瑜伽呼吸练习中不同通气模式下的气体交换研究

A. Frolov, I. Manichev, S. Ermolaeva
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Free breathing was recorded for 2 minutes, then each subject performed the respiratory hypoventilation pattern available to him or her (minimum RR values with maximum TV, inhalation and exhalation were of equal duration). The following parameters of external respiration were determined: respiratory rate (RR), minute ventilation (MV), tidal volume (TV), partial pressure of CO2 in the exhaled air at the end of exhalation (PetCO2 ), percentage of O2 in the exhaled air (FeO2) and hemoglobin saturation (SpO2 ).Results: Compared to breathing at rest (MV = M±SD 8.51 ± 2.57 (95% CI 7.72–9.29) l/min; PetCO2 = M±SD 36.98 ± 3.71 (95% CI 35.85–38.11) mm Hg), the mode with RR = 3 times/min (inspiration and expiration for 10 s), n = 44, leads to an increase in MV up to M±SD 12.02 ± 3.42 (95% CI 10.98–13.06) l/min (p < 0.001) and a decrease of CO2 : PetCO2 = M±SD 33.99 ± 3.59 (95% CI 32.90–35.08) mm Hg (p < 0.001) — that is, to development of alveolar hypocapnia. The mode with RR = 1.5 times/min (inhalation and exhalation for 20 s), n = 44, demonstrates a decrease in MV to M±SD 5.95 ± 1.59 (95% CI 5.46–6.43) l/min (p < 0.001) and growth of PetCO2 up to M±SD 41.19 ± 3.71 (95% CI 40.06–42.32) mm Hg (p < 0.001). The mode with RR = 1 time/min (inspiration and exhalation for 30 s), n = 24: with a decrease in RR to 1 time/min, a decrease in MV was observed to M±SD 4.22 ± 0.92 (95% CI 3.83–4.61) l / min (p < 0.001) and an increase in PetCO2 up to M±SD 44.05 ± 3.05 (95% CI 42.76–45.33) mm Hg (p < 0.001). The breathing pattern with RR = 1 r/min is accompanied by a statistically significant decrease in MV compared to rest, as well as an increase in PetCO2 and a decrease in FeO2 , that is, it is hypoventilation. We have proposed a ventilation coefficient (Qvent), which is the ratio MV/VC, which allows us to judge at what values of MV an individual reaches a state of hypoventilation. It was previously shown in this sample that the breathing exercise becomes hypoventilation when Qvent values are equal to or less than 1. With Qvent in the range from 1 to 2, the ventilation mode is within normal values, and when Qvent is more than 2, hyperventilation occurs.Conclusion: when performing yoga breathing exercises, variations in MV are observed both in the direction of hyperventilation and in the direction of hypoventilation with corresponding shifts in gas exchange (hypocapnia with hyperventilation, hypercapnia with hypoventilation). 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引用次数: 0

