Single-Exposure, Single-Mask, Edge-Illumination X-ray Phase-Contrast Imaging Using a 7.8-µm Pixel Pitch Direct Conversion X-ray Detector

Double-mask edge-illumination is a well-reported technique for phase-contrast x-ray imaging. Although phase retrieval using this technique is comparably easier than propagation-based phase-contrast x-ray imaging, edge-illumination can be inefficient in terms of dose efficiency and imaging time when...

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Bibliographic Details
Published in2021 IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC) pp. 1 - 3
Main Authors Pil-Ali, Abdollah, Adnani, Sahar, Scott, Christopher C., Olivo, Alessandro, Karim, Karim S.
Format Conference Proceeding
LanguageEnglish
Published IEEE 16.10.2021
Subjects
Amorphous Selenium (a-Se)
CMOS X-ray Detector
Coded-Aperture
Detectors
Dose-Efficient
Edge-Illumination
High-Resolution Imaging
Illumination Curve
Image edge detection
Imaging
Information retrieval
Lighting
Motion Artifact
Phase-Contrast X-ray Imaging
Selenium
Single-Exposure
X-ray detectors
X-ray imaging
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Summary:Double-mask edge-illumination is a well-reported technique for phase-contrast x-ray imaging. Although phase retrieval using this technique is comparably easier than propagation-based phase-contrast x-ray imaging, edge-illumination can be inefficient in terms of dose efficiency and imaging time when it comes to computed tomography scanning. The illumination curve, which describes the beamlets' intensity profile impinging upon the detector, is a key parameter that contributes to retrieving phase and absorption information. To obtain the illumination curve, multiple exposures are typically required which decreases x-ray dose efficiency and, more importantly, increases imaging time. Moreover, sample motion can negatively impact the image and information retrieval process. In this research, we employ a single mask in conjunction with a 7.8-µm pixel pitch amorphous selenium-CMOS hybrid direct conversion x-ray detector to obtain the beamlets' intensity profile with only a single exposure. We demonstrate how using an ultra-high spatial resolution x-ray detector with a single-mask edge-illumination technique can potentially increase both dose efficiency and imaging time by at least a factor of 1.5X. Moreover, the resulting system using our approach is more compact with a source-to-detector distance of less than 30 cm. Single-exposure imaging can also help mitigate the impact of motion artifacts in the final image.
ISSN:2577-0829
DOI:10.1109/NSS/MIC44867.2021.9875866