运动期间呼吸急促的个体差异与人类通气化学敏感性的关系。

Individual differences in breathlessness during exercise, as related to ventilatory chemosensitivities in humans.

作者信息

Takano N, Inaishi S, Zhang Y

机构信息

Department of School Health, Faculty of Education, Kanazawa University, Japan.

出版信息

J Physiol. 1997 Mar 15;499 ( Pt 3)(Pt 3):843-8. doi: 10.1113/jphysiol.1997.sp021973.

DOI:10.1113/jphysiol.1997.sp021973

PMID:9130177

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1159299/

Abstract

The present study attempted to test the hypothesis that breathlessness associated with exercise hyperpnoea is greater in subjects with greater activities of the central and peripheral chemoreceptors during exercise. The chemoreceptor activities were assessed by resting estimates of hypercapnic ventilatory response (delta VE/delta PCO2, HCVR) and hypoxic ventilatory response (delta VE/-delta SO2, HVR), respectively, where VE is minute ventilation and SO2 is oxygen saturation. 2. Nine female and nine male subjects performed a 1 min incremental exercise test until exhaustion, during which breathlessness intensity (BS), assessed by a Borg category scale, and VE were measured every minute. The maximum O2 uptake (VO2,max) was also determined. 3. Using a stepwise multiple linear regression analysis, the relative contributions of not only VE, HCVR and HVR, but also VO2,max and a predicted maximum voluntary ventilation (MVVp) of the individuals to BS, were examined. 4. The analysis showed that BS = 0.1VE + 4.9HVR - 0.03MVVp + 0.55 (r2 = 0.71), indicating that VE accounted for 44% of the variance of BS, HVR for 12% and MVVp for 15%. No significant relation of HCVR and VO2,max to BS was found. 5. These results suggest a contribution of peripheral chemoreceptors to the generation of exertional breathlessness.

摘要

本研究试图验证以下假设：在运动过程中，中枢和外周化学感受器活动较强的受试者，与运动性通气过度相关的呼吸急促更为明显。分别通过静息状态下对高碳酸通气反应（ΔVE/ΔPCO2，HCVR）和低氧通气反应（ΔVE/-ΔSO2，HVR）的评估来测定化学感受器活动，其中VE为分钟通气量，SO2为氧饱和度。2. 9名女性和9名男性受试者进行了1分钟递增运动试验，直至力竭，在此期间，每分钟测量一次通过Borg分类量表评估的呼吸急促强度（BS）和VE。还测定了最大摄氧量（VO2,max）。3. 使用逐步多元线性回归分析，研究了不仅VE、HCVR和HVR，还有VO2,max以及个体的预测最大自主通气量（MVVp）对BS的相对贡献。4. 分析表明，BS = 0.1VE + 4.9HVR - 0.03MVVp + 0.55（r2 = 0.71），这表明VE占BS变异的44%，HVR占12%，MVVp占15%。未发现HCVR和VO2,max与BS有显著关系。5. 这些结果表明外周化学感受器对运动性呼吸急促的产生有作用。

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运动期间呼吸急促的个体差异与人类通气化学敏感性的关系。

Individual differences in breathlessness during exercise, as related to ventilatory chemosensitivities in humans.

作者信息

Takano N, Inaishi S, Zhang Y

机构信息

Department of School Health, Faculty of Education, Kanazawa University, Japan.

出版信息

J Physiol. 1997 Mar 15;499 ( Pt 3)(Pt 3):843-8. doi: 10.1113/jphysiol.1997.sp021973.

DOI:10.1113/jphysiol.1997.sp021973

PMID:9130177

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1159299/

Abstract

The present study attempted to test the hypothesis that breathlessness associated with exercise hyperpnoea is greater in subjects with greater activities of the central and peripheral chemoreceptors during exercise. The chemoreceptor activities were assessed by resting estimates of hypercapnic ventilatory response (delta VE/delta PCO2, HCVR) and hypoxic ventilatory response (delta VE/-delta SO2, HVR), respectively, where VE is minute ventilation and SO2 is oxygen saturation. 2. Nine female and nine male subjects performed a 1 min incremental exercise test until exhaustion, during which breathlessness intensity (BS), assessed by a Borg category scale, and VE were measured every minute. The maximum O2 uptake (VO2,max) was also determined. 3. Using a stepwise multiple linear regression analysis, the relative contributions of not only VE, HCVR and HVR, but also VO2,max and a predicted maximum voluntary ventilation (MVVp) of the individuals to BS, were examined. 4. The analysis showed that BS = 0.1VE + 4.9HVR - 0.03MVVp + 0.55 (r2 = 0.71), indicating that VE accounted for 44% of the variance of BS, HVR for 12% and MVVp for 15%. No significant relation of HCVR and VO2,max to BS was found. 5. These results suggest a contribution of peripheral chemoreceptors to the generation of exertional breathlessness.

摘要

本研究试图验证以下假设：在运动过程中，中枢和外周化学感受器活动较强的受试者，与运动性通气过度相关的呼吸急促更为明显。分别通过静息状态下对高碳酸通气反应（ΔVE/ΔPCO2，HCVR）和低氧通气反应（ΔVE/-ΔSO2，HVR）的评估来测定化学感受器活动，其中VE为分钟通气量，SO2为氧饱和度。2. 9名女性和9名男性受试者进行了1分钟递增运动试验，直至力竭，在此期间，每分钟测量一次通过Borg分类量表评估的呼吸急促强度（BS）和VE。还测定了最大摄氧量（VO2,max）。3. 使用逐步多元线性回归分析，研究了不仅VE、HCVR和HVR，还有VO2,max以及个体的预测最大自主通气量（MVVp）对BS的相对贡献。4. 分析表明，BS = 0.1VE + 4.9HVR - 0.03MVVp + 0.55（r2 = 0.71），这表明VE占BS变异的44%，HVR占12%，MVVp占15%。未发现HCVR和VO2,max与BS有显著关系。5. 这些结果表明外周化学感受器对运动性呼吸急促的产生有作用。

运动期间呼吸急促的个体差异与人类通气化学敏感性的关系。

Individual differences in breathlessness during exercise, as related to ventilatory chemosensitivities in humans.

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运动期间呼吸急促的个体差异与人类通气化学敏感性的关系。

Individual differences in breathlessness during exercise, as related to ventilatory chemosensitivities in humans.

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