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RESPIRATORY RELATED MOTOR OUTPUT TO UPPER AIRWAY MUSCLES

上呼吸道肌肉的呼吸相关运动输出

基本信息

批准号：
2901049
负责人：
SAMUEL T. KUNA
金额：
$ 16.44万
依托单位：
UNIVERSITY OF TEXAS MED BR GALVESTON
依托单位国家：
美国
项目类别：
财政年份：
1981
资助国家：
美国
起止时间：
1981-07-01 至 1999-09-09
项目状态：
已结题

项目摘要

The proposed research is based on the general hypothesis that laryngeal and pharyngeal muscles that exhibit phasic expiratory activity have an important role in the regulation of respiration in physiologic and pathophysiologic states. Previous animal and human studies from this and other laboratories indicate that laryngeal adductor muscles help actively brake exhalation regulating lung volume and the time of expiration. In contrast to the laryngeal adductors, relatively little is known about the factors controlling pharyngeal muscles with phasic expiratory activity such as the pharyngeal constrictor (PC) muscles and their role in respiration. It has been assumed that the PC muscles constrict the airway and it has been speculated that they promote upper airway closure during sleep. In contrast, we hypothesize that under conditions of pharyngeal airway narrowing, PC muscles actually dilate and stiffen the airway. Their dilating and stiffening action would lower airway closing pressure helping to maintain airway patency. Previous studies from our laboratory have determined the respiratory- related activity of laryngeal adductors in human subjects. The proposed protocols in decerebrate cats are designed to test the following hypotheses regarding the mechanisms controlling laryngeal adductor muscle activation: 1) different laryngeal adductors have similar responses to decreased lung volume, 2) phasic and tonic volume feedback regulate lung volume during expiration by reflexly modulating motor output to laryngeal adductors, and 3) the increase in laryngeal adductor activity associated with a decrease in end-expiratory lung volume is primarily mediated by unmyelinated thoracic vagal afferents. Our animal model will also be used to test the following hypotheses regarding the PC muscles: 1) the PCs exhibit respiratory-related activity and respond to a variety of respiratory stimuli, and 2) PC activation dilates and stiffens the narrowed pharyngeal airway. The former hypothesis will also be tested in normal human subjects during wakefulness and sleep. To test our hypothesis that activation of the PC muscles has a protective rather than a punitive role in the maintenance of upper airway patency during sleep, PC activity will be recorded during nighttime polysomnograms in patients with obstructive sleep apnea and high upper airway resistance syndrome. Preliminary results of the proposed protocols indicate that respiratory stimuli have different effects on the activation of laryngeal adductor and PC muscles supporting our hypothesis that the two sets of upper airway expiratory muscles have different roles in the control of respiration. Nevertheless, results for a given upper airway muscle are very similar in decerebrate cats and human subjects. This close correlation in responses will allow an exploration in animal experiments of the possible mechanisms underlying observations made in humans.

这项研究是基于一个普遍的假设，而表现出阶段性呼气活动的咽肌具有在生理和生理呼吸调节中的重要作用，病理生理状态。以前的动物和人类研究，其他实验室表明喉内收肌积极地帮助制动呼气调节肺容量和呼气时间。在与喉内收肌相比，控制咽肌时相呼气活动的因素例如咽缩肌（PC）肌肉及其在呼吸有人认为，PC肌肉收缩气道并且据推测，它们促进上呼吸道闭合，睡吧相反，我们假设在咽部条件下，气道变窄，PC肌肉实际上扩张和扩张气道。它们的扩张和硬化作用会降低气道闭合压帮助保持气道通畅。我们实验室之前的研究已经确定了呼吸系统- 在人类受试者中的喉内收肌的相关活动。拟议在去大脑猫中的方案被设计为测试以下内容关于喉内收肌控制机制的假说激活：1）不同的喉内收肌对肺容量减少，2）相位和紧张性容量反馈调节肺通过反射性调节运动输出到喉部的呼气期间的体积内收肌，和3）喉内收肌活动的增加相关随着呼气末肺容量的减少，无髓胸迷走神经传入。我们的动物模型也将被用来测试以下假设关于PC肌肉：1）PC表现出与运动相关的活动并对各种呼吸刺激作出反应; 2）PC激活使狭窄的咽部气道扩张和变硬。前这一假设也将在清醒状态下的正常人类受试者中进行检验睡觉为了验证我们的假设，即PC肌肉的激活在维护上层社会方面，睡眠期间的气道通畅性，夜间将记录PC活动阻塞性睡眠呼吸暂停患者的多导睡眠图气道阻力综合征拟议方案的初步结果表明，刺激对喉内收肌的激活有不同的影响， PC肌肉支持我们的假设，即两组上气道呼气肌在呼吸控制中具有不同的作用。然而，对于给定的上气道肌肉，对猫和人类受试者进行去大脑处理。这种反应的密切相关性将允许在动物实验中探索可能的机制，在人类身上进行的潜在观察。