On the uncertainty quantification of the active uterine contraction during the second stage of labor simulation

Trieu-Nhat-Thanh Nguyen; Abbass Ballit; Pauline Lecomte-Grosbras; Jean-Baptiste Colliat; Tien-Tuan Dao

doi:10.1007/s11517-024-03059-2

On the uncertainty quantification of the active uterine contraction during the second stage of labor simulation

Med Biol Eng Comput. 2024 Mar 13. doi: 10.1007/s11517-024-03059-2. Online ahead of print.

Authors

Trieu-Nhat-Thanh Nguyen¹, Abbass Ballit¹, Pauline Lecomte-Grosbras¹, Jean-Baptiste Colliat¹, Tien-Tuan Dao²

Affiliations

¹ Univ. Lille, CNRS, Centrale Lille, UMR 9013 LaMcube - Laboratoire de Mécanique, Multiphysique, Multiéchelle, 59000, Lille, France.
² Univ. Lille, CNRS, Centrale Lille, UMR 9013 LaMcube - Laboratoire de Mécanique, Multiphysique, Multiéchelle, 59000, Lille, France. tien-tuan.dao@centralelille.fr.

PMID: 38478304
DOI: 10.1007/s11517-024-03059-2

Abstract

Uterine contractions in the myometrium occur at multiple scales, spanning both organ and cellular levels. This complex biological process plays an essential role in the fetus delivery during the second stage of labor. Several finite element models of active uterine contractions have already been developed to simulate the descent of the fetus through the birth canal. However, the developed models suffer severe reliability issues due to the uncertain parameters. In this context, the present study aimed to perform the uncertainty quantification (UQ) of the active uterine contraction simulation to advance our understanding of pregnancy mechanisms with more reliable indicators. A uterus model with and without fetus was developed integrating a transversely isotropic Mooney-Rivlin material with two distinct fiber orientation architectures. Different contraction patterns with complex boundary conditions were designed and applied. A global sensitivity study was performed to select the most valuable parameters for the uncertainty quantification (UQ) process using a copula-based Monte Carlo method. As results, four critical material parameters ( $C_{1}, C_{2}, K, {Ca}_{0}$ ) of the active uterine contraction model were identified and used for the UQ process. The stress distribution on the uterus during the fetus descent, considering first and second fiber orientation families, ranged from 0.144 to 1.234 MPa and 0.044 to 1.619 MPa, respectively. The simulation outcomes revealed also the segment-specific contraction pattern of the uterus tissue. The present study quantified, for the first time, the effect of uncertain parameters of the complex constitutive model of the active uterine contraction on the fetus descent process. As perspectives, a full maternal pelvis model will be coupled with reinforcement learning to automatically identify the delivery mechanism behind the cardinal movements of the fetus during the active expulsion process.

Keywords: Active uterus contraction; Copula-based Monte Carlo method; Second stage of labor; Transversely isotropic Mooney-Rivlin material; Uncertainty quantification (UQ).