Department of Animal Morphology and Physiology, College of Agricultural and Veterinary Sciences, São Paulo State University (FCAV-UNESP), Jaboticabal, SP, Brazil.
J Physiol. 2018 Aug;596(15):3271-3283. doi: 10.1113/JP274726. Epub 2017 Sep 2.
Expiratory muscles (abdominal and thoracic) can be recruited when respiratory drive increases under conditions of increased respiratory demand such as hypercapnia. Studying hypercapnia-induced active expiration in unanaesthetized rats importantly contributes to the understanding of how the control system is integrated in vivo in freely moving animals. In unanaesthetized rats, hypercapnia-induced active expiration was not always recruited either in wakefulness or in sleep, suggesting that additional factors influence the recruitment of active expiration. The pattern of abdominal muscle recruitment varied in a state-dependent manner with active expiration being more predominant in the sleep state than in quiet wakefulness. Pulmonary ventilation was enhanced in periods with active expiration compared to periods without it.
Expiration is passive at rest but becomes active through recruitment of abdominal muscles under increased respiratory drive. Hypercapnia-induced active expiration has not been well explored in unanaesthetized rats. We hypothesized that (i) CO -evoked active expiration is recruited in a state-dependent manner, i.e. differently in sleep or wakefulness, and (ii) recruitment of active expiration enhances ventilation, hence having an important functional role in meeting metabolic demand. To test these hypotheses, Wistar rats (280-330 g) were implanted with electrodes for EEG and electromyography EMG of the neck, diaphragm (DIA) and abdominal (ABD) muscles. Active expiratory events were considered as rhythmic ABD activity interposed to DIA . Animals were exposed to room air followed by hypercapnia (7% CO ) with EEG, EMG and ventilation ( ) recorded throughout the experimental protocol. No active expiration was observed during room air exposure. During hypercapnia, CO -evoked active expiration was predominantly recruited during non-rapid eye movement sleep. Its increased occurrence during sleep was evidenced by the decreased DIA-to-ADB ratio (1:1 ratio means that each DIA event is followed by an ABD event, indicating a high occurrence of ABD activity). Moreover, was also enhanced (P < 0.05) in periods with active expiration. had a positive correlation (P < 0.05) with the peak amplitude of ABD activity. The data demonstrate strongly that hypercapnia-induced active expiration increases during sleep and provides an important functional role to support in conditions of increased respiratory demand.
在呼吸需求增加(例如高碳酸血症)的情况下,呼吸驱动增加时,呼气肌(腹部和胸部)可以被募集。研究未麻醉大鼠的高碳酸血症诱导的主动呼气对理解控制系统如何在自由活动动物体内进行整合具有重要意义。在未麻醉的大鼠中,高碳酸血症诱导的主动呼气在清醒或睡眠状态下并非总是被募集,这表明其他因素会影响主动呼气的募集。腹部肌肉募集的模式以状态依赖的方式变化,在睡眠状态下比在安静清醒状态下更为明显。与无主动呼气期相比,主动呼气期的肺通气增强。
在休息时呼气是被动的,但在呼吸驱动增加时通过募集腹部肌肉而变为主动。在未麻醉的大鼠中,高碳酸血症诱导的主动呼气尚未得到充分探索。我们假设(i)CO 诱发的主动呼气以状态依赖的方式募集,即在睡眠或清醒时不同,(ii)主动呼气的募集增强通气,因此在满足代谢需求方面具有重要的功能作用。为了验证这些假设,我们将 Wistar 大鼠(280-330 克)植入用于脑电图和颈部、膈肌(DIA)和腹部(ABD)肌肉肌电图的电极。主动呼气事件被认为是插入 DIA 的 ABD 节律性活动。动物在整个实验过程中暴露在空气中,然后暴露在 7% CO 下,记录脑电图、肌电图和通气( )。在空气暴露期间没有观察到主动呼气。在高碳酸血症期间,CO 诱发的主动呼气主要在非快速眼动睡眠期间募集。通过 DIA 到 ABD 的比例降低(1:1 比例表示每个 DIA 事件后面跟着一个 ABD 事件,表明 ABD 活动的发生率较高),证明了其在睡眠期间发生率的增加。此外,在主动呼气期间, 也增强(P < 0.05)。 与 ABD 活动的峰值幅度呈正相关(P < 0.05)。数据强烈表明,睡眠期间高碳酸血症诱导的主动呼气增加,并为支持呼吸需求增加时的通气提供了重要的功能作用。
