Division of Fetal Medicine, Department of Obstetrics and Gynaecology, Kasturba Medical College Manipal, Manipal Academy of Higher Education, Manipal, Karnataka, India.
Department of Obstetrics and Gynaecology, Kasturba Medical College Manipal, Manipal Academy of Higher Education, Manipal, Karnataka, India.
J Matern Fetal Neonatal Med. 2024 Dec;37(1):2381589. doi: 10.1080/14767058.2024.2381589. Epub 2024 Jul 25.
TVS (Transvaginal Sonography) guided Cervical strain elastography (CSE) is now available in tertiary referral centers of LMICs (Low- and Middle-Income Countries). TVS cervical length (CL) assessment is being used routinely. Still, elastography is not used in clinical settings, although enough evidence suggests good predictive value towards sPTD (spontaneous Preterm Delivery). The clinical utility of elastography has not been tested among high-risk populations of LMICs for the prediction of sPTD.
To test the performance of TVS-CSE in predicting sPTD among asymptomatic women in the mid-trimester at risk of sPTD either due to clinical factors or due to a short cervix.
Prospective observational study performed at a tertiary hospital in South India. Asymptomatic pregnant women between 16 and 24 weeks who had one or more clinical risk factors for sPTD or CL <2.5 cm were included. GE Voluson E-8 ultrasound machine was used. After CL measurement, elastography color coding was noted around the internal-os in the sagittal view. The strain ratio (SR) was calculated using the trace method on three ROIs (Region of Interest): Internal-os in sagittal view (IN), whole cervix in sagittal view (WN), and internal-os in axial view (AN). Reference Tissue (RT) of similar size and depth was chosen in the darkest blue region on elastography (stiffest area) outside the cervix, posterior/lateral to the cervix over the ligament insertion. Lower the SR - softer the cervix. Two trained fetal medicine consultants performed the initial 57 cases until intra/inter-observer correlation was satisfactory. Delivery before 37 weeks (after 26 weeks), in which the process of labor has begun spontaneously, or labor was induced after PPROM-was considered as sPTD. SRs were assessed to determine how well they could predict sPTD independently or combined with cervical length.
Out of 221 recruited,17 were lost to follow-up after 32 weeks; 204 were delivered in our hospital. Irrespective of the route of delivery, 71 (34.8%) had sPTD. Of the remaining 133, 106 delivered at term, and 27 underwent medically indicated PTD. Apart from multiple pregnancies, no other preterm-related risk factors (including CL < 2.5 cm) showed significant association with sPTD. Red CSE pattern around internal-os was associated with a significantly higher (54.5%) incidence of sPTD. CLs were similar (3.63 ± 0.67 vs. 3.63 ± 0.80, = .981) whereas SRs in all three ROIs were significantly lower among sPTD group versus no sPTD group (IN:0.65 ± 0.29 vs 0.79 ± 0.30 = .001, WN:0.34 ± 0.13 vs 0.39 ± 0.15, = .013, AN:0.37 ± 0.16 vs 0.48 ± 0.26, = .002, respectively). Using ROC curves, while CL was not predictive (AUROC 0.49, = .81), SRs showed moderate predictive value toward sPTD with the best AUC of 0.624 ( = .003) at IN. Prediction was slightly better for early sPTD <32 weeks (AUC 0.653 = 0.03). The best cutoff for SR at IN was 0.72, below which there was a moderate accuracy in predicting sPTD (sensitivity 52.11%, specificity 60.9%, PPV 41.57%, NPV 70.44%, diagnostic OR 1.69 and overall accuracy of 57.84%). A weak positive correlation is seen between IN and CL (Pearson's correlation = 0.181). Multi-variable binary logistic regression analysis suggested that SRs at IN (Adjusted OR - 0.259 CI 0.079-0.850), AN (Adjusted OR 0.182 CI 0.034-0.963), Multiple Pregnancy (Adjusted OR 3.5 CI 1.51-8.13) and previous sPTD/PPROM (Adjusted OR 2.72 CI 0.97-7.61) independently predicted sPTD.
