Grating-Based X-ray Phase Imaging Using Multiline X-ray Source

Momose, Atsushi; Yashiro, Wataru; Kuwabara, Hiroaki; Kawabata, Katsuyuki

doi:10.1143/jjap.48.076512

Cited by 57 publications

(38 citation statements)

References 19 publications

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“…A third grating placed after the x-ray source must be employed in the laboratory version of the technique to create an array of individually coherent sources. An alternative method to obtain individual coherent sources is to cut grooves in the anode target of the x-ray source [10].…”

Section: Introductionmentioning

confidence: 99%

Phase Contrast Imaging with Coded Apertures Using Laboratory-Based X-ray Sources

Ignatyev¹,

Munro²,

Speller³

et al. 2011

AIP Conference Proceedings

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Section: Introductionmentioning

confidence: 99%

Phase Contrast Imaging with Coded Apertures Using Laboratory-Based X-ray Sources

Ignatyev¹,

Munro²,

Speller³

et al. 2011

AIP Conference Proceedings

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“…The development of phase contrast imaging relevant to medical application became active worldwide, among those are the Tsukuba PF -KEK and Harima Spring 8 as leading brands. Because of this kind of large-scale facility, it was recommended to utilize a large number of research developments in industry and government studies [34][35][36][37][38] . However, in order to utilize phase contrast imaging, coherent illumination is necessary.…”

Section: Discussionmentioning

confidence: 99%

“…In relation to this, LEBRA is a relatively small-sized linear accelerator driven x-ray source which is originally coherent monochromatic x-ray where phase contrast imaging can be easily done. Applying this principle, the possibility of compact facilityand clinical application is shown 38) . Presently, we repeat the actual proof of the experiment using internal organs with soft tissues for the advancement of clinical diagnosis.…”

Section: Discussionmentioning

confidence: 99%

Diffraction Enhanced Phase Contrast Imaging of a Kitten Deciduous Tooth using Coherent X-ray Source

Tanaka

Takahashi

Hayakawa

et al. 2010

J. Hard Tissue Biology.

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Wavelength-tunable monochromatic Parametric x-ray (PXR) was generated at the Laboratory for Electron Beam Research and Application (LEBRA) at Nihon University. Using the LEBRA-PXR, phase contrast imaging was carried out. Phase contrast images of a kitten deciduous tooth were taken by diffraction enhanced imaging (DEI) method. The results showed that LEBRA-PXR is a high coherent x-ray and is suitable for phase contrast imaging.

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“…Both rotating-anode x-ray tubes and indirect-detection flat panel detectors (FPD) have been used in DPC-CT systems. 4,7,15,58 Incident photons are diffracted by the Talbot-Lau interferometer before interacting with the detector, as shown in Fig. 1.…”

Section: Iiia Cascaded System Model For Dpc-ct and Act Acquisitionsmentioning

confidence: 99%

Fundamental relationship between the noise properties of grating-based differential phase contrast CT and absorption CT: Theoretical framework using a cascaded system model and experimental validation

Bevins

Zambelli

et al. 2013

Med. Phys.

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Purpose: Using a grating interferometer, a conventional x-ray cone beam computed tomography (CT) data acquisition system can be used to simultaneously generate both conventional absorption CT (ACT) and differential phase contrast CT (DPC-CT) images from a single data acquisition. Since the two CT images were extracted from the same set of x-ray projections, it is expected that intrinsic relationships exist between the noise properties of the two contrast mechanisms. The purpose of this paper is to investigate these relationships. Methods: First, a theoretical framework was developed using a cascaded system model analysis to investigate the relationship between the noise power spectra (NPS) of DPC-CT and ACT. Based on the derived analytical expressions of the NPS, the relationship between the spatial-frequencydependent noise equivalent quanta (NEQ) of DPC-CT and ACT was derived. From these fundamental relationships, the NPS and NEQ of the DPC-CT system can be derived from the corresponding ACT system or vice versa. To validate these theoretical relationships, a benchtop cone beam DPC-CT/ACT system was used to experimentally measure the modulation transfer function (MTF) and NPS of both DPC-CT and ACT. The measured three-dimensional (3D) MTF and NPS were then combined to generate the corresponding 3D NEQ. Results: Two fundamental relationships have been theoretically derived and experimentally validated for the NPS and NEQ of DPC-CT and ACT: (1) the 3D NPS of DPC-CT is quantitatively related to the corresponding 3D NPS of ACT by an inplane-only spatial-frequency-dependent factor 1/f 2 , the ratio of window functions applied to DPC-CT and ACT, and a numerical factor C g determined by the geometry and efficiency of the grating interferometer. Note that the frequency-dependent factor is independent of the frequency component f z perpendicular to the axial plane. (2) The 3D NEQ of DPC-CT is related to the corresponding 3D NEQ of ACT by an f 2 scaling factor and numerical factors that depend on both the attenuation and refraction properties of the image object, as well as C g and the MTF of the grating interferometer. Conclusions: The performance of a DPC-CT system is intrinsically related to the corresponding ACT system. As long as the NPS and NEQ of an ACT system is known, the corresponding NPS and NEQ of the DPC-CT system can be readily estimated using additional characteristics of the grating interferometer.

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Grating-Based X-ray Phase Imaging Using Multiline X-ray Source

Cited by 57 publications

References 19 publications

Phase Contrast Imaging with Coded Apertures Using Laboratory-Based X-ray Sources

Phase Contrast Imaging with Coded Apertures Using Laboratory-Based X-ray Sources

Diffraction Enhanced Phase Contrast Imaging of a Kitten Deciduous Tooth using Coherent X-ray Source

Fundamental relationship between the noise properties of grating-based differential phase contrast CT and absorption CT: Theoretical framework using a cascaded system model and experimental validation

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