Acute effects of the different relaxation periods during passive intermittent static stretching on arterial stiffness

To clarify whether the relaxation period during stretching affects the degree of elevated shear rate and the degree of reduction of arterial stiffness, we examined relaxation duration to build an adequate stretching protocol. In Experiment 1, the changes in cardiac output, the shear rate in the post...

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Veröffentlicht in:	PloS one 2021-11, Vol.16 (11), p.e0259444
Hauptverfasser:	Higaki, Yuya, Yamato, Yosuke, Fujie, Shumpei, Inoue, Kenichiro, Shimomura, Mio, Kato, Shosaku, Horii, Naoki, Ogoh, Shigehiko, Iemitsu, Motoyuki
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Schlagworte:	Acute effects Adult Analysis Ankle Biology and Life Sciences Blood Blood volume Blood Volume - physiology Cardiac output Cardiac Output - physiology Cardiovascular disease Compression Design of experiments Health aspects Heart rate Hemodynamics Hemoglobin Humans Leg Leg - blood supply Leg - physiology Legs Male Medicine and Health Sciences Microvasculature Muscle Stretching Exercises - physiology Muscle, Skeletal - physiology Muscles Observations Physical Sciences Physiological aspects Pulse Wave Analysis Recovery Reduction Relaxation phenomena Reperfusion Reperfusion (Physiology) Shear rate Stiffness Stretch (Physiology) Stretching Tibial Arteries - physiology Ultrasonic imaging Vascular Stiffness - physiology Veins & arteries Velocity Wave velocity Young Adult
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description	To clarify whether the relaxation period during stretching affects the degree of elevated shear rate and the degree of reduction of arterial stiffness, we examined relaxation duration to build an adequate stretching protocol. In Experiment 1, the changes in cardiac output, the shear rate in the posterior tibial artery, and blood volume in the calf muscle were measured during recovery (0-60 s) from a single bout of one-legged passive calf stretching in 12 healthy young men. In Experiment 2, the effects of different relaxation periods (5-, 10-, 20-, and 60-s) of passive one-legged intermittent calf stretching (30-s × 6 sets) on the femoral-ankle pulse wave velocity (faPWV) as an index of peripheral arterial stiffness were identified in 17 healthy young men. As a result, the stretched leg's shear rate significantly increased from 0 to 10th s after stretching. The muscle blood volume in the stretched leg significantly reduced during stretching, and then significantly increased during the recovery period after stretching; however, cardiac output remained unchanged during stretching and recovery. Additionally, the reduction in faPWV from the pre-stretching value in the stretched leg was significantly larger in the protocol with 10-s and 20-s relaxation periods than that in the non-stretched leg, but this did not differ in the 5-s and 60-s relaxation periods. These findings suggest that the relaxation periods of intermittent static stretching that cause a high transient increase in shear rate (via reperfusion after microvascular compression by the stretched calf muscles) are effective to reduce arterial stiffness.
doi_str_mv	10.1371/journal.pone.0259444
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Additionally, the reduction in faPWV from the pre-stretching value in the stretched leg was significantly larger in the protocol with 10-s and 20-s relaxation periods than that in the non-stretched leg, but this did not differ in the 5-s and 60-s relaxation periods. 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Additionally, the reduction in faPWV from the pre-stretching value in the stretched leg was significantly larger in the protocol with 10-s and 20-s relaxation periods than that in the non-stretched leg, but this did not differ in the 5-s and 60-s relaxation periods. These findings suggest that the relaxation periods of intermittent static stretching that cause a high transient increase in shear rate (via reperfusion after microvascular compression by the stretched calf muscles) are effective to reduce arterial stiffness.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>34780500</pmid><doi>10.1371/journal.pone.0259444</doi><tpages>e0259444</tpages><orcidid>https://orcid.org/0000-0003-4362-6030</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Acute effects Adult Analysis Ankle Biology and Life Sciences Blood Blood volume Blood Volume - physiology Cardiac output Cardiac Output - physiology Cardiovascular disease Compression Design of experiments Health aspects Heart rate Hemodynamics Hemoglobin Humans Leg Leg - blood supply Leg - physiology Legs Male Medicine and Health Sciences Microvasculature Muscle Stretching Exercises - physiology Muscle, Skeletal - physiology Muscles Observations Physical Sciences Physiological aspects Pulse Wave Analysis Recovery Reduction Relaxation phenomena Reperfusion Reperfusion (Physiology) Shear rate Stiffness Stretch (Physiology) Stretching Tibial Arteries - physiology Ultrasonic imaging Vascular Stiffness - physiology Veins & arteries Velocity Wave velocity Young Adult
title	Acute effects of the different relaxation periods during passive intermittent static stretching on arterial stiffness
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