New Wavelet Indices to Assess Muscle Fatigue during Dynamic Contractions
The purpose of this study was to evaluate and
compare new indices based on the discrete wavelet transform
with another spectral parameters proposed in the literature as
mean average voltage, median frequency and ratios between
spectral moments applied to estimate acute exercise-induced
changes in power output, i.e., to assess peripheral muscle
fatigue during a dynamic fatiguing protocol. 15 trained
subjects performed 5 sets consisting of 10 leg press, with 2
minutes rest between sets. Surface electromyography was
recorded from vastus medialis (VM) muscle. Several surface
electromyographic parameters were compared to detect
peripheral muscle fatigue. These were: mean average voltage
(MAV), median spectral frequency (Fmed), Dimitrov spectral
index of muscle fatigue (FInsm5), as well as other five
parameters obtained from the discrete wavelet transform
(DWT) as ratios between different scales. The new wavelet
indices achieved the best results in Pearson correlation
coefficients with power output changes during acute dynamic
contractions. Their regressions were significantly different
from MAV and Fmed. On the other hand, they showed the
highest robustness in presence of additive white gaussian
noise for different signal to noise ratios (SNRs). Therefore,
peripheral impairments assessed by sEMG wavelet indices
may be a relevant factor involved in the loss of power output
after dynamic high-loading fatiguing task.
[1] Farina D. "Interpretation of the surface electromyogram in dynamic
contractions". Exerc.Sport Sci.Rev. 2006, vol.34, no. 3, pp. 121-127.
[2] Farina D, Merletti R, Enoka RM. "The extraction of neural strategies
from the surface EMG". J.Appl Physiol 2004, vol. 4, pp. 1486-1495.
[3] Komi PV, Tesch P. "EMG frequency spectrum, muscle structure, and
fatigue during dynamic contractions in man". Eur.J.Appl Physiol
Occup.Physiol 1979, vol. 1, pp. 41-50.
[4] Bigland-Ritchie B, Johansson R, Lippold OC, Woods JJ. Contractile
speed and EMG changes during fatigue of sustained maximal voluntary
contractions. J.Neurophysiol. 1983 Jul;50(1):313-24.
[5] Cheng AJ, Rice CL. Fatigue and recovery of power and isometric torque
following isotonic knee extensions. J.Appl.Physiol 2005
Oct;99(4):1446-52.
[6] Klass M, Guissard N, Duchateau J. Limiting mechanisms of force
production after repetitive dynamic contractions in human triceps surae.
J.Appl.Physiol 2004 Apr;96(4):1516-21.
[7] Linnamo V, Hakkinen K, Komi PV. Neuromuscular fatigue and
recovery in maximal compared to explosive strength loading.
Eur.J.Appl.Physiol Occup.Physiol 1998;77(1-2):176-81.
[8] Basmajian, JV. and De Luca CJ. Muscles Alive: Their Functions
Revealed by Electromyography. 5th ed, Baltimore, MD: Williams and
Wilkins, 1985, pp. 201-222.
[9] Chaffin, DB. "Localized muscle fatigue, definition and measurements".
J. Occup. Med. 1985, vol. 15, pp. 346-354.
[10] Lindström L., and Petersen I. "Power spectrum analysis of EMG signals
and its application". Computer-aided Electromyography, J. E. Desmedt
(Ed.). Prog. Clin. Neurophysiol, 1983, vol. 10, pp. 1-51.
[11] Moxham J., Edwards RHT, Aubier M. "Changes in EMG power
spectrum (high-to-low ratio) with force fatigue in humans". J. Appl.
Physiol. 1982, vol. 53, pp. 1094-1099.
[12] Dimitrov GV, Arabadzhiev TI, Mileva KN, Bowtell JL, Crichton N, and
Dimitrova NA. "Muscle fatigue during dynamic contractions assessed by
new spectral indices". Med Sci Sports Exerc 2006, vol. 38, no. 11, pp.
