Electromyographic evidence of selective fatigue during the eccentric phase of stretch/shortening cycles in man

  • Toshio Moritani
  • Lars Oddson
  • Alf Thorstensson
Article
Accepted:

Summary

Ten male subjects were tested to determine the effects of muscle fatigue upon the activation pattern of the two main ankle extensor muscles, the ‘slow-twitch’ soleus (SOL) and the relatively ‘fast-twitchrs medial gastrocnemius (MG), during a fatiguing 60-s trial of hopping to maximal height. The myoelectric signals from SOL and MG were recorded together with the vertical ground reaction force signal and analysed by means of a computer-aided electromyograph (EMG) contour analysis, i.e. two-dimensional frequency distributions were obtained relating the activation patterns of the two synergists. The EMGs were also full-wave rectified and integrated (IEMG) according to three phases of the hopping movement (PRE, pre-activation phase; ECC, eccentric phase; CON, concentric phase). Results indicated that there were significant decreases (P<0.01) in the peak ground reaction force, the height of hopping and the mechanical power per unit body weight at the end of the fatiguing contractions. These decreases in mechanical parameters were accompanied by significant (P<0.01) decreases in all three phases of MG IEMG while SOL IEMG showed no such significant declines, except in the CON phase. Thus, the decreased mechanical parameters could in large part be accounted for by the substantial and selective decline of the excitation level of the relatively fast-twitch MG muscle. Our data suggest that the centrally mediated pre-activation of the fatiguable MG muscle as well as the MG activation during the eccentric phase, which is largely controlled by supraspinal inputs and stretch-reflex modulation, are most affected by fatigue changes during repeated maximal stretch/shortening cycles of the ankle extensors.

Key words

Selective fatigue Stretch/shortening cycle Ankle extensors 
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References

