TY - JOUR
T1 - Development of a scanner-specific simulation framework for photon-counting computed tomography
AU - Abadi, Ehsan
AU - Harrawood, Brian
AU - Rajagopal, Jayasai R.
AU - Sharma, Shobhit
AU - Kapadia, Anuj
AU - Segars, William Paul
AU - Stierstorfer, Karl
AU - Sedlmair, Martin
AU - Jones, Elizabeth
AU - Samei, Ehsan
N1 - Publisher Copyright:
© 2019 IOP Publishing Ltd.
PY - 2019/8/9
Y1 - 2019/8/9
N2 - The aim of this study was to develop and validate a simulation platform that generates photon-counting CT images of voxelized phantoms with detailed modeling of manufacturer-specific components including the geometry and physics of the x-ray source, source filtrations, anti-scatter grids, and photon-counting detectors. The simulator generates projection images accounting for both primary and scattered photons using a computational phantom, scanner configuration, and imaging settings. Beam hardening artifacts are corrected using a spectrum and threshold dependent water correction algorithm. Physical and computational versions of a clinical phantom (ACR) were used for validation purposes. The physical phantom was imaged using a research prototype photon-counting CT (Siemens Healthcare) with standard (macro) mode, at four dose levels and with two energy thresholds. The computational phantom was imaged with the developed simulator with the same parameters and settings used in the actual acquisition. Images from both the real and simulated acquisitions were reconstructed using a reconstruction software (FreeCT). Primary image quality metrics such as noise magnitude, noise ratio, noise correlation coefficients, noise power spectrum, CT number, in-plane modulation transfer function, and slice sensitivity profiles were extracted from both real and simulated data and compared. The simulator was further evaluated for imaging contrast materials (bismuth, iodine, and gadolinium) at three concentration levels and six energy thresholds. Qualitatively, the simulated images showed similar appearance to the real ones. Quantitatively, the average relative error in image quality measurements were all less than 4% across all the measurements. The developed simulator will enable systematic optimization and evaluation of the emerging photon-counting computed tomography technology.
AB - The aim of this study was to develop and validate a simulation platform that generates photon-counting CT images of voxelized phantoms with detailed modeling of manufacturer-specific components including the geometry and physics of the x-ray source, source filtrations, anti-scatter grids, and photon-counting detectors. The simulator generates projection images accounting for both primary and scattered photons using a computational phantom, scanner configuration, and imaging settings. Beam hardening artifacts are corrected using a spectrum and threshold dependent water correction algorithm. Physical and computational versions of a clinical phantom (ACR) were used for validation purposes. The physical phantom was imaged using a research prototype photon-counting CT (Siemens Healthcare) with standard (macro) mode, at four dose levels and with two energy thresholds. The computational phantom was imaged with the developed simulator with the same parameters and settings used in the actual acquisition. Images from both the real and simulated acquisitions were reconstructed using a reconstruction software (FreeCT). Primary image quality metrics such as noise magnitude, noise ratio, noise correlation coefficients, noise power spectrum, CT number, in-plane modulation transfer function, and slice sensitivity profiles were extracted from both real and simulated data and compared. The simulator was further evaluated for imaging contrast materials (bismuth, iodine, and gadolinium) at three concentration levels and six energy thresholds. Qualitatively, the simulated images showed similar appearance to the real ones. Quantitatively, the average relative error in image quality measurements were all less than 4% across all the measurements. The developed simulator will enable systematic optimization and evaluation of the emerging photon-counting computed tomography technology.
KW - Computed tomography
KW - computational phantoms
KW - photon-counting
KW - photon-counting computed tomography
KW - simulation
KW - virtual clinical trial
UR - http://www.scopus.com/inward/record.url?scp=85076628864&partnerID=8YFLogxK
U2 - 10.1088/2057-1976/ab37e9
DO - 10.1088/2057-1976/ab37e9
M3 - Article
C2 - 33304618
AN - SCOPUS:85076628864
SN - 2057-1976
VL - 5
JO - Biomedical Physics and Engineering Express
JF - Biomedical Physics and Engineering Express
IS - 5
M1 - 055008
ER -