Compression of interventricular septum during right ventricular pressure loading

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Compression of interventricular septum during right ventricular pressure loading

Gregory S. Nelson¹, Ezzeldin Y. Sayed-Ahmed², Carol A. Gibbons Kroeker¹, Yi-Hui Sun¹, Henk E. D. J. Ter Keurs¹, Nigel G. Shrive¹, and John V. Tyberg¹

¹ Departments of Medicine, Physiology and Biophysics and Civil Engineering, University of Calgary, Calgary, Alberta T2N 4N1, Canada; and the ² Department of Civil Engineering, Ain Shams University, Cairo 11331, Egypt

The interventricular septum, which flattens and inverts in conditions such as pulmonary hypertension, is considered by manyto be an unstressed membrane, in that its position is assumedto be determined solely by the transseptal pressure gradient.A two-dimensional finite element model was developed to investigatewhether compression and bending moments (behavior incompatiblewith a membrane) exist in the septum during diastole under abnormalloading, i.e., pulmonary artery (PA) constriction. Hemodynamicand echocardiographic data were obtained in six open-chest anesthetizeddogs. For both control and PA constriction, the measured leftventricular and right ventricular pressures were applied to aresidually stressed mesh. Adjustments were made to the stiffnessand end-bending moments until the deformed and loaded residuallystressed mesh matched the observed configuration of the septum.During PA constriction, end-bending moments were required to obtainsatisfactory matches but not during control. Furthermore, substantialcircumferential compressive stresses developed during PA constriction.Such stresses might impede septal blood flow and provoke the unexplainedischemia observed in some conditions characterized by abnormalseptalmotion.

finite element analysis; interventricular septum; mechanics; compressive stress

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