A new solution for radiation transmission in anti-scatter grids

Zhou, Abel; Yin, Yuming; White, Graeme L.; Davidson, Rob

doi:10.1088/2057-1976/2/5/055011

Cited by 12 publications

(35 citation statements)

References 55 publications

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“…Results from previous simulation investigations 13,17 showed that radiation transmissions in grids were affected by the virtual image receptors stimulated with a physical image receptor without all the construction details. In both the grid evaluation and the determination of SPR, this work necessitated the use of a simulated perfectly efficient detector of energy‐integration to avoid any potential bias from the construction of a physical image receptor.…”

Section: Methodsmentioning

confidence: 96%

“…In this work, the simulation included the interference effect on Rayleigh scattering which has an effect on scatter‐to‐primary ratio (SPR) 13,29,32–35 and Ts 13,35,36 . The simulation of radiation transport in the grid materials were performed using the method of Zhou et al 17 in which the interaction probability of each photon in the grid materials was determined by the path lengths in each type of grid materials. These path lengths were presumably determined as if the photon would traverse the grid materials without an interaction with them.…”

Section: Methodsmentioning

confidence: 99%

“…There is no information found about grid design to optimize grid performance. It is accepted that forward scatter radiation in the narrow‐beam method 12 influences Tp and forward scatter radiation which should arise in the materials underneath the blocker affects Ts 13,17 . Tp, Ts, and Tt are used to calculate the combined effects of the differential attenuation of the primary radiation and scatter reduction (noise reduction) on image diagnostic quality.…”

Section: Introductionmentioning

confidence: 99%

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The determination of the optimal strip‐thickness of anti‐scatter grids for a given grid ratio and strip height

Zhou

Yin

Tan

et al. 2020

Int J Imaging Syst Tech

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In X‐ray imaging, anti‐scatter grids are used to reduce scatter radiation reaching image receptors, hence improving image quality. Optimization of grid performance is essential for improving image diagnostic quality and minimizing radiation doses to patients. This work investigated the performance of a series of grid designs modeled from the design of typically focused grid with grid ratio 8:1 (r8) and strip height 1.7 mm (h1.7) for high‐energy radiographic applications. Monte Carlo simulation was used to evaluate designs (r8h1.7) which had the strip thickness changed from 6 to 150 μm in 2 μm increments and the interspace distance fixed at 214 μm. The transmissions of radiation in grid materials were modeled by using a regression with radial‐basis‐function‐networks (RBFNS). KSNR was then determined from RBFNS models of radiation transmissions. The optimal strip‐thickness was obtained at the maximum signal‐to‐noise ratio (SNR) improvement factor (KSNR). For high‐energy applications at 100 peak‐kilo‐voltage (kVp) and 30 cm PMMA thickness, the optimal lead‐strip‐thickness was found approximately 74 μm resulting in a strip‐frequency approximately 35 per cm (N35). Using the optimal thickness for imaging condition at 100 kVp and 30 cm thickness, the KSNR would increase by approximately 5.3%. This work showed the existence of optimal strip‐thickness for a series of grids with a given grid‐ratio, strip‐height, strip‐, and interspace materials. The findings are useful and provide guidance to improve grid designs for better performance that will essentially lead to better image quality and better radiation protection for patients.

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Section: Methodsmentioning

confidence: 96%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The determination of the optimal strip‐thickness of anti‐scatter grids for a given grid ratio and strip height

Zhou

Yin

Tan

et al. 2020

Int J Imaging Syst Tech

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“…As modificações no código que envolviam a dosimetria da mama foram validadas ao comparar os resultados do Report TG-195 22 , Nosratieh et al 31 , Sarno et al 9 e Wu et al 5 . O algoritmo da grade antiespalhamento foi validado previamente 32 comparando os resultados de Zhou et al 33 e Cunha et al 7 3. Resultados e Discussão 3.1.…”

Section: Validação Do Códigounclassified

Mamografia Digital: estudos dosimétricos e de qualidade da imagem por simulação Monte Carlo

