Respiratory and circulatory effects of saxitoxin in the cerebrospinal fluid

Abstract

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.