Performance of high‐resolution CT for detection and discrimination tasks related to stenotic lesions – A phantom study using model observers

Hernandez, Andrew M.; Burkett, George W.; Pham, Nancy; Abbey, Craig K.; Boone, John M.

doi:10.1002/mp.16194

Cited by 2 publications

(3 citation statements)

References 34 publications

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“…Detectability of simulated lung lesions was best with the smoothest level in DLR; a dose reduction potential of 81% to 94% was assumed. An overview of recently published articles on deep learning–based image reconstruction 5,9,47–87 is given in Table 5.…”

Section: Image Reconstructionmentioning

confidence: 99%

Computed Tomography 2.0

Lell

Kachelrieß

2023

Invest Radiol

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Computed tomography (CT) dramatically improved the capabilities of diagnostic and interventional radiology. Starting in the early 1970s, this imaging modality is still evolving, although tremendous improvements in scan speed, volume coverage, spatial and soft tissue resolution, as well as dose reduction have been achieved. Tube current modulation, automated exposure control, anatomy-based tube voltage (kV) selection, advanced x-ray beam filtration, and iterative image reconstruction techniques improved image quality and decreased radiation exposure. Cardiac imaging triggered the demand for high temporal resolution, volume acquisition, and high pitch modes with electrocardiogram synchronization. Plaque imaging in cardiac CT as well as lung and bone imaging demand for high spatial resolution. Today, we see a transition of photon-counting detectors from experimental and research prototype setups into commercially available systems integrated in patient care. Moreover, with respect to CT technology and CT image formation, artificial intelligence is increasingly used in patient positioning, protocol adjustment, and image reconstruction, but also in image preprocessing or postprocessing. The aim of this article is to give an overview of the technical specifications of up-to-date available whole-body and dedicated CT systems, as well as hardware and software innovations for CT systems in the near future.

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Section: Image Reconstructionmentioning

confidence: 99%

Computed Tomography 2.0

Lell

Kachelrieß

2023

Invest Radiol

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“…As it stands, the highresolution scanner appears to improve dose efficiency for high-resolution tasks but decrease dose efficiency for low-resolution tasks. 5 While the pixel pitch of scintillator-photodiode detectors has generally remained at 1 mm for most CT systems, other X-ray detectors have seen improvement. In flat-panel detectors, the pixel pitch is small and interpixel reflectors are not practical.…”

Section: Introductionmentioning

confidence: 99%

“…While the dimensions of the high‐resolution design are not known to us, and it is possible that improvements in fill factor were obtained in the engineering of this high‐resolution scanner, the observed radiation dose increase appears consistent with a model where the reflector dimensions are fixed at 0.1 mm wide: such a model would predict a dose increase proportional to the fill factors,

\frac{{{{0.9}^2}}}{{{{0.8}^2}}} - 1\; = \;27\%

. As it stands, the high‐resolution scanner appears to improve dose efficiency for high‐resolution tasks but decrease dose efficiency for low‐resolution tasks 5 …”

Section: Introductionmentioning

confidence: 99%

Possible improvements in effective fill factor using X‐ray fluorescent interpixel reflectors

Hsieh

2024

Medical Physics

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BackgroundThe spatial resolution of energy‐integrating diagnostic CT scanners is limited by interpixel reflectors on the detector, which optically isolate pixels but create dead space. Because the width of the reflector cannot easily be decreased, fill factor diminishes as resolution increases.PurposeWe propose loading (or mixing) a high‐Z element into the reflectors, causing the reflectors to be X‐ray fluorescent. Re‐emitted characteristic X‐rays could be detected in adjacent pixels, increasing the effective fill factor and compensating for fill factor loss with higher‐resolution detectors. The purpose of this work is to understand the physical principles of this approach and to analyze its effectiveness using Monte Carlo simulations.MethodsDetector pixels were modeled using the GEANT4 Monte Carlo package. The width of the reflector was kept constant at 0.1 mm throughout, and we considered pixel pitches between 0.5 and 1 mm. The pixelated scintillator material was gadolinium oxysulfide, 3 mm thick. The baseline reflector material was chosen to be acrylic, and varying concentrations of a high‐Z element were loaded into the material. We assumed that the optical characteristics of pixels were ideal (no absorption within pixels, perfect reflection at boundaries). The detector was irradiated uniformly with 10,000 X‐ray photons to estimate its spectral response. The figure of merit was the variance of the detector signal at zero frequency normalized to that of an ideal single‐bin photon‐counting detector with 100% fill factor. Sensitivity analyses were conducted to understand the effect of varying the high‐Z element concentration and the spectrum.ResultsInitial simulations suggested that a k‐edge near 50 keV would be ideal. Gd was therefore selected as the high‐Z material. The relative variances for a conventional energy integrating detector without Gd at 1 mm pixel pitch (81% fill factor) and 0.5 mm pixel pitch (64% fill factor) were 1.38 and 1.74, compared to 1.00 for an ideal photon counting detector, implying a 26% variance penalty for 0.5 mm pitch. When 1 g/cm3 Gd was loaded into the interpixel reflector, the relative variance improved to 1.27 and 1.43, respectively, implying that the variance penalty for including Gd together with 0.5 mm pitch is only 4%. Performance was nearly maximized at 1.0 g/cm3 of Gd, but a concentration of 0.5 g/cm3 of Gd showed most of the benefit. Improvements depend weakly on kV, with lower kV associated with higher improvements. An external anti‐scatter grid was not modeled in our simulations and would reduce the expected benefit, depending greatly on the pitch and dimensionality of the anti‐scatter grid.ConclusionsThe losses in fill factor associated with smaller pixel pitch can be reduced if Gd or a similar element could be loaded into the interpixel reflector. These improvements in noise efficiency are yet to be verified experimentally.

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Performance of high‐resolution CT for detection and discrimination tasks related to stenotic lesions – A phantom study using model observers

Cited by 2 publications

References 34 publications

Computed Tomography 2.0

Computed Tomography 2.0

Possible improvements in effective fill factor using X‐ray fluorescent interpixel reflectors

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