A Personalized Fluid-structure Interaction Modeling Paradigm for Aorta in Human Fetuses

Background - Congenital heart disease (CHD) is the most common birth defect and a leading cause of death and chronic illness in newborns, infants, and children. Prenatal screening and identification of CHD are critically important, but their availability and accuracy are limited by current fetal imaging techniques. To date, few models have been developed for fetal circulation. Considering the fetal aorta is frequently affected in CHDs, this study aims to develop and validate a novel model to assess the hemodynamics of the fetal aorta. Methods - Fetal echocardiography (FE) and Doppler were used to build a fluid-structure interaction (FSI) model that assesses the fetal aorta in 3 dimensions. An inverse approach was used to obtain the material property. An iterative method was also proposed to estimate the outflow boundaries. The FSI results have been validated against clinically measured dimensions and velocities over a cardiac cycle for aortas in 4 healthy fetuses. Results - The proposed FSI model has been implemented in 4 healthy fetal aortas representing a range of gestational age (GA = 23.5-36.0 weeks). The iterative method successfully estimated Windkessel parameters that match in vivo measured flow rates at outflow boundaries. The FSI model has been validated using in vivo velocity waveforms at the aortic isthmus. The resultant L2-norm was [12.5%, 16.4%], which is acceptable based on previous simulation studies. Also, the aortic stiffness of the fetal aorta decreased with GA, adding evidence to an existing controversy about the trend between aortic stiffness and GA. Conclusions - This study represents the first-of-its-kind endeavor of a rigorously validated personalized flow model for fetal circulation. The developed FSI model has been successfully validated for four subjects. The model was also used to obtain new evidence of fetal aortic development and growth.