Self-Calibrated Epipolar Reconstruction for Assessment of Aneurysms in the Internal Carotid Artery Using In-Silico Biplane Angiograms

TL;DR

This paper presents a self-calibrated epipolar reconstruction method that improves 3D visualization of intracranial aneurysms from biplane angiograms, aiding treatment planning by overcoming traditional imaging limitations.

Contribution

The study introduces a novel epipolar reconstruction approach that automatically calibrates and reconstructs vascular structures in 3D from biplane angiograms, enhancing accuracy and speed.

Findings

Reconstruction accuracy with Dice-Sorensen coefficients around 0.65-0.76.

Average reconstruction time was approximately 10 seconds.

Method generalized well across different aneurysm models.

Abstract

The treatment of intracranial aneurysms (IA) relies on angiography guidance using biplane views. However, accurate flow estimation and device sizing for treatment are often compromised by vessel overlap and foreshortening, which can obscure critical details. This study introduces an epipolar reconstruction approach to enhance 3D rendering of the internal carotid artery (ICA) and aneurysm dome using routinely acquired biplane angiographic data. Our method aims to improve procedural guidance by overcoming the limitations of traditional two-dimensional imaging techniques. This study employed three 3D geometries of ICA aneurysms to simulate virtual angiograms. These angiograms were generated using a computational fluid dynamics (CFD) solver, followed by the simulation of biplane angiography using a cone-beam geometry. Self-calibration was accomplished by matching contrast media position as a function of time between biplane views. Feature-matching was used to triangulate and reconstruct vascular structures in 3D. The projection data was utilized to refine the 3D estimation, including elimination of erroneous structures and ellipse-fitting. The accuracy of the reconstructions was evaluated using the Dice-Sorensen coefficient, comparing the 3D reconstructions to the original models. The proposed epipolar reconstruction method generalized well across the three tested aneurysm models, with respective Dice-Sorensen coefficients of 0.745, 0.759, and 0.654. Errors were primarily due to partial vessel overlap. The average reconstruction time for all three volumes was approximately 10 seconds. The proposed epipolar reconstruction method enhanced 3D visualization, addressing challenges such as projection-induced vessel foreshortening. This method provides a solution to the complexity of IA visualization, with the potential to provide more accurate analysis and device sizing for treatment.