A multiscale model of the electrohysterogram the BioModUE_PTL project

Author

Marque, C. ; Laforet, Jeremy ; Rabotti, C. ; Alexandersson, Asgeir ; Germain, Guy ; Gondry, Jean ; Karlsson, Bjorn ; Leskosek, Brane ; Mischi, Massimo ; Muszinski, Charles ; Oei, Guid ; Peuscher, Jan ; Rudel, Drago

Author_Institution

Univ. de Technol. de Compiegne, Compiegne, France

fYear

2013

fDate

3-7 July 2013

Firstpage

7448

Lastpage

7451

Abstract

The electrohysterogram (EHG) is a promising means of monitoring pregnancy and of detecting a risk of preterm labor. To improve our understanding of the EHG as well as its relationship with the physiologic phenomena involved in uterine contractility, we plan to model these phenomena in terms of generation and propagation of uterine electrical activity. This activity can be realistically modeled by representing the principal ionic dynamics at the cell level, the propagation of electrical activity at the tissue level and then the way it is reflected on the skin surface through the intervening tissue. We present in this paper the different steps leading to the development and validation of a biophysics based multiscale model of the EHG, going from the cell to the electrical signal measured on the abdomen.

Keywords

bioelectric phenomena; obstetrics; patient monitoring; skin; BioModUE_PTL project; abdomen; cell level ionic dynamics; electrohysterogram; multiscale model; physiologic phenomena; pregnancy monitoring; preterm labor risk detection; skin surface; uterine contractility; uterine electrical activity generation; uterine electrical activity propagation; Adaptation models; Analytical models; Biological system modeling; Calcium; Computational modeling; Conductors; Electric potential;

fLanguage

English

Publisher

ieee

Conference_Titel

Engineering in Medicine and Biology Society (EMBC), 2013 35th Annual International Conference of the IEEE

Conference_Location

Osaka

ISSN

1557-170X

Type

conf

DOI

10.1109/EMBC.2013.6611280

Filename

6611280