TVS CSE performed better than CL as an independent predictive tool toward sPTD, although predictive efficacy was modest at best. Since technology is now available in high-end USG machines in tertiary care centers, we propose optimal utilization of CSE in LMICs to triage at-risk populations since low SRs are strongly associated with sPTD.
TVS(经阴道超声)引导下的宫颈应变弹性成像(CSE)现在可在中低收入国家的三级转诊中心使用。TVS 宫颈长度(CL)评估已常规进行。尽管有足够的证据表明其对 sPTD(自发性早产)有良好的预测价值,但弹性成像尚未在临床环境中使用。CSE 在中低收入国家高危人群中预测 sPTD 的临床实用性尚未得到测试。
测试 TVS-CSE 在预测有 sPTD 风险的中孕期无症状女性中的表现,这些女性因临床因素或 CL<2.5cm 而有 sPTD 风险。
在印度南部的一家三级医院进行前瞻性观察性研究。纳入了 16 至 24 周之间有一个或多个 sPTD 临床风险因素或 CL<2.5cm 的无症状孕妇。使用 GE Voluson E-8 超声机。测量 CL 后,在矢状视图中注意到内部口周围的弹性成像彩色编码。使用轨迹法在三个 ROI(感兴趣区)计算应变比(SR):矢状视图中的内部口(IN)、矢状视图中的整个宫颈(WN)和轴向视图中的内部口(AN)。在弹性成像上选择最暗蓝色区域(最硬区域)外部、宫颈后方/外侧、韧带附着处的相似大小和深度的参考组织(RT)。SR 越低 - 宫颈越软。两位训练有素的胎儿医学顾问对前 57 例进行了初始评估,直到获得满意的初始/内部观察者相关性。在 37 周后(26 周后)分娩,自发性开始分娩过程,或胎膜早破后引产,被认为是 sPTD。评估 SR 以确定其单独或与 CL 结合预测 sPTD 的能力。
在 221 名招募的患者中,有 17 名在 32 周后失访;204 名在我院分娩。无论分娩方式如何,71 名(34.8%)发生 sPTD。在其余的 133 名中,106 名足月分娩,27 名因医学原因早产。除多胎妊娠外,没有其他与早产相关的危险因素(包括 CL<2.5cm)与 sPTD 有显著关联。IN 周围的红色 CSE 模式与显著更高的 sPTD 发生率(54.5%)相关。CL 相似(3.63±0.67 vs 3.63±0.80, = .981),但 IN 中所有三个 ROI 的 SR 明显低于 sPTD 组与无 sPTD 组(0.65±0.29 vs 0.79±0.30 = .001,WN:0.34±0.13 vs 0.39±0.15, = .013,AN:0.37±0.16 vs 0.48±0.26, = .002,分别)。使用 ROC 曲线,CL 无预测价值(AUROC 0.49, = .81),而 SR 对 sPTD 具有中度预测价值,IN 的最佳 AUC 为 0.624( = .003)。早期 sPTD<32 周的预测效果稍好(AUC 0.653 = .03)。IN 处 SR 的最佳截断值为 0.72,低于该值对 sPTD 的预测具有中等准确性(灵敏度 52.11%,特异性 60.9%,PPV 41.57%,NPV 70.44%,诊断 OR 1.69,总准确率 57.84%)。IN 与 CL 之间存在弱正相关(Pearson 相关系数 = .181)。多变量二项逻辑回归分析表明,IN 的 SR(调整后的 OR - 0.259 CI 0.079-0.850)、AN(调整后的 OR 0.182 CI 0.034-0.963)、多胎妊娠(调整后的 OR 3.5 CI 1.51-8.13)和既往 sPTD/PPROM(调整后的 OR 2.72 CI 0.97-7.61)独立预测 sPTD。
TVS CSE 作为 sPTD 的独立预测工具优于 CL,尽管预测效果充其量也只是适度的。由于目前在三级护理中心的高端超声机上都配备了这项技术,我们建议在中低收入国家充分利用 CSE 对高危人群进行分类,因为低 SR 与 sPTD 密切相关。
