钾、氧及二氧化碳对猫颈动脉体化学感受器稳态放电的影响。
Effects of potassium, oxygen and carbon dioxide on the steady-state discharge of cat carotid body chemoreceptors.
作者信息
Burger R E, Estavillo J A, Kumar P, Nye P C, Paterson D J
机构信息
University Laboratory of Physiology, Oxford.
出版信息
J Physiol. 1988 Jul;401:519-31. doi: 10.1113/jphysiol.1988.sp017176.
Abstract
- We have studied the effects of intravenous infusions of 0.1 mmol/min KCl (raising arterial potassium from ca. 3.2 to 6.0 mM) on the steady-state responses of carotid body chemoreceptors to end-tidal PCO2 and PO2 in the pentobarbitone-anaesthetized cat. 2. The excitatory effect of these KCl infusions was enhanced by hypoxia and reduced or abolished by hyperoxia. 3. Hypercapnia did not enhance, and usually reduced, excitation by KCl. 4. When similar control discharge frequencies were established by hypoxia or by hypercapnia, a KCl infusion excited the hypoxic discharge by about twice as much as it did the hypercapnic discharge. 5. These observations are not inconsistent with the idea that the mechanism underlying hypoxic excitation of arterial chemoreceptors is one that controls extracellular potassium concentration near the afferent nerve ending. 6. Insofar as potassium-induced excitation of chemoreceptor discharge is abruptly reduced by hyperoxia it behaves like Asmussen and Nielsen's postulated 'anaerobic work substance' and it may therefore contribute to the increased importance of the arterial chemoreflex reported in exercise.
摘要
- 我们研究了以0.1 mmol/min的速率静脉输注氯化钾(使动脉血钾从约3.2 mM升至6.0 mM)对戊巴比妥麻醉猫的颈动脉体化学感受器对呼气末二氧化碳分压和氧分压的稳态反应的影响。2. 这些氯化钾输注的兴奋作用在低氧时增强,在高氧时减弱或消除。3. 高碳酸血症并未增强氯化钾的兴奋作用,反而通常会减弱这种作用。4. 当通过低氧或高碳酸血症建立相似的对照放电频率时,氯化钾输注对低氧放电的兴奋作用约为对高碳酸血症放电兴奋作用的两倍。5. 这些观察结果与以下观点并不矛盾,即动脉化学感受器低氧兴奋的机制是一种控制传入神经末梢附近细胞外钾离子浓度的机制。6. 就高氧会突然降低钾离子诱导的化学感受器放电兴奋作用而言,它的表现类似于阿斯穆森和尼尔森所假设的“无氧代谢物质”,因此它可能导致了运动时动脉化学反射重要性的增加。
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