Computational fluid dynamic simulations for determination of ventricular workload in aortic arch obstructions.

OBJECTIVE The cardiac workload associated with various types of aortic obstruction was determined using computational fluid dynamic simulations. METHODS Computed tomography image data were collected from 4 patients with 4 distinct types of aortic arch obstructions and 4 controls. The categorization of arch hypoplasia corresponded to the "A, B, C" nomenclature of arch interruption; a type "D" was added to represent diffuse arch hypoplasia. Measurements of the vessel diameter were compared against the normal measurements to determine the degree of narrowing. Three-dimensional models were created for each patient, and additional models were created for type A and B hypoplasia to represent 25%, 50%, and 75% diameter narrowing. The boundary conditions for the computational simulations were chosen to achieve realistic flow and pressures in the control cases. The simulations were then repeated after changing the boundary conditions to represent a range of cardiac and vascular adaptations. The resulting cardiac workload was compared with the control cases. RESULTS Of the 4 patients investigated, 1 had aortic coarctation and 3 had aortic hypoplasia. The cardiac workload of the patients with 25% narrowing type A and B hypoplasia was not appreciably different from that of the control. When comparing the different arch obstructions, 75% type A, 50% type B, and 50% type D hypoplasia required a greater workload increase than 75% coarctation. CONCLUSIONS The present study has determined the hemodynamic significance of aortic arch obstruction using computational simulations to calculate the cardiac workload. These results suggest that all types of hypoplasia pose more of a workload challenge than coarctation with an equivalent degree of narrowing.

[1]  T. Wonnacott,et al.  Relation between diameter and flow in major branches of the arch of the aorta. , 1992, Journal of biomechanics.

[2]  T. Disessa,et al.  Significance of the Doppler-derived gradient across a residual aortic coarctation , 2005, Pediatric Cardiology.

[3]  K. Zahka Report of the Second Task Force on Blood Pressure Control in Children. , 1987, Maryland medical journal.

[4]  A. Lu,et al.  Normal aortic arch growth and comparison with isolated coarctation of the aorta. , 2003, The American journal of cardiology.

[5]  Charles A. Taylor,et al.  Computational fluid dynamic simulations of aortic coarctation comparing the effects of surgical‐ and stent‐based treatments on aortic compliance and ventricular workload , 2011, Catheterization and cardiovascular interventions : official journal of the Society for Cardiac Angiography & Interventions.

[6]  Charles A. Taylor,et al.  Outflow boundary conditions for three-dimensional finite element modeling of blood flow and pressure in arteries , 2006 .

[7]  Charles A. Taylor,et al.  On Coupling a Lumped Parameter Heart Model and a Three-Dimensional Finite Element Aorta Model , 2009, Annals of Biomedical Engineering.

[8]  M. Campbell Natural history of coarctation of the aorta , 1970, British heart journal.

[9]  M. O'Rourke,et al.  Influence of Aortic Coarctation on Pulsatile Hemodynamics in the Proximal Aorta , 1971, Circulation.

[10]  D. Stewart,et al.  Left Ventricular Function Before and Following Aortic Valve Replacement , 1977, Circulation.

[11]  M. Horan Report of the Second Task Force on Blood Pressure Control in Children--1987. Task Force on Blood Pressure Control in Children. National Heart, Lung, and Blood Institute, Bethesda, Maryland. , 1987, Pediatrics.

[12]  N. Jenkins,et al.  Coarctation of the aorta: natural history and outcome after surgical treatment. , 1999, QJM : monthly journal of the Association of Physicians.

[13]  Tal Geva,et al.  Magnetic Resonance Imaging Predictors of Coarctation Severity , 2005, Circulation.

[14]  T. Graham,et al.  Left Heart Volume and Mass Quantification in Children with Left Ventricular Pressure Overload , 1970, Circulation.

[15]  F. Migliavacca,et al.  Toward Optimal Hemodynamics: Computer Modeling of the Fontan Circuit , 2007, Pediatric Cardiology.

[16]  Robert W. Dutton,et al.  A Software Framework for Creating Patient Specific Geometric Models from Medical Imaging Data for Simulation Based Medical Planning of Vascular Surgery , 2001, MICCAI.

[17]  Megan M. Tschudy,et al.  The Harriet Lane handbook : a manual for pediatric house officers , 2012 .

[18]  Branden M. Engorn,et al.  The Harriet Lane handbook : a manual for pediatric house officers , 2015 .

[19]  Charles A. Taylor,et al.  AORTIC COARCTATION: RECENT DEVELOPMENTS IN EXPERIMENTAL AND COMPUTATIONAL METHODS TO ASSESS TREATMENTS FOR THIS SIMPLE CONDITION. , 2010, Progress in pediatric cardiology.

[20]  Charles A. Taylor,et al.  Efficient anisotropic adaptive discretization of the cardiovascular system , 2006 .

[21]  Charles A. Taylor,et al.  Evaluation of a novel Y-shaped extracardiac Fontan baffle using computational fluid dynamics. , 2009, The Journal of thoracic and cardiovascular surgery.

[22]  V. Fuster,et al.  Coarctation of the aorta. Long-term follow-up and prediction of outcome after surgical correction. , 1989, Circulation.

[23]  R. Rowe,et al.  Coarctation of the aorta with special reference to the first year of life. , 1955, Annals of surgery.

[24]  Charles A. Taylor,et al.  A coupled momentum method for modeling blood flow in three-dimensional deformable arteries , 2006 .

[25]  F. Migliavacca,et al.  Multiscale modelling in biofluidynamics: application to reconstructive paediatric cardiac surgery. , 2006, Journal of biomechanics.

[26]  A. Castañeda,et al.  Interrupted aortic arch in infancy. , 1976, The Journal of pediatrics.