Statistical Image Reconstruction Using Mixed Poisson-Gaussian Noise Model for X-Ray CT

TL;DR

This paper introduces MPG, a novel statistical image reconstruction method for ultra-low dose X-ray CT that models raw measurements with a mixed Poisson-Gaussian distribution, enabling accurate images with reduced noise and bias.

Contribution

The paper proposes MPG, a new SIR approach that directly handles negative raw data at ultra-low doses using a mixed Poisson-Gaussian model, improving image quality over existing methods.

Findings

MPG reduces noise in reconstructed images.

MPG decreases bias compared to traditional methods.

MPG effectively handles non-positive raw data without pre-processing.

Abstract

Statistical image reconstruction (SIR) methods for X-ray CT produce high-quality and accurate images, while greatly reducing patient exposure to radiation. When further reducing X-ray dose to an ultra-low level by lowering the tube current, photon starvation happens and electronic noise starts to dominate, which introduces negative or zero values into the raw measurements. These non-positive values pose challenges to post-log SIR methods that require taking the logarithm of the raw data, and causes artifacts in the reconstructed images if simple correction methods are used to process these non-positive raw measurements. The raw data at ultra-low dose deviates significantly from Poisson or shifted Poisson statistics for pre-log data and from Gaussian statistics for post-log data. This paper proposes a novel SIR method called MPG (mixed Poisson-Gaussian). MPG models the raw noisy measurements using a mixed Poisson-Gaussian distribution that accounts for both the quantum noise and electronic noise. MPG is able to directly use the negative and zero values in raw data without any pre-processing. MPG cost function contains a reweighted least square data-fit term, an edge preserving regularization term and a non-negativity constraint term. We use Alternating Direction Method of Multipliers (ADMM) to separate the MPG optimization problem into several sub-problems that are easier to solve. Our results on 3D simulated cone-beam data set and synthetic helical data set generated from clinical data indicate that the proposed MPG method reduces noise and decreases bias in the reconstructed images, comparing with the conventional filtered back projection (FBP), penalized weighted least-square (PWLS) and shift Poisson (SP) method for ultra-low dose CT (ULDCT) imaging.