Sinogram-based flow estimation in computed tomography using a physics-informed neural network: Impact of gantry rotation speed, X-ray fluence and pulsed acquisition on accuracy.

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Abstract

Non-invasive imaging-based assessment of blood flow plays a critical role in evaluating heart function and structure. Computed Tomography (CT) is a widely-used imaging modality that can robustly evaluate cardiovascular anatomy and function, but direct methods to estimate blood flow velocity from movies of contrast dynamics have not been developed. This study evaluates the impact of CT imaging parameters on Physics-Informed Neural Networks (PINN)-based flow estimation and proposes an improved PINN-based approach, SinoFlow, which uses sinogram data directly to estimate blood flow. We generated pulsatile flow fields in an idealized 2D vessel bifurcation using computational fluid dynamics and simulated CT scans with varying gantry rotation speeds, photon flux, and pulse mode imaging settings. We compared the performance of PINN-based flow estimation using reconstructed images (ImageFlow) to SinoFlow. SinoFlow significantly improved flow estimation performance by avoiding temporal inconsistency errors introduced by filtered backprojection. SinoFlow was robust across all tested gantry rotation speeds and consistently produced lower mean squared error and velocity errors than ImageFlow. Additionally, SinoFlow was less susceptible to noise in the sinogram and was compatible with pulsed-mode imaging and maintained higher accuracy with shorter pulse widths. This study demonstrates the potential of SinoFlow for CT-based flow estimation, providing a more promising approach for non-invasive blood flow assessment. The findings inform future applications of PINNs to CT images and provide an alternative which avoids limitations associated with image-based estimation.

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