Imaging features in post-mortem x-ray dark-field chest radiographs and correlation with conventional x-ray and CT

The Fokker–Planck equation can be used in a partially-coherent imaging context to model the evolution of the intensity of a paraxial x-ray wave field with propagation. This forms a natural generalisation of the transport-of-intensity equation. The x-ray Fokker–Planck equation can simultaneously account for both propagation-based phase contrast, and the diffusive effects of sample-induced small-angle x-ray scattering, when forming an x-ray image of a thin sample. Two derivations are given for the Fokker–Planck equation associated with x-ray imaging, together with a Kramers–Moyal generalisation thereof. Both equations are underpinned by the concept of unresolved speckle due to unresolved sample micro-structure. These equations may be applied to the forward problem of modelling image formation in the presence of both coherent and diffusive energy transport. They may also be used to formulate associated inverse problems of retrieving the phase shifts due to a sample placed in an x-ray beam, together with the diffusive properties of the sample. The domain of applicability for the Fokker–Planck and Kramers–Moyal equations for paraxial imaging is at least as broad as that of the transport-of-intensity equation which they generalise, hence the technique is also expected to be useful for paraxial imaging using visible light, electrons and neutrons.

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“…micro-crack detection in high-strength materials 90 ) and biomedical imaging (e.g. diagnostic imaging of the lungs 91 ).…”

Section: Discussionmentioning

confidence: 99%

X-ray Fokker–Planck equation for paraxial imaging

Paganin

Morgan

2019

Sci Rep

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“…Currently, PCCT is limited to preclinical research and not available as a clinical imaging modality. However, X-ray dark-field radiography, a contrast modality extracting a different signal of phase-contrast imaging, has recently been adapted for lung imaging in human bodies 19 20. In a clinical setting, PCCT has the potential to reduce application of contrast media and improve characterisation of liver lesions, due to its high soft-tissue contrast compared with conventional attenuation-based CT.…”

Section: Discussionmentioning

confidence: 99%

Grating-based phase-contrast CT (PCCT): histopathological correlation of human liver cirrhosis and hepatocellular carcinoma specimen

et al. 2020

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AimsTo correlate signal intensities in grating-based phase-contrast CT (PCCT) images obtained at a synchrotron light source and a conventional X-ray source with tissue components in human liver cirrhosis and hepatocellular carcinoma (HCC) specimen.MethodsStudy approval was obtained by the institutional review board. Human specimen of liver cirrhosis and HCC were imaged at experimental grating-based PCCT setups using either a synchrotron radiation source or a conventional X-ray tube. Tissue samples were sectioned and processed for H&E and Elastica van Gieson staining. PCCT and histological images were manually correlated. Depending on morphology and staining characteristics tissue components like fibrosis, HCC, inflammation, connective tissue and necrosis were differentiated and visually correlated with signal intensity in PCCT images using a 5-point Likert scale with normal liver parenchyma as a reference.ResultsGrating-based PCCT images of human cirrhotic liver and HCC specimen showed high soft-tissue contrast allowing correlation with histopathological sections. Signal intensities were similar in both setups independent of the nature of the radiation source. Connective tissue and areas of haemorrhage displayed the highest signal intensities, fibrotic liver tissue the lowest.ConclusionsGrating-based PCCT provides comparable results for the characterisation of human specimen of liver cirrhosis and HCC using either a synchrotron light source or a conventional X-ray tube. Due to its high soft-tissue contrast and its applicability to conventional X-ray tubes grating-based PCCT holds potential for preclinical research and virtual histology applications.

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“…Different kinds of technical requirements have to be met, such as the increased field-of-view, the higher grating structures needed due to higher energies used, or the setup design. In order to investigate and address the technical challenges of transferring grating-based interferometry to humans, research has been extended to larger in vivo animals and post-mortem human in recent years 22 – 25 . Finally, the investigations on imaging have been successfully extended to human in the clinic at a prototype dark-field radiography setup where first studies are going on.…”

Section: Discussionmentioning

confidence: 99%

A proof-of principal study using phase-contrast imaging for the detection of large airway pathologies after lung transplantation

Umkehrer

Morrone

Dinkel

et al. 2020

Sci Rep

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In this study we aim to evaluate the assessment of bronchial pathologies in a murine model of lung transplantation with grating-based X-ray interferometry in vivo. Imaging was performed using a dedicated grating-based small-animal X-ray dark-field and phase-contrast scanner. While the contrast modality of the dark-field signal already showed several promising applications for diagnosing various types of pulmonary diseases, the phase-shifting contrast mechanism of the phase contrast has not yet been evaluated in vivo. For this purpose, qualitative analysis of phase-contrast images was performed and revealed pathologies due to previous lung transplantation, such as unilateral bronchial stenosis or bronchial truncation. Dependent lung parenchyma showed a strong loss in dark-field and absorption signal intensity, possibly caused by several post transplantational pathologies such as atelectasis, pleural effusion, or pulmonary infiltrates. With this study, we are able to show that bronchial pathologies can be visualized in vivo using conventional X-ray imaging when phase-contrast information is analysed. Absorption and dark-field images can be used to quantify the severity of lack of ventilation in the affected lung.

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Imaging features in post-mortem x-ray dark-field chest radiographs and correlation with conventional x-ray and CT

Cited by 22 publications

References 29 publications

X-ray Fokker–Planck equation for paraxial imaging

X-ray Fokker–Planck equation for paraxial imaging

Grating-based phase-contrast CT (PCCT): histopathological correlation of human liver cirrhosis and hepatocellular carcinoma specimen

A proof-of principal study using phase-contrast imaging for the detection of large airway pathologies after lung transplantation

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