Single-Shot Quantitative X-ray Imaging Using a Primary Modulator and Dual-Layer Detector

TL;DR

This paper introduces a novel single-shot quantitative x-ray imaging method combining a primary modulator and dual-layer detector, enabling accurate material differentiation and scatter correction in a single acquisition.

Contribution

The work presents a new SSQI algorithm that simultaneously recovers multiple material-specific and scatter images from a single shot, improving quantitative accuracy over traditional methods.

Findings

RMSE of 0.13 cm for acrylic and 0.04 mm for copper.

Successfully distinguished contrast in phantom images, reducing RMSE by up to 92%.

Accurate dynamic imaging of iodine contrast in flow phantom.

Abstract

Purpose: Conventional x-ray imaging and fluoroscopy have limitations in quantitation due to several challenges, including scatter, beam hardening, and overlapping tissues. In this work, we propose single-shot quantitative imaging (SSQI) by combining the use of a primary modulator (PM) and dual-layer (DL) detector, which enables motion-free dual-energy (DE) imaging with scatter correction in a single shot. Methods: The SSQI algorithm allows simultaneous recovery of two material-specific images and two scatter images using four sub-measurements from the PM encoding. For validation, we set up SSQI on our tabletop system and imaged acrylic and copper slabs with known thicknesses, estimated scatter with our SSQI algorithm, and compared the material decomposition (MD) for different combinations of the two materials with ground truth. Second, we imaged an anthropomorphic chest phantom containing contrast in the coronary arteries and compared the MD with and without SSQI. Lastly, to evaluate SSQI in dynamic applications, we constructed a flow phantom that enabled dynamic imaging of iodine contrast. Results: The root mean squared error (RMSE) of SSQI estimation was 0.13 cm for acrylic and 0.04 mm for copper. For the anthropomorphic phantom, direct MD resulted in incorrect interpretation of contrast and soft tissue, while SSQI successfully distinguished them and reduced RMSE in material-specific images by 38% to 92%. For the flow phantom, SSQI was able to perform accurate dynamic quantitative imaging, separating contrast from the background. Conclusions: We demonstrated the potential of SSQI for robust quantitative x-ray imaging. The simplicity of SSQI may enable its widespread adoption, including radiography and dynamic imaging such as real-time image guidance and cone-beam CT.