正常人体呼吸与压力感受性反射反应之间的相位关系。
Phase relationship between normal human respiration and baroreflex responsiveness.
作者信息
Eckberg D L, Kifle Y T, Roberts V L
出版信息
J Physiol. 1980 Jul;304:489-502. doi: 10.1113/jphysiol.1980.sp013338.
Abstract
- We studied the influences of phase of respiration and breathing frequency upon human sinus node responses to arterial baroreceptor stimulation. 2. Carotid baroreceptors were stimulated with brief (0.6 sec), moderate (30 mmHg) neck suction during early, mid, and late inspiration or expiratin at usual breathing rates, or, during early inspiration and expiration at breathing rates of 3, 6, 12, and 24 breaths/min. 3. Baroreceptor stimuli applied during early and mid inspiration and late expiration provoked only minor sinus node inhibition; stimuli begun during late inspiration and early expiration provoked maximum sinus node inhibition. 4. At breathing rates of 3, 6 and 12 breaths/min, expiratory baroreflex responses were significantly greater than inspiratory responses; at 24 breaths/min, however, inspiratory and expiratory baroreceptor stimuli produced comparable degrees of sinus node inhibition. 5. Our results delineate an important central biological rhythm in normal man: human baroreflex responsiveness oscillates continuously during normal, quiet respiration. The phase shift of baroreflex responsiveness on respiration suggests that this interaction cannot be ascribed simply to gating synchronous with central inspiratory neurone activity. Regularization of heart rate during rapid breathing is associated with loss of the differential inspiratory-expiratory baroreflex responsiveness which is present at usual breathing rates.
摘要
- 我们研究了呼吸相位和呼吸频率对人体窦房结对动脉压力感受器刺激反应的影响。2. 在正常呼吸频率下的吸气早期、中期和晚期或呼气早期、中期和晚期,或者在呼吸频率为3、6、12和24次/分钟的吸气早期和呼气早期,通过短暂(0.6秒)、适度(30 mmHg)的颈部吸引刺激颈动脉压力感受器。3. 在吸气早期和中期以及呼气晚期施加的压力感受器刺激仅引起轻微的窦房结抑制;在吸气晚期和呼气早期开始的刺激引起最大程度的窦房结抑制。4. 在呼吸频率为3、6和12次/分钟时,呼气压力反射反应明显大于吸气反应;然而,在24次/分钟时,吸气和呼气压力感受器刺激产生的窦房结抑制程度相当。5. 我们的结果描绘了正常人体内一种重要的中枢生物节律:在正常安静呼吸过程中,人体压力反射反应性持续振荡。压力反射反应性在呼吸上的相位变化表明,这种相互作用不能简单地归因于与中枢吸气神经元活动同步的门控。快速呼吸期间心率的规整与通常呼吸频率下存在的吸气 - 呼气压力反射反应性差异的丧失有关。
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