1971-1979.
[13] Akay M. Detection and estimation methods of biomedical signals. New
York: Academic Press, 1996.
[14] Cuiwei L, Chongxun Z, Changfen T. "Detection of ECG characteristic
points using wavelet transforms". IEEE Trans Biomed Eng 1995, vol.
42, pp. 21-28.
[15] Fang J, Agarwall GC, Shahani BT. "Decomposition of multiunit
electromyographic signals". IEEE Trans Biomed Eng 1999, vol. 46, pp.
685-697.
[16] al-Fahoum AS, Howitt I. "Combined wavelet transformation and radial
basis neural networks for classifying life-threatening cardiac
arrhythmias". Med Biol Eng Comput 1999, vol. 37, pp.566-573.
[17] Rodríguez I, Gila L, Malanda A, Gurtubay I, Mallor F, Gómez S,
Navallas J, Rodríguez J. "Motor unit action potential duration, II: a new
automatic measurement method based on the wavelet transform". J Clin
Neurophysiol 2007, vol. 24, pp. 59-69.
[18] Geva AB, Kerem DH. "Forecasting generalized epileptic seizures from
the EEG signal by wavelet analysis and dynamic unsupervised fuzzy
clustering". IEEE Trans Biomed Eng 1998, vol. 45, pp. 1205-1216.
[19] Gurtubay IG, Alegre M, Labarga A, Malanda A, Iriarte J, Artieda J.
"Gamma band activity in an auditory oddball paradigm studied with the
wavelet transform". Clin Neurophysiol 2001, vol. 112, pp.1219-1228.
[20] Englehart K., Hudgins B., Parker P. and Stevenson M. "Time-frequency
representation for classification of the transient myoelectric signal", in
Proc. 20th Ann. In.l Conf. on Engineering in Medicine and Biology
Society, 1998.
[21] Englehart K. "Signal Representation for Classification of the Transient
Myoelectric Signal". Ph.D. dissertation. University of New Brunswick,
Canada, 1998.
[22] Englehart K., Hudgins B., Parker P. "A Wavelet -Based Continuous
Classification Scheme for Multifucntion Myoelectric Control". IEEE
Transactions on Biomedical Engineering 2001, vol. 48, No. 3, pp. 302-
311.
[23] Rodríguez I, Vuskovic M. "Wavelet transform moments for feature
extraction from temporal signals". Informatics in Control, Automation
and Robotics II 2007, pp. 235-242.
[24] Sparto PJ, Parnianpour M., Barria EA, Jagadeesh JM. "Wavelet analysis
of electromyography for back muscle fatigue during isokinetic constanttorque
exertions". Spine 1999, vol. 24, pp. 1791-1798.
[25] Bonato P, Roy SH, Knaflitz M, De Luca CJ. "Time-frequency
parameters of the surface myoelectric signal for assessing muscle fatigue
during cyclic dynamic contractions". IEEE Trans.Biomed.Eng 2001, vol.
48, no.7, pp. 745-753.
[26] Karlsson S, Yu J, Akay M. "Time-frequency analysis of myoelectric
signals during dynamic contractions: a comparative study". IEEE
Trans.Biomed.Eng 2000, vol. 47, no. 2, pp. 228-238.
[27] Strang G. and Nguyen T. Wavelets and filter banks. Wellesley-
Cambridge Press, 1996.
[28] Mallat S. "Characterization of signals from multiscale edges". IEEE
Trans Pattern Anal Machine Intell 1992, vol.14, pp. 710-732.
[29] M. Zecca, S. Micera, M. C. Carrozza, and P. Dario. "Control of
Multifunctional Prosthetic Hands by Processing the Electromyographic
Signal." Critical Reviews in Biomedical Engineering 2002, vol. 30, pp.
459-485.
[1] Farina D. "Interpretation of the surface electromyogram in dynamic
contractions". Exerc.Sport Sci.Rev. 2006, vol.34, no. 3, pp. 121-127.