Massera

Tomal

2019

Rev Bras Fis Med

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Por meio do código Monte Carlo (MC) modificado PENELOPE (v. 2014) + penEasy (v. 2015), a contribuição do corpo do paciente na dose glandular média (DGM), além da contribuição dos fótons por tipos de interação e da geração da partícula, foi estudada. Diferentes métodos de ponderação da DGM foram comparados. A razão contraste-ruído (CNR) foi quantificada para diferentes tamanhos e tipos de lesões (calcificação e tumor), na ausência e presença de grades antiespalhamento (ideal, linear e celular). Em mamografia, o corpo do paciente contribui com menos de 1% para o aumento da DGM. O efeito fotoelétrico é a interação que mais contribui para a DGM (até aproximadamente 50 keV), enquanto a contribuição da radiação espalhada aumenta com a energia e espessura da mama. Ponderar a DGM de maneira retrospectiva pode subestimar em até 6%, para mamas espessas e de baixa glandularidade em 60 keV, sendo negligenciável em mamografia digital. A CNR pode ser superestimada em até 27(2)% na ausência de grade, dependendo da área da lesão, indicando que seu tamanho deve ser considerado nos estudos de qualidade da imagem.

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“…Several degrading mechanisms exist, including patient voluntary and involuntary motion, detector blur, inferior detective quantum efficiency (DQE) and scatter radiations amongst others. Scatter radiation being the dominant image degradation mechanism, many researchers have investigated hardware based scatter correction methods that currently refer to the use of antiscatter grids (Fetterly and Schueler 2008, Carton et al 2009, Zhou et al 2016, Omondi et al 2020. However, the scatter correction efficacy of anti-scatter grids needs further improvements by improving the grid designs based on the fundamental grids features that include, grid ratio (r), grid frequency (N) and septa to interspace ratio (R) amongst others (Zhou et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Evaluation of scatter suppression algorithm for X-ray exposure of soft tissue equivalent phantoms over nominal energy range using FLUKA code

et al. 2021

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Soft tissue imaging is heavily impaired by streaks and cupping effects associated with X-ray scatter. Quality of images from projection imaging may be improved by the use of enhanced anti-scatter grids’ designs with potency to reject significant scatter. However, optimization of grid characteristics requires investigation to improve diagnostic image quality. Transmitted scatter spatially distributed degrades images engendering need for effective scatter correction protocols. This study investigated the pre-scan scatter suppression algorithm for X-ray exposure of soft tissue equivalent phantoms over nominal energy range. Adipose tissue and polymethyl methacrylate phantoms of cross-sectional area (30 x 30) cm2 and of varying thickness from 2 to 8 cm in 1 cm increments were successively exposed using energy ranging between 20–50 kVp. Monte Carlo simulation based on FLUKA code and flair interface was used to generate an input file for execution. The source simulated five cycles of ten million photons each of annular X-ray photon beam of radius, r = 0.5 cm at fixed field of view (FOV) through anti-scatter grid on to gadolinium oxysulfide detector. The transmitted total, scatter and primary estimates were evaluated with and without grids over varying phantom thicknesses, energy and grid design features. The simulated and experimental results obtained were comparable and in agreement with previous literature. Pearson’s correlation coefficients for scatter fraction and scatter to primary ratio were 0.983 and 0.981, respectively. The strong correlation between simulation and experiment results indicated correctness in methodology and protocol. The algorithms and protocols in the simulation would be appropriate for designing grids with enhanced scatter rejection capabilities. Keywords: FLUKA code, Monte Carlo simulation, Scatter suppression algorithm, Scatter correction, X-ray imaging systems.

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A new solution for radiation transmission in anti-scatter grids

Cited by 12 publications

References 55 publications

The determination of the optimal strip‐thickness of anti‐scatter grids for a given grid ratio and strip height

The determination of the optimal strip‐thickness of anti‐scatter grids for a given grid ratio and strip height

Mamografia Digital: estudos dosimétricos e de qualidade da imagem por simulação Monte Carlo

Evaluation of scatter suppression algorithm for X-ray exposure of soft tissue equivalent phantoms over nominal energy range using FLUKA code

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