OBJECTIVE: This study compares in vivo pulmonary blood flow patterns and shear stresses in patients with either the direct atrium-pulmonary artery connection or the bicaval tunnel connection of the Fontan procedure to those in normal volunteers. Comparisons were made with the use of three-dimensional phase contrast magnetic resonance imaging. METHODS: Three-dimensional velocities, flows, and pulmonary artery cross-sectional areas were measured in both pulmonary arteries of each subject. Axial, circumferential, and radial shear stresses were calculated with the use of velocities and estimates of viscosity. RESULTS: The axial velocities were not significantly different between subject groups. However, the flows and cross-sectional areas were higher in the normal group than in the two patient groups in both pulmonary arteries. The group with the bicaval connection had circular swirling in the cross section of both pulmonary arteries, causing higher shear stresses than in the controls. The disorder caused by the connection of the atrium to the pulmonary artery caused an increase in some shear stresses over the controls, but not higher than those found in the group having a bicaval tunnel. CONCLUSIONS: We found that pulmonary flow was equally reduced compared with normal flow in both patient groups. This reduction in flow can be attributed in part to the reduced size of the pulmonary arteries in both patient groups without change in axial velocity. We also found higher shear stress acting on the wall of the vessels in the patients having a bicaval tunnel, which may alter endothelial function and affect the longevity of the repair.
OBJECTIVE: This study compares in vivo pulmonary blood flow patterns and shear stresses in patients with either the direct atrium-pulmonary artery connection or the bicaval tunnel connection of the Fontan procedure to those in normal volunteers. Comparisons were made with the use of three-dimensional phase contrast magnetic resonance imaging. METHODS: Three-dimensional velocities, flows, and pulmonary artery cross-sectional areas were measured in both pulmonary arteries of each subject. Axial, circumferential, and radial shear stresses were calculated with the use of velocities and estimates of viscosity. RESULTS: The axial velocities were not significantly different between subject groups. However, the flows and cross-sectional areas were higher in the normal group than in the two patient groups in both pulmonary arteries. The group with the bicaval connection had circular swirling in the cross section of both pulmonary arteries, causing higher shear stresses than in the controls. The disorder caused by the connection of the atrium to the pulmonary artery caused an increase in some shear stresses over the controls, but not higher than those found in the group having a bicaval tunnel. CONCLUSIONS: We found that pulmonary flow was equally reduced compared with normal flow in both patient groups. This reduction in flow can be attributed in part to the reduced size of the pulmonary arteries in both patient groups without change in axial velocity. We also found higher shear stress acting on the wall of the vessels in the patients having a bicaval tunnel, which may alter endothelial function and affect the longevity of the repair.
Authors: Peter D Gatehouse; Jennifer Keegan; Lindsey A Crowe; Sharmeen Masood; Raad H Mohiaddin; Karl-Friedrich Kreitner; David N Firmin Journal: Eur Radiol Date: 2005-07-08 Impact factor: 5.315
Authors: Kartik S Sundareswaran; Christopher M Haggerty; Diane de Zélicourt; Lakshmi P Dasi; Kerem Pekkan; David H Frakes; Andrew J Powell; Kirk R Kanter; Mark A Fogel; Ajit P Yoganathan Journal: J Thorac Cardiovasc Surg Date: 2011-11-16 Impact factor: 5.209
Authors: E M Pedersen; E V Stenbøg; T Fründ; K Houlind; O Kromann; K E Sørensen; K Emmertsen; V E Hjortdal Journal: Heart Date: 2002-06 Impact factor: 5.994
Authors: G J Nollen; K E van Schijndel; J Timmermans; M Groenink; J O Barentsz; E E van der Wall; J Stoker; B J M Mulder Journal: Int J Cardiovasc Imaging Date: 2003-04 Impact factor: 2.357