Abdulaziz Alsharifi, Niamh Carter, Akbar Irampaye, Charlotte Stevens, Elisa Mejia, Joerg Steier, Gerrard F Rafferty
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Protocol 2 (n = 10, four female) was 50° HDT from supine, sustained for 10 min, while breathing either medical air or normoxic hypercapnic (5% CO<sub>2</sub>) gas. Ventilation ( <math> <semantics> <msub><mover><mi>V</mi> <mo>̇</mo></mover> <mi>E</mi></msub> <annotation>${{\\dot{V}}_E}$</annotation></semantics> </math> , pneumotachograph), end-tidal O<sub>2</sub> and CO<sub>2</sub> concentration and blood pressure (Finapres) were measured continuously throughout each protocol. Middle cerebral artery blood flow velocity (MCAv; transcranial Doppler) was also measured during protocol 2. Ventilation increased significantly (P < 0.05) compared to baseline during HDT in both hyperoxic hypercapnia (protocol 1 by mean [SD] 139 [26]%) and normoxic hypercapnia (protocol 1 by mean [SD] 131 [21]% and protocol 2 by 129 [23]%), despite no change in <math> <semantics><msub><mi>P</mi> <mrow><mi>ETC</mi> <msub><mi>O</mi> <mn>2</mn></msub> </mrow> </msub> <annotation>${{P}_{{\\mathrm{ETC}}{{{\\mathrm{O}}}_2}}}$</annotation></semantics> </math> or <math> <semantics><msub><mi>P</mi> <mrow><mi>ET</mi> <msub><mi>O</mi> <mn>2</mn></msub> </mrow> </msub> <annotation>${{P}_{{\\mathrm{ET}}{{{\\mathrm{O}}}_2}}}$</annotation></semantics> </math> from baseline. No change in <math> <semantics> <msub><mover><mi>V</mi> <mo>̇</mo></mover> <mi>E</mi></msub> <annotation>${{\\dot{V}}_E}$</annotation></semantics> </math> was observed during HDT with medical air or hypoxia, and there was no significant change in MCAv during HDT compared to baseline. The absence of change in cerebral blood flow leads us to postulate that the augmented ventilatory response during steep HDT may involve mechanisms related to cerebral venous pressure and venous outflow.</p>","PeriodicalId":12092,"journal":{"name":"Experimental Physiology","volume":" ","pages":""},"PeriodicalIF":2.6000,"publicationDate":"2024-10-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Ventilatory response to head-down-tilt in healthy human subjects.\",\"authors\":\"Abdulaziz Alsharifi, Niamh Carter, Akbar Irampaye, Charlotte Stevens, Elisa Mejia, Joerg Steier, Gerrard F Rafferty\",\"doi\":\"10.1113/EP092014\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Postural fluid shifts may directly affect respiratory control via a complex interaction of baro- and chemo-reflexes, and cerebral blood flow. 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Middle cerebral artery blood flow velocity (MCAv; transcranial Doppler) was also measured during protocol 2. Ventilation increased significantly (P < 0.05) compared to baseline during HDT in both hyperoxic hypercapnia (protocol 1 by mean [SD] 139 [26]%) and normoxic hypercapnia (protocol 1 by mean [SD] 131 [21]% and protocol 2 by 129 [23]%), despite no change in <math> <semantics><msub><mi>P</mi> <mrow><mi>ETC</mi> <msub><mi>O</mi> <mn>2</mn></msub> </mrow> </msub> <annotation>${{P}_{{\\\\mathrm{ETC}}{{{\\\\mathrm{O}}}_2}}}$</annotation></semantics> </math> or <math> <semantics><msub><mi>P</mi> <mrow><mi>ET</mi> <msub><mi>O</mi> <mn>2</mn></msub> </mrow> </msub> <annotation>${{P}_{{\\\\mathrm{ET}}{{{\\\\mathrm{O}}}_2}}}$</annotation></semantics> </math> from baseline. 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引用次数: 0
摘要
