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Main Authors: Jadick, Giavanna, La Rivière, Patrick
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.12509
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author Jadick, Giavanna
La Rivière, Patrick
author_facet Jadick, Giavanna
La Rivière, Patrick
contents Multi-energy CT has long demonstrated its ability to enhance image quality with material decomposition. Yet, it has largely been limited to applications that already have high contrast. More recently, x-ray phase-contrast (XPC) imaging has gained interest for its potential to improve detectability in tasks lacking such contrast. Previous work has demonstrated the benefit of combining multi-energy imaging with XPC for material decomposition. While the existing method is promising, its analytical approach requires several approximations that limit its broad applicability, and it is based on projection imaging, requiring separate tomographic reconstruction for three-dimensional (3D) volumes. We propose a natively 3D optimization-based solution that leverages modern computational advances, namely automatic differentiability, to efficiently solve the multi-energy CT phase retrieval problem with a more accurate forward model. In a simulation study, we quantitatively demonstrate the improvement of our proposed technique relative to the existing analytical standard, and we affirm the benefits of phase contrast over traditional absorption-only x-ray imaging.
format Preprint
id arxiv_https___arxiv_org_abs_2508_12509
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Optimization-based phase retrieval for material decomposition with multi-energy computed tomography
Jadick, Giavanna
La Rivière, Patrick
Medical Physics
Multi-energy CT has long demonstrated its ability to enhance image quality with material decomposition. Yet, it has largely been limited to applications that already have high contrast. More recently, x-ray phase-contrast (XPC) imaging has gained interest for its potential to improve detectability in tasks lacking such contrast. Previous work has demonstrated the benefit of combining multi-energy imaging with XPC for material decomposition. While the existing method is promising, its analytical approach requires several approximations that limit its broad applicability, and it is based on projection imaging, requiring separate tomographic reconstruction for three-dimensional (3D) volumes. We propose a natively 3D optimization-based solution that leverages modern computational advances, namely automatic differentiability, to efficiently solve the multi-energy CT phase retrieval problem with a more accurate forward model. In a simulation study, we quantitatively demonstrate the improvement of our proposed technique relative to the existing analytical standard, and we affirm the benefits of phase contrast over traditional absorption-only x-ray imaging.
title Optimization-based phase retrieval for material decomposition with multi-energy computed tomography
topic Medical Physics
url https://arxiv.org/abs/2508.12509