Department of Physics, Washington University, St. Louis, MO, 63130, USA; Center for Reproductive Health Sciences, Washington University, St. Louis, MO, 63130, USA; Department of Obstetrics & Gynecology, School of Medicine, St. Louis, MO, 63110, USA.
Center for Reproductive Health Sciences, Washington University, St. Louis, MO, 63130, USA; Department of Obstetrics & Gynecology, School of Medicine, St. Louis, MO, 63110, USA; Department of Biomedical Engineering, Washington University, St. Louis, MO, 63130, USA.
Comput Biol Med. 2020 Jan;116:103543. doi: 10.1016/j.compbiomed.2019.103543. Epub 2019 Nov 18.
Clinically, uterine contractions are monitored with tocodynamometers or intrauterine pressure catheters. In the research setting, electromyography (EMG), which detects electrical activity of the uterus from a few electrodes on the abdomen, is feasible, can provide more accurate data than these other methods, and may be useful for predicting preterm birth. However, EMG lacks sufficient spatial resolution and coverage to reveal where uterine contractions originate, how they propagate, and whether preterm contractions differ between women who do and do not progress to preterm delivery. To address those limitations, electromyometrial imaging (EMMI) was recently developed and validated to non-invasively assess three-dimensional (3D) electrical activation patterns on the entire uterine surface in pregnant sheep. EMMI uses magnetic resonance imaging to obtain subject-specific body-uterus geometry and collects uterine EMG data from up to 256 electrodes on the body surface. EMMI software then solves an ill-posed inverse computation to combine the two datasets and generate maps of electrical activity on the entire 3D uterine surface. Here, we assessed the feasibility to clinically translate EMMI by evaluating EMMI's accuracy under the unavoidable geometrical alterations and electrical noise contamination in a clinical environment. We developed a hybrid experimental-simulation platform to model the effects of fetal kicks, contractions, fetal/maternal movements, and noise contamination caused by maternal respiration and environmental electrical activity. Our data indicate that EMMI can accurately image uterine electrical activity in the presence of geometrical deformations and electrical noise, suggesting that EMMI can be reliably translated to non-invasively image 3D uterine electrical activation in pregnant women.
临床上,通过胎儿宫缩描记器或宫腔内压力导管监测子宫收缩。在研究环境中,肌电图(EMG)通过腹部上的几个电极检测子宫的电活动是可行的,它可以提供比其他方法更准确的数据,并且可能有助于预测早产。然而,EMG 缺乏足够的空间分辨率和覆盖范围来揭示子宫收缩的起源、传播方式以及早产收缩是否在进展为早产的妇女和不进展为早产的妇女之间存在差异。为了解决这些限制,最近开发并验证了肌电描记成像(EMMI)技术,以非侵入性地评估在怀孕绵羊的整个子宫表面上的三维(3D)电激活模式。EMMI 使用磁共振成像来获取特定于主体的身体-子宫几何形状,并从身体表面的多达 256 个电极收集子宫 EMG 数据。然后,EMMI 软件求解不适定的逆计算,将这两个数据集结合起来,并生成整个 3D 子宫表面上的电活动图。在这里,我们通过评估 EMMI 在临床环境中不可避免的几何变形和电噪声污染下的准确性来评估将 EMMI 临床转化的可行性。我们开发了一个混合实验-模拟平台,以模拟胎儿踢腿、收缩、胎儿/母体运动以及由母体呼吸和环境电活动引起的噪声污染的影响。我们的数据表明,EMMI 可以在存在几何变形和电噪声的情况下准确地成像子宫电活动,这表明 EMMI 可以可靠地转化为非侵入性地对孕妇的 3D 子宫电激活进行成像。