U1042, INSERM, Domaine de la Merci, F-38700, La Tronche - Grenoble, France.
Laboratoire HP2, Grenoble Alpes Université, Avenue Kimberley, F-38434, Echirolles - Grenoble, France.
Eur Heart J Cardiovasc Imaging. 2017 Dec 1;18(12):1369-1377. doi: 10.1093/ehjci/jew286.
The aim of this study was to analyse the underlying mechanisms of left and right ventricular (LV and RV) functional alterations during several days in high-altitude hypoxia.
Resting evaluations of LV and RV function and mechanics were assessed by Speckle Tracking Echocardiography on 11 subjects at sea level (SLPRE), 3 ± 2 h after helicopter transport to high altitude (D0), at day 2 (D2), day 4 (D4) and day 6 (D6) at 4350 m and 5 ± 2 h after return to sea level (SLPOST). Subjects experienced acute mountain sickness (AMS) during the first days at 4350 m. LV systolic function, RV systolic and diastolic function, LV and RV strains and LV synchrony were unchanged at high altitude. Peak twist was increased at D0, continued to increase until D6 (SLPRE: 9.0 ± 5.1deg; D6: 13.0 ± 4.0deg, P < 0.05), but was normalized at SLPOST. Early filling decreased at high altitude with a nadir at D2 (SLPRE: 78 ± 13 cm s-1; D2: 66 ± 11 cm s-1, P < 0.05). LV filling pressures index was decreased at high altitude with the minimum value obtained at D2 and remained reduced at SLPOST. Untwisting, an important factor of LV filling, was not decreased but was delayed at 4350 m.
High-altitude exposure impaired LV diastolic function with the greatest effect observed at D2, concomitantly with the occurrence of AMS. The LV early filling impairments resulted from an increased RV afterload, a decrease in LV filling pressure and a delayed LV untwist. However, the increased LV twist probably acted as a compensatory mechanism to maintain cardiac performance during high-altitude hypoxia.
本研究旨在分析高海拔低氧环境下数天内左、右心室(LV 和 RV)功能改变的潜在机制。
11 名受试者在海平面(SLPRE)、直升机转运至高海拔后 3±2 小时(D0)、第 2 天(D2)、第 4 天(D4)和第 6 天(D6)在 4350 米处,以及返回海平面后 5±2 小时(SLPOST)时,采用斑点追踪超声心动图评估 LV 和 RV 功能和力学的静息评估。在高海拔时,LV 收缩功能、RV 收缩和舒张功能、LV 和 RV 应变以及 LV 同步性没有变化。峰值扭转在 D0 时增加,并持续增加至 D6(SLPRE:9.0±5.1°;D6:13.0±4.0°,P<0.05),但在 SLPST 时恢复正常。早期充盈在高海拔时减少,在 D2 时达到最低点(SLPRE:78±13 cm/s;D2:66±11 cm/s,P<0.05)。LV 充盈压指数在高海拔时降低,在 D2 时达到最低值,并在 SLPST 时仍保持降低。LV 充盈的重要因素——解旋,在 4350 米时没有减少,而是延迟了。
高海拔暴露会损害 LV 舒张功能,在 D2 时影响最大,同时伴有 AMS 发生。LV 早期充盈受损是由于 RV 后负荷增加、LV 充盈压降低和 LV 解旋延迟所致。然而,LV 扭转的增加可能是一种代偿机制,以维持心脏在高海拔低氧环境下的性能。
