Quantitative imaging using high-energy X-ray phase-contrast CT with a 70 kVp polychromatic X-ray spectrum.

Imaging of large and dense objects with grating-based X-ray phase-contrast computed tomography requires high X-ray photon energy and large fields of view. It has become increasingly possible due to the improvements in the grating manufacturing processes. Using a high-energy X-ray phase-contrast CT setup with a large (10 cm in diameter) analyzer grating and operated at an acceleration tube voltage of 70 kVp, we investigate the complementarity of both attenuation and phase contrast modalities with materials of various atomic numbers (Z). We confirm experimentally that for low-Z materials, phase contrast yields no additional information content over attenuation images, yet it provides increased contrast-to-noise ratios (CNRs). The complementarity of both signals can be seen again with increasing Z of the materials and a more comprehensive material characterization is thus possible. Imaging of a part of a human cervical spine with intervertebral discs surrounded by bones and various soft tissue types showcases the benefit of high-energy X-ray phase-contrast system. Phase-contrast reconstruction reveals the internal structure of the discs and makes the boundary between the disc annulus and nucleus pulposus visible. Despite the fact that it still remains challenging to develop a high-energy grating interferometer with a broad polychromatic source with satisfactory optical performance, improved image quality for phase contrast as compared to attenuation contrast can be obtained and new exciting applications foreseen.

[1]  J. H. Hubbell,et al.  Photon cross sections, attenuation coefficients, and energy absorption coefficients from 10 keV to 100 GeV , 1969 .

[2]  Rainer Raupach,et al.  Analytical evaluation of the signal and noise propagation in x-ray differential phase-contrast computed tomography , 2011, Physics in medicine and biology.

[3]  D. Stutman,et al.  Glancing angle Talbot-Lau grating interferometers for phase contrast imaging at high x-ray energy. , 2012, Applied physics letters.

[4]  Franz Pfeiffer,et al.  Evaluating the microstructure of human brain tissues using synchrotron radiation-based micro-computed tomography , 2010, Optical Engineering + Applications.

[5]  Yi Qin,et al.  Micro-Manufacturing Engineering and Technology , 2010 .

[6]  J H Siewerdsen,et al.  High energy x-ray phase contrast CT using glancing-angle grating interferometers. , 2014, Medical physics.

[7]  O. Bunk,et al.  Hard x-ray phase tomography with low-brilliance sources. , 2007, Physical review letters.

[8]  E. McCullough,et al.  Photon attenuation in computed tomography. , 1975, Medical physics.

[9]  J. Schulz,et al.  Deep X-Ray Lithography , 2015 .

[10]  Franz Pfeiffer,et al.  Inverse geometry for grating-based x-ray phase-contrast imaging , 2009 .

[11]  Thomas Koehler,et al.  Simultaneous de-noising in phase contrast tomography , 2012 .

[12]  Juergen Mohr,et al.  Soft X-ray lithography of high aspect ratio SU8 submicron structures , 2008 .

[13]  Franz Pfeiffer,et al.  Quantitative wave-optical numerical analysis of the dark-field signal in grating-based X-ray interferometry , 2012 .

[14]  Pascal Meyer,et al.  Increasing the field of view of x-ray phase contrast imaging using stitched gratings on low absorbent carriers , 2014, Medical Imaging.

[15]  S Auweter,et al.  Quantitative breast tissue characterization using grating-based x-ray phase-contrast imaging , 2014, Physics in medicine and biology.

[16]  Franz Pfeiffer,et al.  Quantitative X-ray phase-contrast computed tomography at 82 keV. , 2013, Optics express.

[17]  Sergei V. Gangnus,et al.  The collagen structure of bovine intervertebral disc studied using polarization-sensitive optical coherence tomography. , 2004, Physics in medicine and biology.

[18]  Franz Pfeiffer,et al.  Quantitative phase-contrast tomography of a liquid phantom using a conventional x-ray tube source. , 2009, Optics express.

[19]  Atsushi Momose,et al.  Phase Tomography by X-ray Talbot Interferometry for Biological Imaging , 2006 .

[20]  Franz Pfeiffer,et al.  Phase-contrast imaging and tomography at 60 keV using a conventional x-ray tube source. , 2009, The Review of scientific instruments.

[21]  Franz Pfeiffer,et al.  X-ray phase imaging with a grating interferometer. , 2005, Optics express.

[22]  F Verhaegen,et al.  SpekCalc: a program to calculate photon spectra from tungsten anode x-ray tubes , 2009, Physics in medicine and biology.

[23]  M. Stampanoni,et al.  X-ray phase-contrast imaging at 100 keV on a conventional source , 2014, Scientific Reports.

[24]  O. Bunk,et al.  Hard-X-ray dark-field imaging using a grating interferometer. , 2008, Nature materials.

[25]  F. Pfeiffer,et al.  Imaging Liver Lesions Using Grating-Based Phase-Contrast Computed Tomography with Bi-Lateral Filter Post-Processing , 2014, PloS one.

[26]  Thomas Köhler,et al.  Noise properties of grating-based x-ray phase contrast computed tomography. , 2011, Medical physics.

[27]  O. Bunk,et al.  Phase retrieval and differential phase-contrast imaging with low-brilliance X-ray sources , 2006 .

[28]  J. H. Hubbell,et al.  XCOM: Photon Cross Section Database (version 1.2) , 1999 .

[29]  Juerg Leuthold,et al.  High aspect ratio gratings for X-ray phase contrast imaging , 2012 .

[30]  F. Pfeiffer,et al.  Phase-contrast CT: qualitative and quantitative evaluation of atherosclerotic carotid artery plaque. , 2014, Radiology.