Computational Fluid Dynamic Assessment of Patients with Congenital Heart Disease from 3D Rotational Angiography
- PMID: 38489092
- DOI: 10.1007/s00246-024-03443-7
Computational Fluid Dynamic Assessment of Patients with Congenital Heart Disease from 3D Rotational Angiography
Abstract
For congenital heart disease patients, multiple imaging modalities are needed to discern anatomy and functional information such as differential blood flow. During cardiac catheterization, 3D rotational angiography (3DRA) can provide CTA-like images, enabling anatomical information and intraprocedural guidance. We seek to establish whether unique aspects of this technique can also generate quantitative functional blood flow information. We propose that systematic integration of 3DRA imaging, catheter hemodynamic information, and computational fluid dynamics (CFD), can provide quantitative information regarding blood flow dynamics and energetics, without additional imaging or procedures. We report a single center retrospective feasibility study comprising four patients with 3DRA imaging and a complete set of hemodynamic data. 3DRA was processed and segmented to reconstruct vascular regions of interest (ROI), and a computational grid for CFD modeling of blood flow through the ROI was generated. Blood flow was simulated by integrating catheter hemodynamic data to devise boundary conditions at vascular ROI inlets and outlets. The 3DRA-based workflow successfully generated key computational outputs commonly used for cardiovascular applications, including flow patterns, distribution fractions, wall shear stress. Computational outputs obtained were as detailed and resolved as those obtained from more commonly used CT or MR angiography. Accuracy was confirmed by comparing computed flow distributions with measurements for 2 cases, showing less than 2.0% error from the measured data. Systematic integration of catheter hemodynamic information, 3DRA imaging, and CFD modeling, provides an effective and feasible alternative to obtain important quantitative blood flow information and visualization, without additional imaging.
Keywords: 3D rotational angiography; Computational fluid dynamics; Congenital heart disease; Hemodynamics; Surgical planning.
© 2024. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.
Conflict of interest statement
Declarations. Conflict of interest: Authors JZ, MS, KC, and DM have no conflicts of interest to declare related to the content of this manuscript. Ethics and IRB: For this study, we utilized de-identified patient data for retrospective secondary analysis aimed at developing computational workflow and establishing feasibility. Hence, the study was declared to be exempt from obtaining informed consent by the Colorado Multi-institutional Review Board (COMIRB) (ID: #22–0390).
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