[2] Farina D, Merletti R, Enoka RM. "The extraction of neural strategies
from the surface EMG". J.Appl Physiol 2004, vol. 4, pp. 1486-1495.
[3] Komi PV, Tesch P. "EMG frequency spectrum, muscle structure, and
fatigue during dynamic contractions in man". Eur.J.Appl Physiol
Occup.Physiol 1979, vol. 1, pp. 41-50.
[4] Bigland-Ritchie B, Johansson R, Lippold OC, Woods JJ. Contractile
speed and EMG changes during fatigue of sustained maximal voluntary
contractions. J.Neurophysiol. 1983 Jul;50(1):313-24.
[5] Cheng AJ, Rice CL. Fatigue and recovery of power and isometric torque
following isotonic knee extensions. J.Appl.Physiol 2005
Oct;99(4):1446-52.
[6] Klass M, Guissard N, Duchateau J. Limiting mechanisms of force
production after repetitive dynamic contractions in human triceps surae.
J.Appl.Physiol 2004 Apr;96(4):1516-21.
[7] Linnamo V, Hakkinen K, Komi PV. Neuromuscular fatigue and
recovery in maximal compared to explosive strength loading.
Eur.J.Appl.Physiol Occup.Physiol 1998;77(1-2):176-81.
[8] Basmajian, JV. and De Luca CJ. Muscles Alive: Their Functions
Revealed by Electromyography. 5th ed, Baltimore, MD: Williams and
Wilkins, 1985, pp. 201-222.
[9] Chaffin, DB. "Localized muscle fatigue, definition and measurements".
J. Occup. Med. 1985, vol. 15, pp. 346-354.
[10] Lindström L., and Petersen I. "Power spectrum analysis of EMG signals
and its application". Computer-aided Electromyography, J. E. Desmedt
(Ed.). Prog. Clin. Neurophysiol, 1983, vol. 10, pp. 1-51.
[11] Moxham J., Edwards RHT, Aubier M. "Changes in EMG power
spectrum (high-to-low ratio) with force fatigue in humans". J. Appl.
Physiol. 1982, vol. 53, pp. 1094-1099.
[12] Dimitrov GV, Arabadzhiev TI, Mileva KN, Bowtell JL, Crichton N, and
Dimitrova NA. "Muscle fatigue during dynamic contractions assessed by
new spectral indices". Med Sci Sports Exerc 2006, vol. 38, no. 11, pp.
1971-1979.
[13] Akay M. Detection and estimation methods of biomedical signals. New
York: Academic Press, 1996.
[14] Cuiwei L, Chongxun Z, Changfen T. "Detection of ECG characteristic
points using wavelet transforms". IEEE Trans Biomed Eng 1995, vol.
42, pp. 21-28.
[15] Fang J, Agarwall GC, Shahani BT. "Decomposition of multiunit
electromyographic signals". IEEE Trans Biomed Eng 1999, vol. 46, pp.
685-697.
[16] al-Fahoum AS, Howitt I. "Combined wavelet transformation and radial
basis neural networks for classifying life-threatening cardiac
arrhythmias". Med Biol Eng Comput 1999, vol. 37, pp.566-573.
[17] Rodríguez I, Gila L, Malanda A, Gurtubay I, Mallor F, Gómez S,
Navallas J, Rodríguez J. "Motor unit action potential duration, II: a new
automatic measurement method based on the wavelet transform". J Clin
Neurophysiol 2007, vol. 24, pp. 59-69.
[18] Geva AB, Kerem DH. "Forecasting generalized epileptic seizures from
the EEG signal by wavelet analysis and dynamic unsupervised fuzzy
clustering". IEEE Trans Biomed Eng 1998, vol. 45, pp. 1205-1216.
[19] Gurtubay IG, Alegre M, Labarga A, Malanda A, Iriarte J, Artieda J.
"Gamma band activity in an auditory oddball paradigm studied with the
wavelet transform". Clin Neurophysiol 2001, vol. 112, pp.1219-1228.