体位体液变化可能会通过气压反射、化学反射和脑血流的复杂相互作用直接影响呼吸控制。有关头向下倾斜时稳态通气反应的数据很少。我们研究了 18 名健康受试者(平均 [SD] 年龄 27 [10] 岁)在急性 50° 头向下倾斜(HDT)过程中的心肺反应。方案 1(n = 8,2 名女性)是从 60° 抬头姿势开始 50° HDT,持续 10 分钟,同时暴露在常氧、常氧高碳酸血症(5% CO2)、缺氧(12% 氧气)或高氧高碳酸血症(95% 氧气,5% CO2)环境中。协议 2(n = 10,4 名女性)是从仰卧位开始 50° HDT,持续 10 分钟,同时呼吸医用空气或常氧高碳酸血症(5% CO2)气体。在每个方案的整个过程中连续测量通气量(V ̇ E ${{dot{V}}_E}$ ,气动记录仪)、潮气末氧气和二氧化碳浓度以及血压(Finapres)。在方案 2 中还测量了大脑中动脉血流速度(MCAv;经颅多普勒)。与基线相比,通气量明显增加(P P ETC O 2 ${{P}_{\mathrm{ETC}}{{{\mathrm{O}}}_2}}$ 或 P ET O 2 ${{P}_{{mathrm{ET}}{{{\mathrm{O}}}_2}}}$ )。在使用医用空气或缺氧进行 HDT 期间,未观察到 V ̇ E ${{{dot{V}}_E}$ 发生变化,而且与基线相比,HDT 期间 MCAv 没有显著变化。脑血流没有变化使我们推测,陡峭 HDT 期间增强的通气反应可能涉及与脑静脉压和静脉外流有关的机制。
Ventilatory response to head-down-tilt in healthy human subjects.
Postural fluid shifts may directly affect respiratory control via a complex interaction of baro- and chemo-reflexes, and cerebral blood flow. Few data exist concerning the steady state ventilatory responses during head-down tilt. We examined the cardiorespiratory responses during acute 50° head-down tilt (HDT) in 18 healthy subjects (mean [SD] age 27 [10] years). Protocol 1 (n = 8, two female) was 50° HDT from 60° head-up posture sustained for 10 min, while exposed to normoxia, normoxic hypercapnia (5% CO2), hypoxia (12% inspired O2) or hyperoxic hypercapnia (95% O2, 5% CO2). Protocol 2 (n = 10, four female) was 50° HDT from supine, sustained for 10 min, while breathing either medical air or normoxic hypercapnic (5% CO2) gas. Ventilation ( , pneumotachograph), end-tidal O2 and CO2 concentration and blood pressure (Finapres) were measured continuously throughout each protocol. Middle cerebral artery blood flow velocity (MCAv; transcranial Doppler) was also measured during protocol 2. Ventilation increased significantly (P < 0.05) compared to baseline during HDT in both hyperoxic hypercapnia (protocol 1 by mean [SD] 139 [26]%) and normoxic hypercapnia (protocol 1 by mean [SD] 131 [21]% and protocol 2 by 129 [23]%), despite no change in or from baseline. No change in was observed during HDT with medical air or hypoxia, and there was no significant change in MCAv during HDT compared to baseline. The absence of change in cerebral blood flow leads us to postulate that the augmented ventilatory response during steep HDT may involve mechanisms related to cerebral venous pressure and venous outflow.
期刊介绍:
Experimental Physiology publishes research papers that report novel insights into homeostatic and adaptive responses in health, as well as those that further our understanding of pathophysiological mechanisms in disease. We encourage papers that embrace the journal’s orientation of translation and integration, including studies of the adaptive responses to exercise, acute and chronic environmental stressors, growth and aging, and diseases where integrative homeostatic mechanisms play a key role in the response to and evolution of the disease process. Examples of such diseases include hypertension, heart failure, hypoxic lung disease, endocrine and neurological disorders. We are also keen to publish research that has a translational aspect or clinical application. Comparative physiology work that can be applied to aid the understanding human physiology is also encouraged.
Manuscripts that report the use of bioinformatic, genomic, molecular, proteomic and cellular techniques to provide novel insights into integrative physiological and pathophysiological mechanisms are welcomed.
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