Abstract
BACKGROUND AND PURPOSE: 4D-DSA allows time-resolved 3D imaging of the cerebral vasculature. The aim of our study was to evaluate this method in comparison with the current criterion standard 3D-DSA by qualitative and quantitative means using computational fluid dynamics.
MATERIALS AND METHODS: 3D- and 4D-DSA datasets were acquired in patients with cerebral aneurysms. Computational fluid dynamics analysis was performed for all datasets. Using computational fluid dynamics, we compared 4D-DSA with 3D-DSA in terms of both aneurysmal geometry (quantitative: maximum diameter, ostium size [OZ1/2], volume) and hemodynamic parameters (qualitative: flow stability, flow complexity, inflow concentration; quantitative: average/maximum wall shear stress, impingement zone, low-stress zone, intra-aneurysmal pressure, and flow velocity). Qualitative parameters were descriptively analyzed. Correlation coefficients (r, P value) were calculated for quantitative parameters.
RESULTS: 3D- and 4D-DSA datasets of 10 cerebral aneurysms in 10 patients were postprocessed. Evaluation of aneurysmal geometry with 4D-DSA (rmaximum diameter = 0.98, Pmaximum diameter <.001; rOZ1/OZ2 = 0.98/0.86, POZ1/OZ2 < .001/.002; rvolume = 0.98, Pvolume <.001) correlated highly with 3D-DSA. Evaluation of qualitative hemodynamic parameters (flow stability, flow complexity, inflow concentration) did show complete accordance, and evaluation of quantitative hemodynamic parameters (raverage/maximum wall shear stress diastole = 0.92/0.88, Paverage/maximum wall shear stress diastole < .001/.001; raverage/maximum wall shear stress systole = 0.94/0.93, Paverage/maximum wall shear stress systole < .001/.001; rimpingement zone = 0.96, Pimpingement zone < .001; rlow-stress zone = 1.00, Plow-stress zone = .01; rpressure diastole = 0.84, Ppressure diastole = .002; rpressure systole = 0.9, Ppressure systole < .001; rflow velocity diastole = 0.95, Pflow velocity diastole < .001; rflow velocity systole = 0.93, Pflow velocity systole < .001) did show nearly complete accordance between 4D- and 3D-DSA.
CONCLUSIONS: Despite a different injection protocol, 4D-DSA is a reliable basis for computational fluid dynamics analysis of the intracranial vasculature and provides equivalent visualization of aneurysm geometry compared with 3D-DSA.
ABBREVIATIONS:
- AWSS
- average wall shear stress
- CFD
- computational fluid dynamics
- dmax
- maximum diameter
- IZ
- impingement zone
- LSZ
- low-stress zone
- MWSS
- maximum wall shear stress
- OZ
- ostium size
- r
- correlation coefficient
- V
- flow velocity
- WSS
- wall shear stress
Footnotes
Stefan Lang and Philip Hoelter contributed equally to this publication.
Disclaimer: The concepts and results presented in this paper are based on research and are not commercially available.
Disclosures: Annette I. Birkhold—UNRELATED: Employment: Siemens. Jürgen Endres—UNRELATED: Consultancy: iSchemaview, Inc; Grant: Bayern Innovativ GmbH Projektträger Bayern-BayMED.* *Money paid to the institution.
The Department of Neuroradiology, University of Erlangen-Nuremberg has a research agreement with Siemens Healthcare GmbH, Erlangen, Germany.
- © 2019 by American Journal of Neuroradiology