Hypothalamic modulation of laryngeal reflexes in the anaesthetized cat: role of the nucleus tractus solitarii.

1. This investigation was initiated because activation of laryngeal afferents, either by electrical stimulation of the superior laryngeal nerve (SLN) or by natural stimulation of receptors in the laryngeal mucosa, results in a cardiorespiratory response comprising bradycardia, hypotension and apnoea (phrenic nerve activity was suppressed). This pattern of response is qualitatively equivalent to the response that is evoked on activation of the arterial baroreceptors. 2. Preliminary studies indicated that the effects of activating the SLN were suppressed during stimulation in the hypothalamic defence area (HDA) at points that also blocked the effects of baroreceptor stimulation. 3. Recordings were taken from seventy-two neurones localized within the ipsilateral nucleus tractus solitarii (NTS) whose activity was modified by SLN stimulation. Sixty neurones responded with an EPSP on SLN stimulation; nine of these had an inspiratory firing pattern. Five neurones were seen to receive an IPSP on SLN stimulation. 4. Five respiratory SLN-activated neurones were unresponsive to stimulation of the other nerve inputs, whilst four received convergent EPSP inputs on sinus nerve (SN) stimulation. One cell of these four also received inputs from the aortic and the vagus nerves. Sixty-one non-respiratory SLN-activated neurones also received convergent inputs from the sinus nerve. Of these, fifty displayed an EPSP, four an IPSP and seven an EPSP-IPSP. Fifteen neurones also received inputs from the aortic nerve and seventeen from the vagus. 5. From the population of neurones affected by SLN stimulation, twenty-four of seventy were also influenced by HDA stimulation (3 were respiratory cells). Sixteen of these responses consisted of an EPSP (2 respiratory cells), five of an IPSP (1 respiratory cell) and three of an EPSP-IPSP. 6. In neurones receiving an IPSP on HDA stimulation, the SLN-evoked excitatory response was reduced throughout the period of HDA-evoked inhibition. These neurones were all shown to receive excitatory inputs from the arterial baroreceptors and laryngeal mechanoreceptors. 7. Additionally, in the thirty-seven neurones that were excited by SLN stimulation but received no direct synaptic input on HDA stimulation, a conditioning stimulus to the HDA evoked a block of SLN-evoked responses without an accompanying change in membrane potential. Several of these neurones were also affected by both baroreceptor and laryngeal mechanoreceptor stimulation. 8. These observations are discussed in the context of the role of the NTS in cardiorespiratory control. The potential importance of these interactions in respiratory distress are highlighted and the implications for the organization of central pathways for the control of autonomic and respiratory function are discussed.