Mijacika Tanja, Frestad Daria, Kyhl Kasper, Barak Otto, Drvis Ivan, Secher Niels H, Buca Ante, Obad Ante, Dujic Zeljko, Madsen Per Lav
Department of Integrative Physiology, University of Split School of Medicine, Šoltanska 2, 21000, Split, Croatia.
Department of Cardiology, Copenhagen University Hospital, Hvidovre, University of Copenhagen, Copenhagen, Denmark.
Eur J Appl Physiol. 2017 Apr;117(4):641-649. doi: 10.1007/s00421-017-3545-9. Epub 2017 Feb 27.
Trained breath-hold divers hyperinflate their lungs by glossopharyngeal insufflation (GPI) to prolong submersion time and withstand lung collapse at depths. Pulmonary hyperinflation leads to profound hemodynamic changes.
Thirteen divers performed preparatory breath-holds followed by apnea with GPI. Filling of extrathoracic veins was determined by ultrasound and magnetic resonance imaging and peripheral extravasation of fluid was assessed by electrical impedance. Femoral vein diameter was measured by ultrasound throughout the easy-going and struggle phase of apnea with GPI in eight divers in a sub-study.
After GPI, pulmonary volume increased by 0.8 ± 0.6 L above total lung capacity. The diameter of the superior caval (by 36 ± 17%) and intrathoracic part of the inferior caval vein decreased (by 21 ± 16%), while the diameters of the internal jugular (by 53 ± 34%), hepatic (by 28 ± 40%), abdominal part of the inferior caval (by 28 ± 28%), and femoral veins (by 65 ± 50%) all increased (P < 0.05). Blood volume of the internal jugular, the hepatic, the abdominal part of the inferior caval vein, and the combined common iliac and femoral veins increased by 145 ± 115, 80 ± 88, 61 ± 60, and 183 ± 197%, respectively. In the sub-study, femoral vein diameter increased by 44 ± 33% in the easy-going phase of apnea with GPI, subsequently decreasing by 20 ± 16% during the struggle phase. Electrical impedance remained unchanged over the thigh and forearm, thus excluding peripheral fluid extravasation.
GPI leads to heart and pulmonary vessel compression, resulting in redistribution of blood to extrathoracic capacitance veins proximal to venous valves. This is partially reversed by the onset of involuntary breathing movements.
经过训练的屏气潜水者通过咽鼓管吹张(GPI)使肺部过度充气,以延长潜水时间并承受深度潜水时的肺塌陷。肺部过度充气会导致深刻的血液动力学变化。
13名潜水者先进行预备屏气,然后通过GPI进行呼吸暂停。通过超声和磁共振成像确定胸外静脉的充盈情况,并通过电阻抗评估外周液体外渗情况。在一项子研究中,对8名潜水者在通过GPI进行呼吸暂停的轻松阶段和挣扎阶段全程用超声测量股静脉直径。
GPI后,肺容积比肺总量增加了0.8±0.6升。上腔静脉直径(增加36±17%)和下腔静脉胸内部分直径减小(21±16%),而颈内静脉(增加53±34%)、肝静脉(增加28±40%)、下腔静脉腹部部分(增加28±28%)和股静脉直径(增加65±50%)均增大(P<0.05)。颈内静脉、肝静脉、下腔静脉腹部部分以及髂总静脉和股静脉合并后的血容量分别增加了145±115%、80±88%、61±60%和183±197%。在子研究中,在通过GPI进行呼吸暂停的轻松阶段股静脉直径增加44±33%,随后在挣扎阶段减小20±16%。大腿和前臂的电阻抗保持不变,因此排除了外周液体外渗。
GPI导致心脏和肺血管受压,导致血液重新分布到静脉瓣膜近端的胸外容量静脉。非自主呼吸运动的开始会部分逆转这种情况。
