Pulmonary Function Subsequent to Expiratory Muscle Fatigue in Healthy Humans

H. C. Haverkamp; M. Metelits; J. Hartnett; K. Olsson; J. R. Coast

doi:10.1055/s-2001-17612

International Journal of Sports Medicine, Inhaltsverzeichnis

Int J Sports Med 2001; 22(7): 498-503
DOI: 10.1055/s-2001-17612

Physiology and Biochemistry

Pulmonary Function Subsequent to Expiratory Muscle Fatigue in Healthy Humans

H. C. Haverkamp, M. Metelits, J. Hartnett, K. Olsson, J. R. Coast

S. A. Rasmussen Exercise Physiology Laboratory, Northern Arizona University, Flagstaff, Arizona, USA

Abstract

One of the mechanisms proposed to explain the decrement in pulmonary function often seen after exercise is fatigue of the expiratory muscles. To test the hypothesis that expiratory muscle fatigue alters lung function, several indices of pulmonary function were measured before and after expiratory muscle fatigue was induced by expiratory loaded breathing. Eight subjects completed a fatigue trial (EF) in which expiratory threshold loaded breathing was performed at an initial resistance equal to 80 % of their maximal expiratory pressure (MEP), at a respiratory rate of 13 bpm, and a duty cycle (T_I/T_Tot) of 0.33. MEP was taken at predefined intervals throughout the loaded breathing protocol, and loaded breathing was discontinued when MEP was less than 80 % of each subject’s pre EF trial MEP (T_Lim). FVC, FEV_1.0, FEF_{25 %} , FEF_{25 - 75 %} , and maximal inspiratory and expiratory pressures (MIP and MEP) were taken prior to, immediately after, and at 5, 10, and 15 min post fatigue. On a separate day a control trial (CON) was performed that was identical to each subjects EF trial with the exception that no expiratory load was utilized. At T_Lim MEP was significantly reduced (p < 0.001) by 23.5 % from the pre-expiratory loaded breathing value (183.1 ± 39.56 to 140.13 ± 30.45 mmHg), whereas it remained unchanged during the CON trial (191.06 ± 44.18 to 188.06 ± 43.50 mmHg). FVC measured prior to and immediately after T_Lim remained unchanged following both the EF (5349.45 ± 1130.8 to 5387.43 ± 1139.92 mL) and CON trials (5287.75 ± 1220.29 and 5352.78 ± 1191.30 mL). These results suggest that any expiratory muscle fatigue developed during exercise by itself does not result in altered pulmonary function. However, any interactions between expiratory muscle fatigue and other consequences of exercise that may alter lung function cannot be ruled out.

Key word:

Expiratory muscle fatigue, pulmonary function, expiratory loaded breathing, endurance exercise.

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Referenzen

References

1 Black L F, Hyatt R E. Maximal respiratory pressures: normal values and relationship to age and sex. Am Rev Respir Dis. 1969; 99 696-702
2 Coast J R, 0’Kroy J A, Akers I I F M, Dahl T. Effects of lower body pressure changes on pulmonary function. Med Sci Sports Exerc. 1998; 30 1035-1040
3 Coast J R, Haverkamp H C, Finkbone C M, Anderson K L, George S O, and Herb R A. Alterations in pulmonary function following exercise are not caused by the work of breathing alone. Int J Sports Med. 1999; 20 470-475
4 Cordain L, Rode E J, Gotshall R W, Tucker A. Residual lung volume and ventilatory muscle strength changes following maximal and submaximal exercise. Int J Sports Med. 1994; 15 158-161
5 Demedts M, Anthonisen N R. Effects of increased external airway resistance during steady-state exercise. J Appl Physiol. 1973; 35 361-366
6 Ewig J M, Griscom N T, Wohl M EB. The effect of the absence of abdominal muscles on pulmonary function and exercise. Am J Repir Crit Care Med. 1996; 153 1314-1321
7 Farrell P A, Maron M B, Hamilton L H, Maksud M G, Foster C. Time course of lung volume changes during prolonged treadmill exercise. Med Sci Sports Exerc. 1983; 15 319-324
8 Fuller D, Sullivan J, Fregosi R F. Expiratory muscle endurance performance after exhaustive submaximal exercise. J Appl Physiol. 1996; 80 1495-1502
9 Hill N S, Jacoby C, Farber H W. Effect of an endurance triathlon on pulmonary function. Med Sci Sports Exerc. 1991; 23 1260-1264
10 Hughes J M, Rosenweig D Y. Factors affecting trapped gas volume in perfused dog lungs. J Appl Physiol. 1970; 29 332-339, 1970
11 Loke J, Mahler D A, Virgulato J A. Respiratory muscle fatigue after marathon running. J Appl Physiol Respirat Environ Exercise Physiol. 1982; 52 821-824
12 Maron M B, Hamilton L H, Maksud M G. Alterations in pulmonary function consequent to competitive marathon running. Med Sci Sports. 1979; 11 244-249
13 McKenzie D K, Allen G M, Butler J E, Gandevia S C. Task failure with lack of diaphragm fatigue during inspiratory resistive loading in human subjects. J Appl Physiol. 1997; 82 2011-2019
14 Miles D S, Cox M H, Bomze J P, Gotshall R W. Acute recovery profile of lung volumes and function after running 5 miles. J Sports Med Phys Fitness. 1991; 31 243-248
15 Miles D S, Enoch A D, Grevey S C. Interpretation of changes in DL_co and pulmonary function after running five miles. Respir Physiol. 1986; 66 135-145
16 Mizuno M, Secher N H. Histochemical characteristics of human expiratory and inspiratory intercostal muscles. J Appl Physiol. 1989; 67 592-598
17 Nava S, Bellemare F. Cardiovascular failure and apnea in shock. J Appl Physiol. 1989; 66 184-189
18 Nickerson B G, Keens T G. Measuring ventilatory muscle endurance in humans as sustainable inspiratory pressure. J Appl Physiol. 1982; 52 768-772
19 0’Kroy J A, Loy R A, Coast J R. Pulmonary function changes following exercise. Med Sci Sports Exerc. 1992; 24 1359-1364
20 Olgiati R, Atchou G, Cerretelli P. Hemodynamic effects of resistive breathing. J Appl Physiol. 1986; 60 846-853
21 Suzuki S, Suzuki J, Okubo T. Expiratory muscle fatigue in normal subjects. J Appl Physiol. 1991; 70 2632-2639
22 Watchko J F, Standaert T A, Mayock D E, Twiggs G, Woodrum D E. Ventilatory failure during loaded breathing: the role of central neural drive. J Appl Physiol. 1988; 65 249-255

H. C. Haverkamp

University of Wisconsin - Madison
Department of Preventive Medicine

504 North Walnut Street
Madison, WI 53705-2368

USA

Telefon: +1 (608) 2629499

Fax: +1 (608) 2632820

eMail: hchaverkamp@students.wisc.edu