Borison H L, McCarthy L E
Br J Pharmacol. 1977 Dec;61(4):679-89. doi: 10.1111/j.1476-5381.1977.tb07561.x.
1 In cats anaesthetized with pentobarbitone, saxitoxin and, on a few occasions, tetrodotoxin were injected into a lateral cerebral ventricle or into the subarachnoid space of the lower brain stem. Observations were made on frequency and tidal volume of breathing, on CO(2) responsiveness and on electrical responsiveness of the respiratory centre. Effects on the blood pressure were observed simultaneously.2 A single large dose of toxin, e.g., 250 ng, produced within minutes apneustic breathing and a rise in blood pressure which were converted rapidly to respiratory failure and hypotension. In contrast, repeated small doses, e.g., 25 ng, yielded only progressive slowing of the respiration together with circulatory hypotension. Bulbar depression was produced as effectively by subarachnoid injection as by intraventricular injection of the toxins. Onset of action was detectable within seconds.3 Slowing of the respiration occurred independently of change in tidal volume and whether or not the vagus nerves were cut. The reduction in breathing frequency is attributed to direct toxin-induced depression of the central respiratory oscillator.4 Steady-state measurements of tidal volume at controlled levels of alveolar CO(2) pressure in intermediate stages of respiratory depression showed that the toxins produced an increase in CO(2) stimulation threshold as well as a reduction in gain of CO(2) responsiveness, whether or not the vagus nerves were cut. Carotid arterial chemoreceptor reactivity to O(2) was demonstrable when central sensitivity to CO(2) was depressed. These effects are attributed to a direct influence of the toxins upon the brainstem CO(2)-tidal volume controller.5 Responsiveness of the medullary inspiratory centre to electrical stimulation persisted after the failure of spontaneous breathing was caused by the toxins. Conversely, restitution of electrical responsiveness preceded the reappearance of spontaneous respiratory activity in the recovery phase of toxic depression. Circulatory effects paralleled the changes in respiratory behaviour.6 On the basis of the relatively prompt and discrete alterations in the central respiratory and circulatory control mechanisms produced by saxitoxin and tetrodotoxin placed in the cerebrospinal fluid, it is concluded that the agents rapidly penetrated to deep target loci in the lower brain stem.
在用戊巴比妥麻醉的猫身上,将石房蛤毒素以及在少数情况下将河豚毒素注入大脑侧脑室或脑桥下部的蛛网膜下腔。观察呼吸频率和潮气量、二氧化碳反应性以及呼吸中枢的电反应性。同时观察对血压的影响。
单次大剂量毒素,例如250纳克,在数分钟内会产生长吸式呼吸和血压升高,随后迅速转变为呼吸衰竭和低血压。相比之下,重复小剂量,例如25纳克,只会导致呼吸逐渐减慢以及循环性低血压。蛛网膜下腔注射毒素与脑室内注射毒素一样能有效产生延髓抑制。数秒内即可检测到作用开始。
呼吸减慢与潮气量变化无关,且无论迷走神经是否切断均会发生。呼吸频率降低归因于毒素直接引起的中枢呼吸振荡器抑制。
在呼吸抑制中间阶段,在肺泡二氧化碳压力控制水平下对潮气量进行的稳态测量表明,无论迷走神经是否切断,毒素都会使二氧化碳刺激阈值升高以及二氧化碳反应性增益降低。当中枢对二氧化碳的敏感性降低时,颈动脉化学感受器对氧气的反应性仍可显示。这些影响归因于毒素对脑干二氧化碳 - 潮气量控制器的直接作用。
在毒素导致自主呼吸停止后,延髓吸气中枢对电刺激的反应性仍然存在。相反,在中毒性抑制的恢复阶段,电反应性的恢复先于自主呼吸活动的重新出现。循环效应与呼吸行为的变化平行。
根据置于脑脊液中的石房蛤毒素和河豚毒素对中枢呼吸和循环控制机制产生的相对迅速且离散的改变,得出结论:这些药物迅速渗透到脑桥下部的深部靶点。