The Effects of Nasal Flow Stimulation on Central Respiratory Pattern

The purpose of this study was to analyze the functional role of nasal afferents on central respiratory mechanisms. The electromyographic activity of the diaphragm and the neuronal activities of respiratory neurons within the brainstem were recorded during nasal flow stimulation, using decerebrate cats. Flow stimulation delivered to the nose prolonged the respiratory cycle time and decreased the amplitude of diaphragmatic activity. The respiratory cycle time was prolonged due to prolongation of expiratory phase. Cool air flow stimulation was more effective for changing the respiratory pattern than was warm air. All recorded inspiratory neurons of the dorsal respiratory group decreased their firing rate during stimulation, but more than half of expiratory neurons of the ventral respiratory group did not change. These results suggest that nasal afferents which respond to temperature can modulate the central respiratory pattern and have a stronger suppressive effect on the activity of inspiratory neurons than that of expiratory neurons.

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