electr. Eng. 15, 424–434. doi: 10.15598/aeee.v15i3.2173
Triwiyanto, T., Wahyunggoro, O., Nugroho, H. A., and Herianto. (2018). Adaptive threshold to compensate the effect of muscle fatigue on elbow-joint angle estimation based on electromyography. J. Mechan. Eng. Sci. 12, 3786–3796. doi: 10.15282/jmes.12.3.2018.3.0334
Wan, J. J., Qin, Z., Wang, P. Y., Sun, Y., and Liu, X. (2017). Muscle fatigue: general understanding and treatment. Exp. Mol. Med. 49:e384. doi: 10.1038/emm.2017.194
Wang, C. (2021). Analyzing the influencing factors of sports fatigue based on algorithm. Revista Brasileira De Medicina Do Esporte 27, 377–380. doi: 10.1590/1517-8692202127042021_0125
Wang, J., Sun, Y., and Sun, S. (2020). Recognition of muscle fatigue status based on improved wavelet threshold and CNN-SVM. IEEE Access 8, 207914–207922.
Wang, J. H., Sun, S. M., and Sun, Y. N. (2021). A muscle fatigue classification model based on LSTM and improved wavelet packet threshold. Sensors 21:16. doi: 10.3390/s21196369
Wang, L., Wang, H., and Liu, J. (2021). Discrimination of driver fatigue based on distortion energy density theory and multiple physiological signals. IEEE Access 9, 151824–151833. doi: 10.1109/ACCESS.2021.3125052
Wang, S. R., Tang, H., Wang, B., and Mo, J. (2018). A novel approach to detecting muscle fatigue based on sEMG by using neural architecture search framework. IEEE Trans. Neural Networks Learn. Syst. 1–12. doi: 10.1109/tnnls.2021.3124330
Whittaker, R. L., Sonne, M. W., and Potvin, J. R. (2019). Ratings of perceived fatigue predict fatigue induced declines in muscle strength during tasks with different distributions of effort and recovery. J. Electr. Kinesiol. 47, 88–95. doi: 10.1016/j.jelekin.2019.05.012
Wu, Q., Xi, C., Ding, L., Wei, C., Ren, H., Law, R., et al. (2017). Classification of EMG signals by BFA-optimized GSVCM for diagnosis of fatigue status. IEEE Trans. Autom. Sci. Eng. 14, 915–930.
Yamagishi, K., Nakanishi, T., Mihara, S., Azuma, M., Takeoka, S., Kanosue, K., et al. (2019). Elastic kirigami patch for electromyographic analysis of the palm muscle during baseball pitching. NPG Asia Mater. 11:183. doi: 10.1038/s41427-019-0183-1
Yousif, H. A., Norasmadi, A. R., Salleh, A. B., Zakaria, A., and Alfarhan, K. A. (2019). Assessment of muscles fatigue during 400-meters Running Strategies Based on the surface EMG signals. J. Biomimet. Biomat. Biomed. Eng. 42, 1–13.
Yu, N., Hong, L., and Guo, J. (2021). Analysis of upper-limb muscle fatigue in the process of rotary handling. Int. J. Industr. Ergon. 83:9. doi: 10.1016/j.ergon.2021.103109
Zanca, G. G., Oliveira, A., Ansanello, W., Barros, F. C., and Mattiello, S. M. (2014). EMG of upper trapezius electrode sites and association with clavicular kinematics. J. Electr. Kinesiol. Off. J. Int. Soc. Electr. Kinesiol. 24, 868–874.
Zeng, J., Zhou, Y., Yang, Y. C., Xu, Z. L., Zhang, H. W., and Liu, H. H. (2021). “Robustness of combined sEMG and ultrasound modalities against muscle fatigue in force estimation,” in Proceeding of the 14th International Conference on Intelligent Robotics and Applications (ICIRA)), 213–221.
Zhang, C., Chen, X., Cao, S., Zhang, X., and Chen, X. (2019). A novel HD-sEMG preprocessing method integrating muscle activation heterogeneity analysis and kurtosis-guided filtering for high-accuracy joint force estimation. IEEE Trans. Neural Syst. Rehabili. Eng. 27, 1920–1930. doi: 10.1109/tnsre.2019.2933811
Zhang, X., and Zhou, P. (2012). Sample entropy analysis of surface EMG for improved muscle activity onset detection against spurious background spikes. J. Electr. Kinesiol. 22:6.
Zhang, Y., Chen, S., Cao, W., Guo, P., Gao, D., Wang, M., et al. (2021). MFFNet: multi-dimensional feature fusion network based on attention mechanism for sEMG analysis to detect muscle fatigue. Exp. Syst. Appl. 185:115639. doi: 10.1016/j.eswa.2021.115639
Zhao, S. M., Liu, J. X., Gong, Z. D., Lei, Y. S., OuYang, X., Chan, C. C., et al. (2020). Wearable physiological monitoring system based on electrocardiography and electromyography for upper limb rehabilitation training. Sensors 20:17. doi: 10.3390/s20174861
Keywords: exercise fatigue, sEMG, machine learning, feature extraction, classification
Citation: Sun J, Liu G, Sun Y, Lin K, Zhou Z and Cai J (2022) Application of Surface Electromyography in Exercise Fatigue: A Review. Front. Syst. Neurosci. 16:893275. doi: 10.3389/fnsys.2022.893275
Received: 10 March 2022; Accepted: 07 June 2022;
Published: 11 August 2022.
Edited by:
Mikhail Lebedev, Skolkovo Institute of Science and Technology, RussiaReviewed by:
Karthick P. A., National Institute of Technology Tiruchirappalli, IndiaRamakrishnan Swaminathan, Indian Institute of Technology Madras, India
Xinjun Sheng, Shanghai Jiao Tong University, China
Copyright © 2022 Sun, Liu, Sun, Lin, Zhou and Cai. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Jing Cai, caijing1979@jlu.edu.cn