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Hauptverfasser: Dine, Kamil Bader El, Nader, Noujoud, Khalil, Mohamad, Marque, Catherine
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2501.10544
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author Dine, Kamil Bader El
Nader, Noujoud
Khalil, Mohamad
Marque, Catherine
author_facet Dine, Kamil Bader El
Nader, Noujoud
Khalil, Mohamad
Marque, Catherine
contents Premature delivery is a leading cause of fetal death and morbidity, making the prediction and treatment of preterm contractions critical. The electrohysterographic (EHG) signal measures the electrical activity controlling uterine contraction. Analyzing EHG features can provide valuable insights for labor detection. In this paper, we propose a framework using simulated EHG signals to identify features sensitive to uterine connectivity. We focus on EHG signal propagation during delivery, recorded by multiple electrodes. Simulated EHG signals were generated using electrical diffusion (ED) and mechanotransduction (EDM) to identify which connectivity methods and graph parameters best represent uterine synchronization. The signals were simulated in two scenarios: using only ED by modifying tissue resistance, and using both ED and EDM by varying mechanotransduction model parameters. A matrix of 16 surface electrodes was used for the simulations. Our results show that a simplified electromechanical model can monitor uterine synchronization. Feature selection using Fscore on real and simulated EHG signals highlighted that the best features for detecting mechanotransduction shifts were H2 alone or combined with Str, R2(PR), and ICOH(Str). The best features for detecting electrical diffusion shifts were H2, Eff, PR, and BC.
format Preprint
id arxiv_https___arxiv_org_abs_2501_10544
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Electrical and Mechanical Modeling of Uterine Contractions Analysis Using Connectivity Methods and Graph Theory
Dine, Kamil Bader El
Nader, Noujoud
Khalil, Mohamad
Marque, Catherine
Medical Physics
Premature delivery is a leading cause of fetal death and morbidity, making the prediction and treatment of preterm contractions critical. The electrohysterographic (EHG) signal measures the electrical activity controlling uterine contraction. Analyzing EHG features can provide valuable insights for labor detection. In this paper, we propose a framework using simulated EHG signals to identify features sensitive to uterine connectivity. We focus on EHG signal propagation during delivery, recorded by multiple electrodes. Simulated EHG signals were generated using electrical diffusion (ED) and mechanotransduction (EDM) to identify which connectivity methods and graph parameters best represent uterine synchronization. The signals were simulated in two scenarios: using only ED by modifying tissue resistance, and using both ED and EDM by varying mechanotransduction model parameters. A matrix of 16 surface electrodes was used for the simulations. Our results show that a simplified electromechanical model can monitor uterine synchronization. Feature selection using Fscore on real and simulated EHG signals highlighted that the best features for detecting mechanotransduction shifts were H2 alone or combined with Str, R2(PR), and ICOH(Str). The best features for detecting electrical diffusion shifts were H2, Eff, PR, and BC.
title Electrical and Mechanical Modeling of Uterine Contractions Analysis Using Connectivity Methods and Graph Theory
topic Medical Physics
url https://arxiv.org/abs/2501.10544