[20] Englehart K., Hudgins B., Parker P. and Stevenson M. "Time-frequency
representation for classification of the transient myoelectric signal", in
Proc. 20th Ann. In.l Conf. on Engineering in Medicine and Biology
Society, 1998.
[21] Englehart K. "Signal Representation for Classification of the Transient
Myoelectric Signal". Ph.D. dissertation. University of New Brunswick,
Canada, 1998.
[22] Englehart K., Hudgins B., Parker P. "A Wavelet -Based Continuous
Classification Scheme for Multifucntion Myoelectric Control". IEEE
Transactions on Biomedical Engineering 2001, vol. 48, No. 3, pp. 302-
311.
[23] Rodríguez I, Vuskovic M. "Wavelet transform moments for feature
extraction from temporal signals". Informatics in Control, Automation
and Robotics II 2007, pp. 235-242.
[24] Sparto PJ, Parnianpour M., Barria EA, Jagadeesh JM. "Wavelet analysis
of electromyography for back muscle fatigue during isokinetic constanttorque
exertions". Spine 1999, vol. 24, pp. 1791-1798.
[25] Bonato P, Roy SH, Knaflitz M, De Luca CJ. "Time-frequency
parameters of the surface myoelectric signal for assessing muscle fatigue
during cyclic dynamic contractions". IEEE Trans.Biomed.Eng 2001, vol.
48, no.7, pp. 745-753.
[26] Karlsson S, Yu J, Akay M. "Time-frequency analysis of myoelectric
signals during dynamic contractions: a comparative study". IEEE
Trans.Biomed.Eng 2000, vol. 47, no. 2, pp. 228-238.
[27] Strang G. and Nguyen T. Wavelets and filter banks. Wellesley-
Cambridge Press, 1996.
[28] Mallat S. "Characterization of signals from multiscale edges". IEEE
Trans Pattern Anal Machine Intell 1992, vol.14, pp. 710-732.
[29] M. Zecca, S. Micera, M. C. Carrozza, and P. Dario. "Control of
Multifunctional Prosthetic Hands by Processing the Electromyographic
Signal." Critical Reviews in Biomedical Engineering 2002, vol. 30, pp.
459-485.
@article{"International Journal of Medical, Medicine and Health Sciences:49536", author = "González-Izal M. and Rodríguez-Carreño I and Mallor-Giménez F and Malanda A and Izquierdo M", title = "New Wavelet Indices to Assess Muscle Fatigue during Dynamic Contractions", abstract = "The purpose of this study was to evaluate and
compare new indices based on the discrete wavelet transform
with another spectral parameters proposed in the literature as
mean average voltage, median frequency and ratios between
spectral moments applied to estimate acute exercise-induced
changes in power output, i.e., to assess peripheral muscle
fatigue during a dynamic fatiguing protocol. 15 trained
subjects performed 5 sets consisting of 10 leg press, with 2
minutes rest between sets. Surface electromyography was
recorded from vastus medialis (VM) muscle. Several surface
electromyographic parameters were compared to detect
peripheral muscle fatigue. These were: mean average voltage
(MAV), median spectral frequency (Fmed), Dimitrov spectral
index of muscle fatigue (FInsm5), as well as other five
parameters obtained from the discrete wavelet transform
(DWT) as ratios between different scales. The new wavelet
indices achieved the best results in Pearson correlation
coefficients with power output changes during acute dynamic
contractions. Their regressions were significantly different
from MAV and Fmed. On the other hand, they showed the
highest robustness in presence of additive white gaussian
noise for different signal to noise ratios (SNRs). Therefore,
peripheral impairments assessed by sEMG wavelet indices
may be a relevant factor involved in the loss of power output
after dynamic high-loading fatiguing task.", keywords = "Median Frequency, EMG, wavelet transform,
muscle fatigue", volume = "3", number = "7", pages = "109-6", }
