Universitätsklinikum des Saarlandes, Klinik für Innere Medizin III, Homburg/Saar, Germany.
Heart Rhythm. 2011 Sep;8(9):1436-43. doi: 10.1016/j.hrthm.2011.03.053. Epub 2011 Mar 30.
Obstructive sleep apnea (OSA) causes negative tracheal pressure (NTP) and is associated with atrial fibrillation (AF).
This study aimed to determine the mechanism of atrial electrophysiological changes during tracheal occlusion with or without applied NTP and to evaluate the role of vagal activation, Na(+)/H(+)exchanger (NHE), and ATP-dependent potassium channels (K(ATP)).
Seventeen closed-chest pigs were anesthetized with urethane, and an endotracheal tube was placed to apply NTP (up to -100 mbar), comparable to clinically observed OSA in patients by a negative pressure device for a time period of 2 minutes. Right atrial refractory periods (AERP) and AF inducibility were measured transvenously by a monophasic action potential recording and stimulation catheter.
All tracheal occlusions with and without applied NTP resulted in comparable increases in blood pressure and hypoxemia. NTP shortened AERP (157.0 ± 2.8 to 102.1 ± 6.2 ms; P <.0001) and enhanced AF inducibility during AERP measurements from 0% at baseline to 90% (P <.00001) during NTP. Release of NTP resulted in a prompt restoration of sinus rhythm, and AERP returned to normal. NTP-induced AERP shortening and AF inducibility were prevented by atropine or vagotomy. Neither the NHE blocker cariporide nor the K(ATP) channel blocker glibenclamide abolished NTP-induced AERP shortening. By contrast, tracheal occlusion without applied NTP caused comparable changes in blood gases but did not induce AERP shortening or AF inducibility.
NTP during obstructive events is a strong trigger for AF compared with changes in blood gases alone. NTP caused AERP shortening and increased susceptibility to AF mainly by enhanced vagal activation. AERP shortening was not prevented by K(ATP) channel blockade or NHE blockade.
阻塞性睡眠呼吸暂停(OSA)会导致气道负压(NTP),并与心房颤动(AF)有关。
本研究旨在确定在气管阻塞时伴有或不伴有应用 NTP 的情况下心房电生理变化的机制,并评估迷走神经激活、Na(+)/H(+)交换器(NHE)和 ATP 依赖性钾通道(K(ATP))的作用。
17 只闭胸猪用尿烷麻醉,并放置气管内导管以施加 NTP(最高可达-100 mbar),通过负压装置施加 2 分钟,模拟临床观察到的 OSA 患者中的 NTP。通过单相动作电位记录和刺激导管经静脉测量右房不应期(AERP)和 AF 易感性。
所有伴有和不伴有应用 NTP 的气管阻塞均导致血压和低氧血症的相似增加。NTP 缩短 AERP(157.0 ± 2.8 至 102.1 ± 6.2 ms;P <.0001),并在 NTP 期间增强 AERP 测量期间的 AF 易感性,从基线的 0%增加到 90%(P <.00001)。释放 NTP 可迅速恢复窦性节律,AERP 恢复正常。NTP 诱导的 AERP 缩短和 AF 易感性被阿托品或迷走神经切断术所预防。NHE 阻滞剂 cariporide 或 K(ATP) 通道阻滞剂 glibenclamide 均不能消除 NTP 诱导的 AERP 缩短。相比之下,不伴有应用 NTP 的气管阻塞会引起相似的血气变化,但不会引起 AERP 缩短或 AF 易感性。
与单独的血气变化相比,阻塞性事件期间的 NTP 是 AF 的强烈触发因素。NTP 通过增强迷走神经激活导致 AERP 缩短和 AF 易感性增加。K(ATP) 通道阻断或 NHE 阻断并不能预防 AERP 缩短。
