人体正弦式工作负荷变化期间动脉血钾与通气动力学的比较。

Comparison of arterial potassium and ventilatory dynamics during sinusoidal work rate variation in man.

作者信息

Casaburi R, Stringer W W, Singer E

机构信息

Division of Respiratory and Critical Care, Physiology and Medicine, Harbor-UCLA Medical Center, Torrance 90509, USA.

出版信息

J Physiol. 1995 Jun 1;485 ( Pt 2)(Pt 2):571-80. doi: 10.1113/jphysiol.1995.sp020753.

DOI:10.1113/jphysiol.1995.sp020753

PMID:7666376

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1158016/

Abstract

The mechanisms underlying the exercise hyperpnoea have been difficult to define. Recently it has been suggested that exercise ventilation (VE) changes in proportion to changes in arterial potassium concentration ([K+]a). Similar VE and [K+]a time courses following work rate changes have been cited as supporting evidence. This study compared [K+]a and VE dynamics during moderate exercise in man. 2. We observed VE and gas exchange responses in five healthy men to sinusoidal work rate variation between 25 and approximately 105 W. Tests of approximately 30 min duration were performed at sinusoidal periods of 9, 6 and 3 min and in the steady state. In each test, during two or three sine periods, arterial blood was sampled (24 per test) and analysed for [K+] and blood gases. Response amplitude and phase (relative to work rate) were determined for each variable. 3. [K+]a fluctuated in response to sinusoidal work rate forcing with mean-to-peak amplitude averaging 0.15 mmol 1(-1). However, among tests, VE amplitude and phase were not highly correlated with [K+]a (r = 0.36 and 0.67, respectively). Further, average [K+]a amplitude in the 9 and 6 min sinusoidal studies tended to exceed the steady-state amplitude, while average VE amplitude fell progressively with increasing forcing frequency. The dissimilar dynamics of [K+]a and VE seem inconsistent with a major role for [K+]a as a proportional controller of ventilation during non-steady state moderate exercise in man. 4. Among tests, VE and CO2 output (VCO2) amplitude and phase were closely correlated (r = 0.87 and 0.94, respectively). Further, arterial CO2 pressure (Pa,CO2) and arterial pH(pHa) did not fluctuate significantly in ten of twenty and thirteen of twenty studies, respectively. In tests where sinusoidal fluctuation was detected, amplitude averaged 1.1 mmHg and 0.008 units, respectively. Thus VE demonstrated a close dynamic coupling to CO2 output, with consequent tight regulation of Pa,CO2 and pHa.

摘要

运动性呼吸急促的潜在机制一直难以明确。最近有人提出，运动通气量（VE）与动脉血钾浓度（[K⁺]a）的变化成比例。工作强度变化后相似的VE和[K⁺]a时间进程被引为支持证据。本研究比较了人体中度运动期间的[K⁺]a和VE动态变化。2. 我们观察了5名健康男性对25至约105瓦正弦工作强度变化的VE和气体交换反应。在9分钟、6分钟和3分钟的正弦周期以及稳定状态下进行了约30分钟的测试。在每次测试中，在两到三个正弦周期内采集动脉血（每次测试24份）并分析[K⁺]和血气。确定每个变量的反应幅度和相位（相对于工作强度）。3. [K⁺]a随正弦工作强度的强迫作用而波动，平均峰间幅度为0.15 mmol·L⁻¹。然而，在各测试中，VE幅度和相位与[K⁺]a的相关性不高（分别为r = 0.36和0.67）。此外，9分钟和6分钟正弦研究中的平均[K⁺]a幅度往往超过稳态幅度，而平均VE幅度随强迫频率增加而逐渐下降。在人体非稳态中度运动期间，[K⁺]a和VE不同的动态变化似乎与[K⁺]a作为通气比例控制器的主要作用不一致。4. 在各测试中，VE和二氧化碳排出量（VCO₂）的幅度和相位密切相关（分别为r = 0.87和0.94）。此外，在20项研究中的10项和20项研究中的13项中，动脉血二氧化碳分压（Pa,CO₂）和动脉血pH值（pHa）分别没有明显波动。在检测到正弦波动的测试中，幅度平均分别为1.1 mmHg和0.008个单位。因此，VE显示出与二氧化碳排出量密切的动态耦合，从而对Pa,CO₂和pHa进行严格调节。