CHANGES IN SYSTEMIC AND REGIONAL HEMODYNAMICS DURING INTENSIVE MUSCULAR ACTIVITY (EXPERIMENTAL STUDY)

IF 0.2 Q4 SPORT SCIENCES

Human Sport Medicine Pub Date : 2019-10-25 DOI:10.14529/hsm190306

M. Balykin, H. Karkobatov, Y. Shidakov, I. Antipov

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Abstract

Aim. The article deals with evaluating the changes in minute volume of blood circulation and the features of regional hemodynamics in somatic and visceral organs during intensive muscular activity. Materials and methods. Studies were conducted on outbred laboratory dogs (n = 16). At rest and at maximum physical exertion (running on a treadmill to failure), oxygen consumption (VO2), blood gas composition, the minute volume of respiration (VE) and blood circulation (Q) (according to Fick) were determined. The volumetric blood flow velocity in skeletal muscles and visceral organs (qt) was determined by introducing iodine-131-labeled microspheres into the heart cavity. Results. At maximum physical exertion, VO2 significantly increases by 11.7 times, Q – by 5.3 times. The volumetric blood flow velocity significantly (P ≤ 0.001) increases in locomotor (6.2–7.5 times) and respiratory (6.5–8.0 times) muscles. In postural muscles, blood flow does not change. In the myocardium, blood flow increases by 4.5 times and corresponds to changes in cardiac performance. In the adrenal gland, blood flow increases by 1.6 times (p ≤ 0.001), in the thyroid gland, it remains unchanged. In the kidney, blood flow decreases by 21.5%, in the liver by 23.0%, with an increase in the arterial fraction by 56.3% of organs. In organs of the splanchnic region (spleen, organs of the gastrointestinal tract), the volumetric blood flow velocity decreases by 44.9% (P ≤ 0.001). Conclusion. During extreme physical exertion, most of the cardiac output is distributed into the locomotor, respiratory muscles and organs involved in muscle activity, while reducing the volumetric blood flow in the visceral organs. It is postulated that against the background of high oxygen demand and arterial hypoxemia in the somatic and visceral organs, there are competitive relationships for blood flow and the prerequisites for the development of total tissue hypoxia.

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剧烈肌肉运动时全身和局部血流动力学的变化(实验研究)

的目标。本文讨论了在剧烈的肌肉运动中，人体和内脏器官的血液循环的微小体积的变化和区域血流动力学的特点。材料和方法。研究对象为近交实验犬(n = 16)。在休息和最大体力消耗时(在跑步机上跑步至失败)，测定耗氧量(VO2)，血气成分，呼吸分钟量(VE)和血液循环(Q)(根据菲克)。通过将碘-131标记的微球引入心脏腔内，测定骨骼肌和内脏器官的体积血流速度(qt)。结果。在最大体力消耗时，VO2显著增加11.7倍，Q -显著增加5.3倍。运动肌(6.2 ~ 7.5倍)和呼吸肌(6.5 ~ 8.0倍)的体积血流速度显著增加(P≤0.001)。在体位性肌肉中，血流不会改变。在心肌中，血流量增加了4.5倍，与心脏功能的变化相对应。肾上腺血流量增加1.6倍(p≤0.001)，甲状腺血流量保持不变。肾脏血流量减少21.5%，肝脏血流量减少23.0%，动脉部分器官血流量增加56.3%。脏器(脾、胃肠道脏器)体积血流速度降低44.9% (P≤0.001)。结论。在极度体力消耗时，大部分心输出量分布到运动肌、呼吸肌和参与肌肉活动的器官，同时减少内脏器官的血流量。假设在躯体和内脏器官高需氧量和动脉低氧血症的背景下，存在着血流竞争关系和组织全缺氧发展的先决条件。

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来源期刊

Human Sport Medicine SPORT SCIENCES-

CiteScore

0.70

自引率

50.00%

发文量