Respiratory rhythm generation in mammals: synaptic and membrane properties

Abstract

Respiratory rhythm generation depends on a complex interaction between synaptic and membrane properties of functionally defined neurons. To gain a better understanding of how inhibitory and excitatory synaptic inputs lead to the generation of the respiratory rhythm we analyzed the depolarization pattern of respiratory neurons that were recorded in the transverse slice preparation of mice (P8–22) and the in vivo adult cat. Using voltage-clamp recordings from respiratory neurons and specific antagonists for inhibitory synaptic transmission we demonstrate under in vitro conditions, that inspiratory ( n=7) and post-inspiratory neurons ( n=13) received concurrent glycinergic and glutamatergic synaptic input during inspiration. A similar conclusion was gained with chloride injections into in vivo respiratory neurons. The inhibitory input was essential not only for generating the characteristic depolarization pattern of respiratory neurons, but also for switching the respiratory rhythm between inspiration and post-inspiration. The generation of the depolarization pattern depends also on intrinsic membrane properties. Negative current injections reveal that excitatory synaptic input was amplified by intrinsic bursting properties in some inspiratory neurons ( n=4) recorded in vitro. Although such properties have not been described under in vivo conditions our findings suggest that with respect to inspiratory, post-inspiratory and late-inspiratory neurons, the principle network organization is similar under both in vitro and in vivo conditions.