Laboratory of Neuropharmacology, School of Pharmacy, Aichi Gakuin University, Nagoya, Japan.
Neuroscience. 2012 Aug 30;218:100-9. doi: 10.1016/j.neuroscience.2012.05.053. Epub 2012 May 29.
This study was carried out on decerebrate, paralyzed and artificially ventilated cats to investigate the central regulatory mechanism for cough reflex. Fictive cough was induced by repetitive stimulation of the superior laryngeal nerve (SLN) or the nucleus tractus solitarius (NTS), and characterized by an increased inspiratory discharge in the phrenic nerve (stage 1 of cough; S1C) and large burst discharge in the iliohypogastric nerve (stage 2 of cough; S2C). Membrane potential was recorded from the neurons located in the cough-inducible sites of the NTS. Seven augmenting inspiratory (aug-I), 25 inspiratory-modulated (I-mod) and 16 non-respiratory (non-R) neurons were encountered, all of which showed short-latency (7.5 ± 1.6 ms, n=48) waves of excitatory and inhibitory postsynaptic potentials (EPSPs and IPSPs) in response to single pulse stimulation of the SLN. Out of these, all 7 aug-I and 12 I-mod neurons depolarized during the S1C and hyperpolarized during the S2C (DH-type response). Three I-mod and five non-R neurons showed membrane hyperpolarization during both stages (HH-type response). Ten I-mod and three non-R neurons displayed membrane depolarization during the S1C and S2C (DD-type response). The remaining eight non-R neurons showed no response during the fictive cough (NN-type response) but a long-lasting EPSP wave to single SLN stimulation. The NTS neurons recorded here were divided into three groups. Group I neurons with the NN-type response may be the second-order relay neurons. Group II neurons with the DD-type response may integrate the tussigenic afferent information and send a gate signal to the cough pattern generator. Group III neurons with either DH-type or HH-type response may constitute the network of cough pattern generation or modulatory circuits recruited during the cough reflex. The present study suggests that Group II neurons may play a gating role in generating the cough reflex.
本研究在去大脑、麻痹和人工通气的猫上进行,旨在研究咳嗽反射的中枢调节机制。通过重复刺激上喉神经 (SLN) 或孤束核 (NTS) 来诱发虚拟咳嗽,其特征是膈神经吸气放电增加 (咳嗽第 1 期;S1C) 和髂腹股沟神经的大爆发放电 (咳嗽第 2 期;S2C)。记录位于 NTS 咳嗽诱导部位的神经元的膜电位。共遇到 7 个增强吸气 (aug-I)、25 个吸气调制 (I-mod) 和 16 个非呼吸 (non-R) 神经元,它们对 SLN 的单次脉冲刺激均表现出短潜伏期 (7.5±1.6ms,n=48) 的兴奋性和抑制性突触后电位 (EPSP 和 IPSP) 波。其中,所有 7 个 aug-I 和 12 个 I-mod 神经元在 S1C 期间去极化,在 S2C 期间超极化 (DH 型反应)。3 个 I-mod 和 5 个 non-R 神经元在两个阶段均表现出膜超极化 (HH 型反应)。10 个 I-mod 和 3 个 non-R 神经元在 S1C 和 S2C 期间表现出膜去极化 (DD 型反应)。其余 8 个 non-R 神经元在虚拟咳嗽期间无反应 (NN 型反应),但对 SLN 的单次刺激表现出持久的 EPSP 波。记录到的 NTS 神经元分为三组。具有 NN 型反应的第 I 组神经元可能是二级中继神经元。具有 DD 型反应的第 II 组神经元可能整合刺激传入信息,并向咳嗽模式发生器发送门控信号。具有 DH 型或 HH 型反应的第 III 组神经元可能构成咳嗽模式产生或调制回路的网络,这些回路在咳嗽反射期间被募集。本研究表明,第 II 组神经元可能在咳嗽反射的产生中起门控作用。
