Dawes G S
J Physiol. 1984 Jan;346:1-18. doi: 10.1113/jphysiol.1984.sp015003.
Breathing movements in the sheep fetus have been observed from a gestational age of about 40 days. From 95 to 115 days fetal breathing movements are almost continuous, interrupted by apnoea rarely exceeding 2 min. From 115 days until term (about 147 days) breathing and movements of the trunk and limbs are episodic. Breathing normally occurs only during rapid-eye-movement sleep as identified by low-voltage cortical electrical activity. Active movements of the neck muscles occur predominantly in high-voltage electrocortical activity. Hypercapnia or acid cerebrospinal fluid perfusion cause an increase in the regularity and depth of breathing when present, and recruit intercostal and laryngeal abductor activity. Isocapnic hypoxia, however, in contrast to the hyperventilation seen postnatally, causes arrest of fetal breathing movements. This effect is due to a central inhibition. Section of the brain stem, from the caudal hypothalamus rostrally, causes dissociation of fetal breathing movements and electrocortical activity into independent rhythms. Section of the brain stem caudally, in the upper pons or at the inferior colliculus, also causes a dissociation of electrocortical activity from breathing movements, which become almost continuous. Isocapnic hypoxia causes an increase in the rate and depth of breathing movements. It is concluded that the arrest of breathing in intact fetal lambs is not due to a direct effect on the respiratory centre in the medulla. The lumbar polysynaptic flexor reflex response becomes episodic after 115 days gestation but, in contrast to fetal breathing movements, is enhanced during high-voltage electrocortical activity. Isocapnic hypoxia arrests movements of the fetal limbs and trunk and inhibits the lumbar flexor reflex. This inhibition of the reflex is prevented by section of the spinal cord at T12, but persists after section of the brain stem in the upper pons. It is attributed to an action on the medulla, independent of the systemic arterial chemoreceptors. Small doses of pentobarbitone (5 mg/kg) cause arrest of fetal breathing movements by a suprapontine mechanism, abolished by brain stem transection, and inhibition of the lumbar flexor reflex by an action on the spinal cord, persisting after transection at T12. Inhibitors of prostaglandin synthetase (indomethacin, meclofenamate or aspirin) induce continuous fetal breathing movements, while prostaglandin E2 arrests fetal breathing. The site of action is on the medulla, as shown by section of the brain stem and of afferents from the systemic arterial chemoreceptors.(ABSTRACT TRUNCATED AT 400 WORDS)
从大约40天的胎龄开始,就已观察到绵羊胎儿的呼吸运动。在95至115天期间,胎儿呼吸运动几乎持续不断,呼吸暂停很少超过2分钟。从115天到足月(约147天),躯干和四肢的呼吸及运动是间歇性的。正常情况下,呼吸仅在以低电压皮质电活动为特征的快速眼动睡眠期间发生。颈部肌肉的主动运动主要发生在高电压皮质电活动期间。高碳酸血症或脑脊液灌注酸性物质时,若存在呼吸,则会使呼吸的规律性和深度增加,并引发肋间肌和喉外展肌活动。然而,与出生后出现的过度通气相反,等碳酸血症性低氧会导致胎儿呼吸运动停止。这种效应是由于中枢抑制。从下丘脑尾部向头端切断脑干,会使胎儿呼吸运动和皮质电活动解离为独立的节律。在脑桥上段或下丘水平从尾部切断脑干,也会使皮质电活动与呼吸运动解离,呼吸运动几乎变为持续不断。等碳酸血症性低氧会使呼吸运动的频率和深度增加。得出的结论是,完整胎儿羊羔呼吸停止并非由于对延髓呼吸中枢的直接作用。妊娠115天后,腰段多突触屈肌反射反应变为间歇性,但与胎儿呼吸运动不同的是,在高电压皮质电活动期间该反射增强。等碳酸血症性低氧会使胎儿肢体和躯干运动停止,并抑制腰段屈肌反射。在T12水平切断脊髓可防止这种反射抑制,但在脑桥上段切断脑干后该抑制仍会持续。这归因于对延髓的作用,独立于全身动脉化学感受器。小剂量戊巴比妥(5毫克/千克)通过脑桥以上机制导致胎儿呼吸运动停止,脑干横断可消除该作用,其对腰段屈肌反射的抑制是通过对脊髓的作用,在T12横断后仍会持续。前列腺素合成酶抑制剂(吲哚美辛、甲氯芬那酸或阿司匹林)可诱导胎儿持续呼吸运动,而前列腺素E2会使胎儿呼吸停止。如脑干横断及切断来自全身动脉化学感受器的传入神经所示,作用部位在延髓。(摘要截选至400字)
