Abstract

X-ray phase-contrast imaging is a promising method for medical imaging and non-destructive testing. Information about the attenuation, small-angle scattering and phase-shifting properties of an object can be gained simultaneously in three image modalities using a Talbot–Lau interferometer. This is a highly sensitive approach for retrieving this information. Nevertheless, until now, Talbot–Lau interferometry has been a time-consuming process due to image acquisition by phase-stepping procedures. Thus, methods to accelerate the image acquisition process in Talbot–Lau interferometry would be desirable. This is especially important for medical applications to avoid motion artifacts. In this work, the Talbot–Lau interferometry is combined with the moiré imaging approach. Firstly, the reconstruction algorithm of moiré imaging is improved compared to the standard reconstruction methods in moiré imaging that have been published until now. Thus, blurring artifacts resulting from the reconstruction in the frequency domain can be reduced. Secondly, the improved reconstruction algorithm allows for reducing artifacts in the reconstructed images resulting from inhomogeneities of the moiré pattern in large fields of view. Hence, the feasibility of differential phase-contrast imaging with regard to the integration into workflows in medical imaging and non-destructive testing is improved considerably. New fields of applications can be gained due to the accelerated imaging process—for example, live imaging in medical applications.

Highlights

  • In conventional X-ray imaging, the attenuation image of an object is acquired

  • This work shows that it is possible to depict an object in attenuation, differential phase-contrast and dark-field image with the single-shot moiré X-ray imaging method

  • The contrast to noise ratios (CNRs) values of the images reconstructed with the moiré imaging approach are comparable to those of the phase-stepping images

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Summary

Introduction

In conventional X-ray imaging, the attenuation image of an object is acquired. for example, in medical imaging, a good bone-tissue contrast can be achieved. Using a Talbot–Lau interferometer [12,20,21,22,23,24,25,26], information about the phase-shift and the scattering properties of an object can be obtained simultaneously [12,27]. This technique is very promising for applications in medical imaging [12,27,28,29,30] and non-destructive testing [12]

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