Subject(s)
Anti-N-Methyl-D-Aspartate Receptor Encephalitis/diagnosis , Encephalitis, Herpes Simplex/diagnosis , Pregnancy Complications, Infectious/diagnosis , Adrenal Cortex Hormones/therapeutic use , Adult , Anti-N-Methyl-D-Aspartate Receptor Encephalitis/drug therapy , Anti-N-Methyl-D-Aspartate Receptor Encephalitis/immunology , Encephalitis, Herpes Simplex/drug therapy , Encephalitis, Herpes Simplex/immunology , Female , Herpes Simplex/complications , Herpes Simplex/diagnosis , Herpes Simplex/drug therapy , Herpes Simplex/immunology , Humans , Immunoglobulins, Intravenous/therapeutic use , Immunosuppressive Agents/therapeutic use , Paresis/diagnosis , Paresis/drug therapy , Paresis/etiology , Pregnancy , Pregnancy Complications, Infectious/drug therapy , Pregnancy Complications, Infectious/immunology , Pregnancy Complications, Infectious/pathology , Pregnancy Trimester, SecondABSTRACT
Both in radiography and computed tomography (CT), recently emerged energy-resolved x-ray photon counting detectors enable the identification and quantification of individual materials comprising the inspected object. However, the approaches used for these operations require highly accurate x-ray images. The accuracy of the images is severely compromised by the presence of scattered radiation, which leads to a loss of spatial contrast and, more importantly, a bias in radiographic material imaging and artefacts in CT. The aim of the present study was to experimentally evaluate a recently introduced partial attenuation spectral scatter separation approach (PASSSA) adapted for multi-energy imaging. For this purpose, a prototype x-ray system was used. Several radiographic acquisitions of an anthropomorphic thorax phantom were performed. Reference primary images were obtained via the beam-stop (BS) approach. The attenuation images acquired from PASSSA-corrected data showed a substantial increase in local contrast and internal structure contour visibility when compared to uncorrected images. A substantial reduction of scatter induced bias was also achieved. Quantitatively, the developed method proved to be in relatively good agreement with the BS data. The application of the proposed scatter correction technique lowered the initial normalized root-mean-square error (NRMSE) of 45% between the uncorrected total and the reference primary spectral images by a factor of 9, thus reducing it to around 5%.
Subject(s)
Algorithms , Phantoms, Imaging , Photons , Thorax/diagnostic imaging , Tomography, X-Ray Computed/methods , Humans , Scattering, Radiation , X-RaysABSTRACT
X-ray imaging coupled with recently emerged energy-resolved photon counting detectors provides the ability to differentiate material components and to estimate their respective thicknesses. However, such techniques require highly accurate images. The presence of scattered radiation leads to a loss of spatial contrast and, more importantly, a bias in radiographic material imaging and artefacts in computed tomography (CT). The aim of the present study was to introduce and evaluate a partial attenuation spectral scatter separation approach (PASSSA) adapted for multi-energy imaging. This evaluation was carried out with the aid of numerical simulations provided by an internal simulation tool, Sindbad-SFFD. A simplified numerical thorax phantom placed in a CT geometry was used. The attenuation images and CT slices obtained from corrected data showed a remarkable increase in local contrast and internal structure detectability when compared to uncorrected images. Scatter induced bias was also substantially decreased. In terms of quantitative performance, the developed approach proved to be quite accurate as well. The average normalized root-mean-square error between the uncorrected projections and the reference primary projections was around 23%. The application of PASSSA reduced this error to around 5%. Finally, in terms of voxel value accuracy, an increase by a factor >10 was observed for most inspected volumes-of-interest, when comparing the corrected and uncorrected total volumes.