  1. Asmussen E, Bonde-Petersen F (1974) Storage of elastic energy in skeletal muscles in man. Acta Physiol Scand 91:385–392Google Scholar
  2. Bigland-Ritchie B, Jones DA, Woods JJ (1979) Excitation frequency and muscle fatigue: electrical responses during human voluntary and stimulated contractions. Exp Neurol 64:414–427Google Scholar
  3. Bigland-Ritchie B, Johansson R, Lippold OCJ, Woods JJ (1983) Contractile speed and EMG changes during fatigue of sustained maximal voluntary contractions. J Neurophysiol 50:313–324Google Scholar
  4. Bosco C, Tarkka I, Komi PV (1982a) Effect of elastic energy and myoelectric potentiation of triceps surae during stretch-shortening cycle exercise. Int J Sports Med 3:137–140Google Scholar
  5. Bosco C, Viitasalo JT, Komi PV, Luhtanen P (1982b) Combined effect of elastic energy and myoelectric potentiation during stretch-shortening cycle exercise. Acta Physiol Scand 114:557–565Google Scholar
  6. Bosco C, Tihanyi J, Latteri F, Fekete G, Apor P, Rusko H (1986) The effect of fatigue on store and re-use of elastic energy in slow and fast types of human skeletal muscle. Acta Physiol Scand 128:109–117Google Scholar
  7. Bosco C, Montanari G, Tarkka I, Latteri F, Cozzi M, Iachelli G, Faina M, Colli R, Dal Monte A, La Rosa M, Ribacchi R, Giovenali P, Cortili G, Saibene F (1987) The effect of prestretch on mechanical efficiency of human skeletal muscle. Acta Physiol Scand 131:323–329Google Scholar
  8. Cavagna GA (1978) Aspects of efficiency and inefficiency of terrestrial locomotion. In: Asmussen E, Jorgrensen K (eds) Biomechanics IV-A. University Park Press, Baltimore, pp 3–22Google Scholar
  9. Cavagna GA, Kaneko M (1977) Mechanical work and efficiency in level walking and running. J Physiol (Lond) 268:467–481Google Scholar
  10. Dietz V, Schmidtbleicher D, Hainaut K (14979) Neural mechanisms of human locomotion. J Neurophysiol 42:1212–1222Google Scholar
  11. Dietz V, Noth J, Schmidtbleicher D (1981) Interaction between pre-activity and stretch reflex in human triceps brachii during landing from forward falls. J Physiol (Lond) 311:113–125Google Scholar
  12. Friden J, Sjostrom M, Ekblom B (1983) Myofibrillar damage following intense eccentric exercise in man. Int J Sports Med 4:170–176Google Scholar
  13. Gollhofer A, Komi PV, Miyashita M, Aura O (1987) Fatigue during stretch-shortening cycle exercise: changes in mechanical performance of human skeletal muscle. Int J Sports Med 8:71–78Google Scholar
  14. Grillner S (1972) The role of muscle stiffness in meeting the changing postural and locomotor requirements for force development by the ankle extensors. Acta Physiol Scand 86:92–108Google Scholar
  15. Hodgson JA (1983) The relationship between soleus and gastrocnemius muscle activity in conscious cats — a model for motor unit recruitment? J Physiol (Lond) 337:553–562Google Scholar
  16. Kaneko M, Komi PV, Aura O (1984) Mechanical efficiency of eccentric and concentric exercises performed with medium to fast contraction rates. Scand J Sport Sci 6:15–20Google Scholar
  17. Komi PV (1984) Physiological and biomechanical correlates of muscles function: effect of muscle structure and stretch-shortening cycle on force and speed. Exerc Sports Sci Rev 12:81–121Google Scholar
  18. Komi PV, Viitasalo JT (1977) Changes in motor unit activity and metabolism in human skeletal muscle during and after repeated eccentric and concentric contractions. Acta Physiol Scand 100:246–254Google Scholar
  19. Komi PV, Kaneko M, Aura O (1987) EMG activity of the leg extensor muscles with special reference to mechanical efficiency in concentric and eccentric exercise. Int J Sports Med 8:22–29Google Scholar
  20. Moritani T, Muro M (1987) Motor unit activity and surface electromyogram power spectrum during increasing force of contraction. Eur J Appl Physiol 56:260–265Google Scholar
  21. Moritani T, Muro M, Kijima A (1985a) Electromechanical changes during electrically induced and maximal voluntary contractions: electrophysiologic responses of different muscle fiber types during stimulated contractions. Exp Neurol 88:471–483Google Scholar
  22. Moritani T, Muro M, Kijima A, Gaffney FA, Persons D (1985b) Electromechanical changes during electrically induced and maximal voluntary contractions: surface and intramuscular EMG responses during sustained maximal voluntary contraction. Exp Neurol 88:484–499Google Scholar
  23. Moritani T, Muro M, Nagata A (1986) Intramuscular and surface electromyogram changes during muscle fatigue. J Appl Physiol 60:1179–1185Google Scholar
  24. Moritani T, Muramatsu S, Muro M (1988) Activity of motor units during concentric and eccentric contractions. Am J Phys Med 66:338–350Google Scholar
  25. Newham DJ, Mills KR, Quigley BM, Edwards RHT (1983) Pain and fatigue after concentric and eccentric muscle contractions. Clin Sci 64:55–62Google Scholar
  26. Saltin B, Gollnick PD (1983) Skeletal muscle adaptability: significance for metabolism and performance. In: American Physiologial Society, Handbook of physiology, sect 10. Maryland, p 555–631Google Scholar
  27. TECA corporation (1972) Motorpoint charts and chronaxie values. New York, pp 1–18Google Scholar

Copyright information

© Springer-Verlag 1990

Authors and Affiliations

  • Toshio Moritani
    • 1
  • Lars Oddson
    • 1
  • Alf Thorstensson
    • 1
  1. 1.Department of Physiology IIIKarolinska InstituteStockholmSweden

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