The effect of small changes in arterial carbon dioxide tension on carotid chemoreceptor activity in the cat.

The hypothesis that the fluctuations in carotid chemoreceptor discharge represent more than a simple proportional response to respiratory oscillations of Pa, CO2 has been examined. Simultaneous recordings of the activity in few- or multi-fibre chemoreceptor preparations of the cut carotid sinus nerve and oscillations of carotid arterial pH have been made in four anaesthetized cats which were paralysed and artificially ventilated at constant frequency. Chemoreceptor activity was averaged over a minimum of twenty consecutive pH cycles and the amplitude of the fluctuations in discharge frequency determined. Using the mean Pa, CO2 obtained from blood-gas analysis and the slope of the relationship between log Pa, CO2 and pH obtained in each cat, the amplitude of the pH oscillations was converted to Pa, CO2 amplitude. This amplitude relative to the mean Pa, CO2 has been compared with the amplitude of the corresponding fluctuation in the chemoreceptor discharge frequency recorded from the carotid sinus nerve (e.s.n.d. amplitude) relative to its mean level. Whereas the Pa, CO2 amplitude was always less than 8% of the mean Pa, CO2, the c.s.n.d. amplitude ranged from 40 to 186% of the mean discharge frequency. C.s.n.d. amplitude was divided by the corresponding Pa, CO2 amplitude to give an index of the sensitivity of the chemoreceptors to Pa, CO2. This sensitivity has been compared with that determined from the mean discharge frequency produced in response to changes in mean Pa, CO2 comparable in magnitude to the Pa, CO2 amplitude. The former sensitivity was usually at least 3 times greater than the latter. Examination of the fluctuations in chemoreceptor discharge frequency in relation to the corresponding pH oscillations revealed that whereas the minimum discharge frequency coincided with the alkaline peak of the pH oscillation (trough of the Pa, CO2 oscillation), the maximum discharge frequency did not invariably coincide with the acid trough of the pH oscillation (peak of the Pa, CO2 oscillation). On 30% of occasions, the maximum discharge frequency was associated with the region of maximum rate of fall of pH (maximum rate of rise of Pa, CO2). It was concluded that fluctuations in the discharge of carotid chemoreceptors cannot be accounted for on the basis of a simple proportional relationship to Pa, CO2. They contain a large rate of change component.