Summary
Previous experiments in the dog have shown that static contractions of the muscles of one limb elicit a reflex increase of resistance in the vessels of the opposite limb, along with an increase of systemic blood pressure. The aim of the present experiments was to examine whether this reflex can cause a redistribution of cardiac output from the resting areas, in favor of the working parts. In 17 anesthetized and ventilated dogs, static contraction of the muscles of the right thigh was elicited with electrodes inserted into these muscles. The carotid sinuses were kept at constant pressure and the vagi cut. During static contractions systemic blood pressure and cardiac output increased by 17.7±3.1 and 24.2±5.5%, respectively. The blood flow measured with an electromagnetic flowmeter decreased by 21.9±5.3% in the femoral artery of the resting limb and increased by 101±21% in the femoral artery of the “active limb∝. Data obtained in six dogs with injection of radioactive microspheres during stimulations show that blood flow decreased not only in the muscles of the resting limb (34±10%), but also in several other resting areas, such as skin (38±8%), kidney (24±8%), gut (38±6%), and tongue (23±3%). The results show that the reflex under study causes a redistribution of the cardiac output during static muscular contractions.
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References
Alam M, Smirk FH (1937) Observations in man upon a blood pressure raising reflex arising from the voluntary muscles. J Physiol (Lond) 89: 372–383
Alam M, Smirk FH (1938) Observations in man on a pulse-accelerating reflex from the voluntary muscles of the legs. J Physiol (Lond) 92: 167–177
Archie JP, Jr, Fixier DE, Ullyot DJ, Hoffmann JIE, Utley JR, Carlson EL (1973) Measurement of cardiac output with an organ trapping of radioactive microspheres. J Appl Physiol 35: 148–154
Asmussen E, Nielsen M, Wieth-Pedersen G (1943) Cortical or reflex control of respiration during muscular work? Acta Physiol Scand 6: 168–175
Bevegård BS, Shepherd JT (1967) Regulation of the circulation during exercise in man. Physiol Rev 47: 178–213
Buckberg GD, Luck JC, Payne DB, Hoffmann JIE, Archie JP, Fixier DE (1971) Some sources of error in measuring regional blood flow with radioactive microspheres. J Appl Physiol 31: 598–604
Clement DL (1974) Onderzoekingen over de reflectoire regulatie van de bloeddruk en van de vaattonus tijdens kontrakties van skeletspieren. Arscia Uitgaven NV, Brussel (Proefschrift, Rijksuniversiteit Gent)
Clement DL, Pelletier LC, Shepherd JT (1973) Role of muscular contraction in the reflex vascular responses to stimulation of muscle afferents in the dog. Circ Res 33: 386–392
Clement DL, Shepherd JT (1973) Changes in renal nerve traffic with stimulation of muscle afferents. Circulation [Suppl 4] 48: 28
Clement DL, Shepherd JT (1974) Influence of muscle afferents on the cutaneous and muscle vessels in the dog. Circ Res 35: 177–183
Clement DL, Shepherd JT (1976) Regulation of peripheral circulation during muscular exercise. Progr Cardiovasc Dis 19: 23–31
Coote JH, Hilton SM, Perez-Gonzales JF (1971) The reflex nature of the pressor response to muscular exercise. J Physiol (Lond) 215: 789–804
Crayton SC, Aung-Din R, Fixler DE, Mitchell JH (1979) Distribution of cardiac output during induced isometric exercise in dogs. Am J Physiol 236: H218-H224
Fisher ML, Nutter DO (1974) Cardiovascular reflex adjustments to static muscular contractions in the canine hindlimb. Am J Physiol 226: 648–655
Fixler DE, Atkins JM, Mitchell JH, Horwitz LD (1976) Blood flow to respiratory, cardiac and limb muscles in dogs during graded exercise. Am J Physiol 231: 1515–1519
