Sites of action of halothane on respiratory pattern and ventilatory response to CO2 in cats.

To assess the major sites of action of halothane on the control of breathing, the ventilatory response to CO2 was studied in 11 cats and partitioned into tidal volume and frequency response. In these cats artificial perfusion of the ponto-medullary region was applied. In essence, this technique allows one to deliver to the brainstem blood-gas tensions and anesthetic concentrations at predetermined levels which are independent from those in the systemic circulation; thus the central and peripheral effects of halothane and CO2 can be determined separately. In cats exposed both centrally and peripherally to halothane (1.0-1.6%) tachypnea was observed which disappeared when the blood perfusing the brainstem was purged of halothane. From these results is follows that the tachypnea is exclusively due to an action of halothane on structures in the brainstem. In these cats the extrapolated Paco2 at zero ventilation was significantly lower during general halothane anesthesia than during light chloralose-urethane anesthesia (P less than 0.05). In cats lightly anesthetized with chloralose-urethane, halothane (0.5-1.5%) was either administered centrally or peripherally. In these experiments the "overall" ventilatory CO2 sensitivity of both the peripheral and central chemorereflex pathways decreased significantly (P less than 0.01). However, the ratio between these two sensitivities remained the same (P less than 0.5). The extrapolated Paco2 at zero ventilation was not affected by halothane provided its concentration was below 1% (P less than 0.7). From these results we conclude that the depressant effect of halothane on ventilation originates centrally as well as peripherally. Furthermore, from the findings that the ratio of the CO2 sensitivities and the extrapolated Paco2 at zero ventilation remained constant, the authors argue that halothane acts on the processing part of the neural respiratory drive (integrating centers) rather than on the neural activity of the peripheral and central chemoreceptors per se. The peripheral effect is mainly on the neuromechanical link between integrating centers and respiratory movements.