Stembridge Mike, Ainslie Philip N, Donnelly Joseph, MacLeod Nicholas T, Joshi Suchita, Hughes Michael G, Sherpa Kami, Shave Rob
Cardiff School of Sport, Cardiff Metropolitan University, Cardiff, United Kingdom;
Centre for Heart, Lung and Vascular Health, School of Health and Exercise Sciences, University of British Columbia Okanagan Campus, Kelowna, British Columbia, Canada;
Am J Physiol Heart Circ Physiol. 2016 Mar 15;310(6):H740-6. doi: 10.1152/ajpheart.00938.2015. Epub 2016 Jan 22.
The purpose of this study was to examine ventricular structure and function in Sherpa adolescents to determine whether age-specific differences in oxygen saturation (SpO2 ) and pulmonary artery systolic pressure (PASP) influence cardiac adaptation to chronic hypoxia early in life. Two-dimensional, Doppler, and speckle-tracking echocardiography were performed on adolescent (9-16 yr) highland Sherpa (HLS; 3,840 m; n = 26) and compared with age-matched lowland Sherpa (LLS; 1,400 m; n = 10) and lowland Caucasian controls (LLC; sea level; n = 30). The HLS were subdivided into pre- and postadolescence; SpO2 was also recorded. Only HLS exhibited a smaller relative left ventricular (LV) end-diastolic volume; however, both HLS and LLS demonstrated a lower peak LV untwisting velocity compared with LLC (92 ± 26 and 100 ± 45 vs. 130 ± 43°/s, P < 0.05). Although SpO2 was similar between groups, PASP was higher in post- vs. preadolescent HLS (30 ± 5 vs. 25 ± 5 mmHg, P < 0.05), which negatively correlated with right ventricular strain rate (r = 0.50, P < 0.01). Much like their adult counterparts, HLS and LLS adolescents exhibit slower LV diastolic relaxation, despite residing at different altitudes. These findings suggest fundamental differences exist in the diastolic function of Sherpa that are present at an early age and may be retained after migration to lower altitudes. The higher PASP in postadolescent Sherpa is in contrast to previous reports of lowland children at high altitude and, unlike that in lowlanders, was not explained by differences in SpO2 ; thus different regulatory mechanisms seem to exist between these two distinct populations.
本研究的目的是检查夏尔巴青少年的心室结构和功能,以确定氧饱和度(SpO2)和肺动脉收缩压(PASP)的年龄特异性差异是否会影响生命早期心脏对慢性缺氧的适应。对青少年(9 - 16岁)高原夏尔巴人(HLS;海拔3840米;n = 26)进行二维、多普勒和斑点追踪超声心动图检查,并与年龄匹配的低地夏尔巴人(LLS;海拔1400米;n = 10)和低地高加索对照组(LLC;海平面;n = 30)进行比较。HLS被细分为青春期前和青春期后;同时记录SpO2。只有HLS表现出相对较小的左心室(LV)舒张末期容积;然而,与LLC相比,HLS和LLS的LV最大解旋速度均较低(分别为92±26和100±45°/秒,而LLC为130±43°/秒,P < 0.05)。尽管各组之间SpO2相似,但青春期后HLS组的PASP高于青春期前(分别为30±5和25±5 mmHg,P < 0.05),且与右心室应变率呈负相关(r = 0.50,P < 0.01)。与成年夏尔巴人相似,HLS和LLS青少年尽管居住在不同海拔高度,但LV舒张期松弛均较慢。这些发现表明,夏尔巴人心室舒张功能存在根本差异,这种差异在早年就已存在,并且在迁移到低海拔地区后可能仍然存在。青春期后夏尔巴人的PASP较高,这与之前关于高海拔低地儿童的报道相反,并且与低地人不同,其并非由SpO2差异所解释;因此,这两个不同人群之间似乎存在不同的调节机制。