摘要

瑜珈呼吸练习可培养自愿调节微量呼吸(MV)和维持低通气、低氧和高碳酸血症状态的能力,可被视为低氧-高碳酸血症训练的一种方式,有可能对脑循环和神经保护因素产生影响。然而,目前尚未对影响低通气呼吸模式发展能力的个体人体测量特征进行研究,也未制定训练方法标准:这项研究涉及 44 人(32 名男性和 12 名女性),他们定期练习瑜伽呼吸技巧,利用最大潮气量(TV)自愿降低呼吸频率。先记录 2 分钟的自由呼吸,然后每个受试者都采用自己可用的呼吸低通气模式(最大潮气量下的最小呼吸频率值,吸气和呼气的持续时间相同)。测定的外部呼吸参数包括:呼吸频率(RR)、分钟通气量(MV)、潮气量(TV)、呼气末呼出空气中的二氧化碳分压(PetCO2)、呼出空气中的氧气百分比(FeO2)和血红蛋白饱和度(SpO2):与静态呼吸(MV = M±SD 8.51 ± 2.57 (95% CI 7.72-9.29) l/min;PetCO2 = M±SD 36.98 ± 3.71 (95% CI 35.85-38.11) mm Hg)相比,RR = 3 次/min(吸气和呼气 10 秒)的模式(n = 44)导致 MV 增加到 M±SD 12.02 ± 3.42 (95% CI 10.98-13.06) l/min (p < 0.001),CO2 : PetCO2 = M±SD 33.99 ± 3.59 (95% CI 32.90-35.08) mm Hg (p < 0.001),即肺泡低碳酸血症。RR = 1.5 次/分的模式(吸气和呼气 20 秒),n = 44,显示 MV 下降至 M±SD 5.95 ± 1.59 (95% CI 5.46-6.43) l/min (p < 0.001),PetCO2 增长至 M±SD 41.19 ± 3.71 (95% CI 40.06-42.32) mm Hg (p < 0.001)。RR = 1 次/分钟的模式(吸气和呼气 30 秒),n = 24:随着 RR 下降到 1 次/分钟,观察到 MV 下降到 M±SD 4.22 ± 0.92 (95% CI 3.83-4.61) 升/分钟(p < 0.001),PetCO2 上升到 M±SD 44.05 ± 3.05 (95% CI 42.76-45.33) mm Hg(p < 0.001)。与静息时相比,RR = 1 r/min 的呼吸模式伴随着 MV 的显著下降、PetCO2 的上升和 FeO2 的下降,即通气不足。我们提出了通气系数 (Qvent),即 MV/VC 的比值,通过它我们可以判断一个人的 MV 值达到了何种通气不足状态。结论:在进行瑜伽呼吸练习时,可以观察到 MV 的变化,既有过度通气方向的变化,也有低通气方向的变化,并伴有相应的气体交换变化(低碳酸血症伴有过度通气,高碳酸血症伴有低通气)。个人达到换气不足时的肺活量值因人而异,可通过换气系数(Qvent)进行预测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Study of gas exchange under different modes of ventilation in yoga breathing exercises
Yoga breathing exercises that develop the ability to voluntarily regulate the minute volume of respiration (MV) and maintain the state of hypoventilation, hypoxia and hypercapnia, can be considered as a way of hypoxic-hypercapnic training, potentially capable of influencing cerebral circulation and neuroprotective factors. However, at the moment, individual anthropometric features that affect the ability to develop a hypoventilation mode of breathing have not been studied, and methodological criteria for training have not been developed.Methods: The study involved 44 people (32 men and 12 women) who regularly practice yoga breathing techniques with a voluntary decrease in respiratory rate using maximum tidal volume (TV). Free breathing was recorded for 2 minutes, then each subject performed the respiratory hypoventilation pattern available to him or her (minimum RR values with maximum TV, inhalation and exhalation were of equal duration). The following parameters of external respiration were determined: respiratory rate (RR), minute ventilation (MV), tidal volume (TV), partial pressure of CO2 in the exhaled air at the end of exhalation (PetCO2 ), percentage of O2 in the exhaled air (FeO2) and hemoglobin saturation (SpO2 ).Results: Compared to breathing at rest (MV = M±SD 8.51 ± 2.57 (95% CI 7.72–9.29) l/min; PetCO2 = M±SD 36.98 ± 3.71 (95% CI 35.85–38.11) mm Hg), the mode with RR = 3 times/min (inspiration and expiration for 10 s), n = 44, leads to an increase in MV up to M±SD 12.02 ± 3.42 (95% CI 10.98–13.06) l/min (p < 0.001) and a decrease of CO2 : PetCO2 = M±SD 33.99 ± 3.59 (95% CI 32.90–35.08) mm Hg (p < 0.001) — that is, to development of alveolar hypocapnia. The mode with RR = 1.5 times/min (inhalation and exhalation for 20 s), n = 44, demonstrates a decrease in MV to M±SD 5.95 ± 1.59 (95% CI 5.46–6.43) l/min (p < 0.001) and growth of PetCO2 up to M±SD 41.19 ± 3.71 (95% CI 40.06–42.32) mm Hg (p < 0.001). The mode with RR = 1 time/min (inspiration and exhalation for 30 s), n = 24: with a decrease in RR to 1 time/min, a decrease in MV was observed to M±SD 4.22 ± 0.92 (95% CI 3.83–4.61) l / min (p < 0.001) and an increase in PetCO2 up to M±SD 44.05 ± 3.05 (95% CI 42.76–45.33) mm Hg (p < 0.001). The breathing pattern with RR = 1 r/min is accompanied by a statistically significant decrease in MV compared to rest, as well as an increase in PetCO2 and a decrease in FeO2 , that is, it is hypoventilation. We have proposed a ventilation coefficient (Qvent), which is the ratio MV/VC, which allows us to judge at what values of MV an individual reaches a state of hypoventilation. It was previously shown in this sample that the breathing exercise becomes hypoventilation when Qvent values are equal to or less than 1. With Qvent in the range from 1 to 2, the ventilation mode is within normal values, and when Qvent is more than 2, hyperventilation occurs.Conclusion: when performing yoga breathing exercises, variations in MV are observed both in the direction of hyperventilation and in the direction of hypoventilation with corresponding shifts in gas exchange (hypocapnia with hyperventilation, hypercapnia with hypoventilation). The MV values at which an individual reaches hypoventilation vary from person to person and can be predicted using the ventilation coefficient (Qvent).
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