Patey O V, Botting-Lawford K J, Niu Y, Zhang L, Ma J, Ford S G, Tong W, Coutinho C M, Thilaganathan B, Giussani D A
Department of Physiology, Development and Neuroscience, University of Cambridge, Cambridge, UK.
Brompton Centre for Fetal Cardiology, Royal Brompton and Harefield Hospitals, Guy's and St Thomas' NHS Foundation Trust, London, UK.
Ultrasound Obstet Gynecol. 2025 Aug 18. doi: 10.1002/uog.29306.
Human fetal growth restriction (FGR) is associated with cardiac dysfunction. However, it remains unclear whether alterations in the fetal heart in human pregnancy affected by FGR are a consequence of chronic fetal hypoxia. In this study, we used novel in-vivo ultrasound imaging modalities in pregnant sheep to evaluate fetal cardiac responses to progressive hypoxia in late gestation.
This was a prospective study of data collected between July 2019 and March 2022 from 42 Welsh mountain ewes, each carrying a single fetus. Seventeen ewes were exposed to hypoxia in isobaric chambers (10% oxygen (O)) from 105 days of gestational age (dGA; with term being approximately 147 days) for 11 ± 1 days (H1, n = 5), 17 ± 1 days (H2, n = 6) or 32 ± 2 days (H3, n = 6). An ultrasound system with vendor-specific software was used to determine fetal left ventricular (LV) and right ventricular (RV) geometry and function. Outcomes were compared with the remaining 25 gestational age-matched ovine normoxic control pregnancies at 117 ± 1 (N1, n = 13), 124 ± 1 (N2, n = 5) and 133 ± 3 (N3, n = 7) dGA.
Compared to controls with expected fetal RV dominance in late gestation, hypoxic fetal sheep showed LV dominance with increasing duration of hypoxia, including statistically significant increases in mean ± SD LV/RV end-diastolic area ratio (N1, 1.1 ± 0.2 vs H1, 1.3 ± 0.1; N2, 1.2 ± 0.4 vs H2, 1.7 ± 0.5; N3, 0.9 ± 0.1 vs H3, 1.4 ± 0.2), LV sphericity index (N3, 0.44 ± 0.04 vs H3, 0.54 ± 0.11) and LV/RV cardiac output ratio (N1, 0.55 ± 0.18 vs H1, 1.00 ± 0.31; N2, 0.80 ± 0.10 vs H2, 1.62 ± 0.59; N3, 0.74 ± 0.23 vs H3, 1.50 ± 0.58). The mean ± SD LV myocardial performance index was significantly greater in the hypoxic groups, signifying global myocardial dysfunction (N1, 0.45 ± 0.07 vs H1, 0.64 ± 0.07; N2, 0.40 ± 0.05 vs H2, 0.66 ± 0.07; N3, 0.36 ± 0.07 vs H3, 0.60 ± 0.10). While LV apical radial strain and LV apical systolic rotation were initially increased after 17 days of hypoxia, these indices were significantly reduced after 32 days of hypoxia (median LV apical radial strain: N1, 27% (interquartile range (IQR), 26-28%) vs H1, 24% (IQR, 21-26%); N2, 24% (IQR, 22-25%) vs H2, 70% (IQR, 66-79%); N3, 51% (IQR, 48-54%) vs H3, 29% (IQR, 27-32%); mean ± SD LV apical systolic rotation: N1, 7 ± 5° vs H1, 5 ± 3°; N2, 9 ± 1° vs H2, 14 ± 2°; N3, 15 ± 2° vs H3, 7 ± 2°). Hypoxic fetuses showed biventricular hypertrophy and evidence of biventricular diastolic dysfunction, with significant LV impairment presenting after 11 days of hypoxia (mean ± SD LV isovolumetric relaxation time (IVRT') normalized by cardiac cycle (cc) length: N1, 0.10 ± 0.02 ms vs H1, 0.15 ± 0.02 ms; N2, 0.09 ± 0.01 ms vs H2, 0.14 ± 0.02 ms; N3, 0.08 ± 0.03 ms vs H3, 0.12 ± 0.02 ms), preceding RV impairment after 32 days of chronic hypoxia (mean ± SD RV-IVRT' normalized by cc length: N3, 0.08 ± 0.03 ms vs H3, 0.14 ± 0.03 ms).
