The Concept of X-Ray Ct Dose Evaluation Method Using Radiochromic Film and Film-Folding Phantom

Tanki, Nobuyoshi; Katsuda, Toshizo; Gotanda, Rumi; Gotanda, Tatsuhiro; Imai, Shinya; Kawaji, Yasuyuki; Noguchi, Atsushi; Kuwano, Tadao; Fujita, Hideki; Takeda, Yoshihiro

doi:10.1093/rpd/ncab033

Cited by 3 publications

(2 citation statements)

References 33 publications

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“…However, when the entire exposure area is to be estimated, three‐dimensional (3D) volume data are required. The concept of creating 3D dose data has already been established in a previous study 15 . This study demonstrates the evaluation of 3D data using axial images.…”

Section: Introductionmentioning

confidence: 90%

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Development of a three‐dimensional dose evaluation method for computed tomography

Katsuda

Gotanda

et al. 2023

J Applied Clin Med Phys

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During a single scan using computed tomography, an X‐ray tube orbits along a 360°‐circular path around the patient. A scan obtained using the half‐cylindrical type phantoms with a radiochromic film sandwiched in between reveals a pixel value map illustrating the two‐dimensional (2D) dose distribution. A three‐dimensional (3D) dose distribution can be obtained with a 360° rotation of the 2D dose map. This study evaluates the concept and methodology of creating a 3D dose map to develop a phantom with a radiochromic film for obtaining the 3D dose distribution. The coronal and axial plane dose distributions were also evaluated. A single scan computed tomography image obtained using a half‐cylindrical type of acrylic phantom with a sandwiched radiochromic film was studied. The diameters of the phantoms were 10 and 16 cm, and their lengths were 30 cm. A 2D image of the XR‐QA2 film was obtained using an image scanner and image processing software. A red channel image was used to obtain the 3D dose distribution using a computing platform. A pseudo color was applied to the red channel image from which cross‐sectional color images were obtained. Half of the cross‐sectional pixel data were rotated by 360° to generate the data for each axial plane. The image created was saved, and a 3D pixel value map was constructed. The dose measurement procedure for the 3D dose distribution was developed using half‐cylindrical acrylic phantoms with a radiochromic film.

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Section: Introductionmentioning

confidence: 90%

“…The concept of creating 3D dose data has already been established in a previous study. 15 This study demonstrates the evaluation of 3D data using axial images.…”

Section: Introductionmentioning

confidence: 99%

Development of a three‐dimensional dose evaluation method for computed tomography

Katsuda

Gotanda

et al. 2023

J Applied Clin Med Phys

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Identification of the computed tomography dose index for tube voltage variations in a polyester-resin phantom

Fatichah

Anam

Sutanto

et al. 2023

Applied Radiation and Isotopes

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Backside Irradiation of Ultraviolet-A for Correcting Nonuniformity Error of Gafchromic XR-QA2 Films

Tanki,

Goto,

Katsuda

et al. 2024

Journal of Medical Physics

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Purpose: Radiochromic film is used for quality assurance and quality control of X-ray equipment in the diagnostic radiology. In addition, three-dimensional dose distribution of computed tomography (CT) is measured. To correct the nonuniformity and uncertainty of radiochromic films for dose measurement of CT, the films are preirradiated ultraviolet (UV)-A rays. There is a difference in the UV protection strength of radiochromic films. A concern exists about the effects of the UV-A irradiation intensity. We thus irradiated with UV-A rays from the backsides of the films to assess if backside irradiation was possible. Materials and Methods: Gafchromic XR-QA2 and RTQA2 were used in this study. The UV-A rays were simultaneously irradiated on the front and backsides of each film for 12 h. The yellow layer of each film was scanned and imaged. The average pixel values ± standard deviations (SDs) were compared. In the statistical analysis, a paired t-test was performed. To compare, the active-layer densities engendered by the UV-A rays. Calibration curve was created with 48 h of preirradiation of UV-A. Results: The mean pixel values ± SD for Gafchromic XR-QA2 on the front and backsides were 130.776 ± 0.812 and 81.015 ± 1.128, respectively. On the other hand, the mean pixel values ± SD for Gafchromic RTQA2 on the front and backsides were 62.299 ± 1.077 and 133.761 ± 1.365, respectively. The statistical results of the paired t-test were significantly different (P < 0.01) between both films. Fitting equation of the calibration curve is shown below. y = -390.47 ± 200 + (443.45 ± 10x80).5068 ± 0.0434. Conclusion: Based on the relationship between the sensitivity of the active layer to UV-A rays and the strength of UV protection on the surface, we concluded that backside irradiation is recommended for Gafchromic XR-QA2, and frontside irradiation is recommended for Gafchromic RTQA2.

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The Concept of X-Ray Ct Dose Evaluation Method Using Radiochromic Film and Film-Folding Phantom

Cited by 3 publications

References 33 publications

Development of a three‐dimensional dose evaluation method for computed tomography

Development of a three‐dimensional dose evaluation method for computed tomography

Identification of the computed tomography dose index for tube voltage variations in a polyester-resin phantom

Backside Irradiation of Ultraviolet-A for Correcting Nonuniformity Error of Gafchromic XR-QA2 Films

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