Hirche HJ, Raff WK, Grün D (1970) The resistance to blood flow in the gastrocnemius of the dog during sustained and rhythmical isometric and isotonic contractions. Pfluegers Arch 314: 97–112
Humphreys PW, Lind AR (1963) The blood flow through active and inactive muscles of the forearm during sustained hand-grip contractions. J Physiol (Lond) 166: 120–135
Jarish A, Gaisböck F (1929) über das Verhalten des Kreislaufes bei der postanÄmischen HyperÄmie. Arch Exp Pathol Pharmacol 139: 159–171
Krasney JA, Levitzky MG, Koehler RC (1974) Sinoaortic contribution to the adjustment of systemic resistance in exercising dogs. J Appl Physiol 36: 679–685
Leusen I, Demeester G, Bouckaert JJ (1956) Pressorécepteurs artériels et débit cardiaque au cours de l'exercice musculaire. Arch Int Physiol Bioch 64: 564–570
Leusen I, Demeester G, Bouckaert JJ (1958) Influence du travail musculaire sur la circulation et la respiration chez le chien. Acta Cardiol 13: 153–172
Lind AR, Taylor SK, Humphreys PW, Kennelly BM, Donald KW (1964) The circulatory effects of sustained voluntary muscle contraction. Clin Sci 27: 229–244
McCloskey DI, Mitchell JH (1972) Reflex cardiovascular and respiratory responses originating in exercising muscle. J Physiol (Lond) 224: 173–186
McRitchie RJ, Vatner SF, Boettcher D, Heyndrickx GR, Patrick TA, Braunwald E (1976) Role of arterial baroreceptors in mediating cardiovascular response to exercise. Am J Physiol 230: 85–89
Moissejeff E (1927) Zur Kenntnis der Karotissinusreflexes. Z Gesamte Exp Med 53: 696–704
Pannier JL, Leusen I (1973) Circulation to the brain of the rat during acute and prolonged respiratory changes in the acid-base balance. Pfluegers Arch 338: 347–359
Pannier JL, Leusen I (1977) Regional blood flow in response to exercise in conscious dogs. Eur J Appl Physiol 36: 255–265
Remensnyder JP, Mitchell JH, Sarnoff SJ (1962) Functional sympatholysis during muscular activity: observations on influence of carotid sinus on oxygen uptake. Circ Res 11: 370–380
Rowell LB (1974) Human cardiovascular adjustments to exercise and thermal stress. Physiol Rev 54: 75–159
Rudolph AM, Heymann MA (1967) The circulation of the fetus in utero. Methods for studying distribution of blood flow, cardiac output, and organ blood flow. Circ Res 21: 163–184
Sarnoff SJ, Gilmore JP, Brockman SK, Mitchell JH, Linden RJ (1960) Regulation of ventricular contraction by the carotid sinus. Circ Res 8: 1123–1136
Sarnoff SJ, Mitchell JH (1962) The control of the heart. In: Hamilton WF, Dow P (eds) Handbook of physiology, section 2: Circulation, vol I. American Physiological Society, Washington, DC, pp 489–532
Vanhoutte P, Lacroix E, Leusen I (1966) The cardiovascular adaptation of the dog to muscular exercise. Role of the arterial pressoreceptors. Arch Int Physiol Biochim 74: 201–222
Vatner SF, Pagani M (1976) Cardiovascular adjustments to exercise: hemodynamics and mechanisms. Progr Cardiovasc Dis 19: 91–108
Wagner HN, Jr, Rhodes BA, Sasaki Y, Ryan JP (1969) Studies of the circulation with radioactive microspheres. Invest Radiol 4: 374–386
Wexler I, Kao FF (1970) Neural and humoral factors affecting canine renal blood flow during induced muscular work. Am J Physiol 218: 755–761
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Clement, D.L., Pannier, J.L. Cardiac output distribution during induced static muscular contractions in the dog. Europ. J. Appl. Physiol. 45, 199–207 (1980). https://doi.org/10.1007/BF00421328
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DOI: https://doi.org/10.1007/BF00421328