Progressive fetal hypoxia in sheep leads to profound changes in fetal cardiac structure and function, resulting from a switch to LV dominance triggered by fetal brain sparing. The findings also indicate that fetal cardiac compensatory reserves become exhausted with progressive hypoxia. © 2025 The Author(s). Ultrasound in Obstetrics & Gynecology published by John Wiley & Sons Ltd on behalf of International Society of Ultrasound in Obstetrics and Gynecology.
胎儿生长受限(FGR)与心脏功能障碍有关。然而,受FGR影响的人类妊娠中胎儿心脏的改变是否是慢性胎儿缺氧的结果仍不清楚。在本研究中,我们使用新型的体内超声成像方式对妊娠绵羊进行评估,以观察妊娠晚期胎儿心脏对渐进性缺氧的反应。
这是一项前瞻性研究,收集了2019年7月至2022年3月期间42只威尔士山地母羊的数据,每只母羊怀有单胎。17只母羊在等压舱中从妊娠105天(dGA;足月约为147天)开始暴露于低氧环境(10%氧气(O)),持续11±1天(H1组,n = 5)、17±1天(H2组,n = 6)或32±2天(H3组,n = 6)。使用配备特定供应商软件的超声系统测定胎儿左心室(LV)和右心室(RV)的几何形态及功能。将结果与其余25例妊娠年龄匹配的正常氧合绵羊对照妊娠进行比较,对照妊娠分别在117±1(N1组,n = 13)、124±1(N2组,n = 5)和133±3(N3组,n = 7)dGA。
与妊娠晚期预期胎儿右心室占优势的对照组相比,缺氧的胎儿绵羊随着缺氧时间延长出现左心室占优势,包括平均±标准差左心室/右心室舒张末期面积比(N1组,1.1±0.2 vs H1组,1.3±0.1;N2组,1.2±0.4 vs H2组,1.7±0.5;N3组,0.9±0.1 vs H3组,1.4±0.2)、左心室球形指数(N3组,0.44±0.04 vs H3组,0.54±0.11)和左心室/右心室心输出量比(N1组,0.55±0.18 vs H1组,1.00±0. — 31;N2组,0.80±0.10 vs H2组,1.62±0.59;N3组,0.74±0.23 vs H3组,1.50±0.58)有统计学意义的增加。缺氧组左心室心肌性能指数的平均值±标准差显著更高,表明整体心肌功能障碍(N1组,0.45±0.07 vs H1组,0.64±0.07;N2组,0.40±0.05 vs H2组,0.66±0.07;N3组,0.36±0.07 vs H3组,0.60±0.10)。虽然缺氧17天后左心室心尖径向应变和左心室心尖收缩期旋转最初增加,但缺氧3 — 2天后这些指标显著降低(左心室心尖径向应变中位数:N1组,27%(四分位间距(IQR),26 - 28%)vs H1组,24%(IQR,21 - 26%);N2组,24%(IQR,22 - 25%)vs H2组,70%(IQR,66 - 79%);N3组,51%(IQR,48 - 54%)vs H3组,29%(IQR,27 - — 32%);左心室心尖收缩期旋转平均值±标准差:N1组,7±5°vs H1组,5±3°;N2组,9±1°vs H2组,14±2°;N3组 — )。缺氧胎儿表现为双心室肥厚和双心室舒张功能障碍的证据,缺氧11天后出现明显的左心室损害(左心室等容舒张时间(IVRT')经心动周期(cc)长度标准化后的平均值±标准差:N1组,0.10±0.02 ms vs H1组,0.15±0.02 ms;N2组,0.09±0.01 ms vs H2组,0.14±0.02 ms;N3组,0.08±0.03 ms vs H3组,0.12±0.02 ms),慢性缺氧32天后右心室损害出现之前(右心室IVRT'经cc长度标准化后的平均值±标准差:N3组,0.08±0. + 03 ms vs H3组,0.14±0.03 ms)。
绵羊胎儿渐进性缺氧导致胎儿心脏结构和功能发生深刻变化,这是由胎儿脑保护触发的向左心室占优势转变所致。研究结果还表明,随着渐进性缺氧,胎儿心脏的代偿储备会耗尽。© 2025作者。《超声医学与妇产科》由约翰·威利父子有限公司代表国际妇产科超声学会出版。
