Role of muscle mass and mode of contraction in circulatory responses to exercise

Lewis, Steven F.; Snell, Peter G.; Taylor, W. F.; Hamra, Mary; Graham, R.; Pettinger, William A.; Blomqvist, C. Gunnar

doi:10.1152/jappl.1985.58.1.146

Cited by 105 publications

(112 citation statements)

References 16 publications

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“…The different active muscle mass between the recent and present studies must have induced the different changes in the TPR in the repetitive contraction. It has been indicated that the TPR decreases from the baseline more with the increase in active muscle mass during dynamic exercise [6,7], but it does not change from the baseline during static exercise irrespective of active muscle mass [10,25,26]. In fact, Stebbins et al [10] showed that the repetitive handgrip contraction caused no change in the TPR from the baseline, which was at a level similar to that in the sustained one in the recent study.…”

Section: Discussionmentioning

confidence: 75%

“…In these studies, however, small muscle groups were used as active muscles, which were triceps surae muscles in anesthetized cats [9] and forearm muscles in conscious humans [10]. The recruited small muscle group could be the factor resulting in similar or greater pressor response in the repetitive contraction compared to the sustained contraction because the pressor response to dynamic exercise with the recruitment of large muscles is smaller than that with the recruitment of small muscles, which is due to more reduction in total peripheral resistance (TPR) with the active muscle mass [6,7]. Thus the effect of large muscle recruitments on the different pressor responses to between static and dynamic contractions remained unknown.…”

mentioning

confidence: 99%

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Pressor Response to Static and Dynamic Knee Extensions at Equivalent Workload in Humans

Koba

Hayashi

Miura

et al. 2004

JJP

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Section: Discussionmentioning

confidence: 75%

mentioning

confidence: 99%

Pressor Response to Static and Dynamic Knee Extensions at Equivalent Workload in Humans

Koba

Hayashi

Miura

et al. 2004

JJP

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“…Previous studies attempting to compare the pressor response to dynamic and static contraction have used dynamic conditions with a lower TTI (12,21) or equated conditions on whole body oxygen uptake (3,5), which likely also results in a lower intensity in the dynamic condition due to higher muscle blood flows (35). We used the same handgrip protocol described by Stebbins et al (35), who demonstrated that peripheral diastolic, systolic and mean pressures were similar in response to static and dynamic contraction performed at 30% MVC and at the same TTI.…”

Section: Discussionmentioning

confidence: 99%

Wave reflection and central aortic pressure are increased in response to static and dynamic muscle contraction at comparable workloads

Edwards¹,

Mastin²,

Kenefick³

2008

Journal of Applied Physiology

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Edwards DG, Mastin CR, Kenefick RW. Wave reflection and central aortic pressure are increased in response to static and dynamic muscle contraction at comparable workloads. J Appl Physiol 104: 439-445, 2008. First published December 13, 2007 doi:10.1152/japplphysiol.00541.2007.-We determined the effects of static and dynamic muscle contraction at equivalent workloads on central aortic pressure and wave reflection. At random, 14 healthy men and women (23 Ϯ 5 yr of age) performed a static handgrip forearm contraction [90 s at 30% of maximal voluntary contraction (MVC)], dynamic handgrip contractions (1 contraction/s for 180 s at 30% MVC), and a control trial. During static and dynamic trials, tension-time index was controlled by holding peak tension constant. Measurements of brachial artery blood pressure and the synthesis of a central aortic pressure waveform (by radial artery applanation tonometry and generalized transfer function) were conducted at baseline, during each trial, and during 1 min of postexercise ischemia (PEI). Aortic augmentation index (AI), an index of wave reflection, was calculated from the aortic pressure waveform. AI increased during both static and dynamic trials (static, 5.2 Ϯ 3.1 to 11.8 Ϯ 3.4%; dynamic, 5.8 Ϯ 3.0 to 13.3 Ϯ 3.4%; P Ͻ 0.05) and further increased during PEI (static, 18.5 Ϯ 3.1%; dynamic, 18.6 Ϯ 2.9%; P Ͻ 0.05). Peripheral and central systolic and diastolic pressures increased (P Ͻ 0.05) during both static and dynamic trials and remained elevated during PEI. AI and pressure responses did not differ between static and dynamic trials. Peripheral and central pressures increased similarly during static and dynamic contraction; however, the rise in central systolic pressure during both conditions was augmented by increased wave reflection. The present data suggest that wave reflection is an important determinant of the central blood pressure response during forearm muscle contractions. tension-time index; exercise pressor reflex; blood pressure THE PRESSOR RESPONSE to exercise had been thought to be greater as a result of static muscle contraction compared with dynamic muscle contraction; however, initial studies were not performed on the same muscle groups or at equivalent workloads (4, 42). When static and dynamic muscle contractions are performed at equivalent workloads by controlling for the tension-time index [TTI; a measure of muscular force produced over time (2, 35)] by equating peak tension and altering duration, the pressor response has been shown to be the same during static and dynamic contractions (11,35). Further, measurement of blood pressure during postexercise ischemia (PEI) indicated no difference in metaboreceptor activation of the pressor reflex between conditions (35). Thus it appears that the pressor response to static and dynamic muscle contraction is similar when muscle mass, peak tension, and TTI are held constant. However, to date, studies of the exercise pressor reflex have not assessed central blood pressure, which may provide important information as ...

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“…It is known that the blood pressure response during exercise has relationships with exercise intensity, duration and active muscle mass. 32,33 It is also known that although ECC includes less active muscle mass than CON [34][35][36][37] its exerted muscle strength is higher than CON. 16,31 Therefore, it might be thought that the active muscle mass in CON increases more than in ECC and that the accompanying significant vasopressor response increases the load on blood vessels.…”

Section: Discussionmentioning

confidence: 99%

Effects of eccentric and concentric resistance training on arterial stiffness

2006

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It has been suggested that resistance training (RT) increases arterial stiffness. The purpose of the present study was to clarify the effect of eccentric RT (ERT) and concentric RT (CRT) on arterial stiffness in female adults by an interventional study. In total, 29 healthy female subjects were randomly assigned to either the ERT group (n ¼ 10), CRT group (n ¼ 10) or sedentary (SED) group (n ¼ 9). The ERT and CRT groups performed resistance training three times a week for 8 weeks. We determined brachial blood pressure, brachial-ankle pulse wave velocity (baPWV), carotid artery intimamedial thickness (IMT) and carotid arterial lumen diameter before and after training and after detraining.The before-training baPWV did not differ significantly among the three groups. After 8 weeks of RT, arterial stiffness in the CRT group was increased compared with the ERT and SED group (Po0.05). However, brachial blood pressure, baPWV, carotid IMT and carotid lumen diameter in the ERT and CRT groups were unchanged by RT for 8 weeks. Consequently, it was clarified that arterial stiffness was not changed by ERT for 8 weeks. This suggests that ERT may be effective as an exercise prescription for middle-aged and elderly adults.

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Role of muscle mass and mode of contraction in circulatory responses to exercise

Cited by 105 publications

References 16 publications

Pressor Response to Static and Dynamic Knee Extensions at Equivalent Workload in Humans

Pressor Response to Static and Dynamic Knee Extensions at Equivalent Workload in Humans

Wave reflection and central aortic pressure are increased in response to static and dynamic muscle contraction at comparable workloads

Effects of eccentric and concentric resistance training on arterial stiffness

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