Technical Note: Characterization of x‐ray beam profiles for a fluoroscopic system incorporating copper filtration

Wunderle, Kevin; Godley, A.; Shen, Zhongzhou; Dong, Frank

doi:10.1002/mp.13774

Cited by 5 publications

(9 citation statements)

References 9 publications

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“…This additional uncertainty was estimated in a previous study (7) to be 5% for beam spectra commonly encountered during adult fluoroscopic imaging, but this uncertainty may vary by as much as 12% for beam spectra commonly encountered during pediatric imaging when using a correction factor derived from the American Association of Physicists in Medicine Task Group 190-recommended beam spectra (90-100 kV without a prescribed amount of additional filtration). Second, there are substantial variations in X-ray beam quality and intensity across the X-ray field because of the anode heel effect; with dependencies on X-ray beam quality and field size, variations at or near the skin entrance can exceed ±20% from central axis measurements (15,16). Application of these uncertainties and specific approaches to estimating PSD are beyond the scope of this work; however, valuable discussions regarding approaches to PSD calculations have been published previously (12,13).…”

Section: Discussionmentioning

confidence: 99%

The American College of Radiology Fluoroscopy Dose Index Registry Pilot: Technical Considerations and Dosimetric Performance of the Interventional Fluoroscopes

Wunderle

Jones

Dharmadhikari

et al. 2020

Journal of Vascular and Interventional Radiology

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Section: Discussionmentioning

confidence: 99%

The American College of Radiology Fluoroscopy Dose Index Registry Pilot: Technical Considerations and Dosimetric Performance of the Interventional Fluoroscopes

Wunderle

Jones

Dharmadhikari

et al. 2020

Journal of Vascular and Interventional Radiology

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“…Furthermore, the same work reported that 20% of the primary beam intensity was found just outside the edge of the beam, with a decline to 3% at a position 6 cm from the edge. X‐ray beam intensity variations, due to the heel effect, field size, tube voltage and spectral filtration, are important for backscatter corrections in PSD estimation in FGI procedures with overlapping fields 41,42 …”

Section: Current and Emerging Methods To Estimate Patient Skin Dosementioning

confidence: 99%

“…X-ray beam intensity variations, due to the heel effect, field size, tube voltage and spectral filtration, are important for backscatter corrections in PSD estimation in FGI procedures with overlapping fields. 41,42 To illustrate the variability and dependencies of backscatter factors, Fig. 6 shows the ratio of exposure from a 6 cm 2 × 6 cm 2 X-ray beam measured with an ionization chamber on the entrance surface of a number of different phantoms, compared to that of a 30 cm 3 × 30 cm 3 × 20 cm 3 block of solid water.…”

Section: A1 the Backscatter Factormentioning

confidence: 99%

“…The uncertainty imposed by the heel effect, depending on the X-ray beam quality and area striking the patient, may be up to 30%-40%. 41,42…”

Section: A7 Non-uniformity Of the X-ray Beammentioning

confidence: 99%

“…There is a knowledge gap identified by AAPM Task Group 357 and EFOMP in the literature on the magnitude of many of these uncertainties. More work should be done in general to investigate uncertainties in applied radiation dosimetry and further expand the possibilities of corrections to improve accuracy, for example, as in recent studies on collimator scatter and X‐ray beam inhomogenities 42,75 . Furthermore, it is recommended that patient skin dose estimates should be reported together with the associated uncertainty, for example, a 95% confidence interval.…”

Section: Summary Of Report and Recommendationsmentioning

confidence: 99%

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Estimation of patient skin dose in fluoroscopy: summary of a joint report by AAPM TG357 and EFOMP

et al. 2021

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Background: Physicians use fixed C-arm fluoroscopy equipment with many interventional radiological and cardiological procedures. The associated effective dose to a patient is generally considered low risk, as the benefit-risk ratio is almost certainly highly favorable. However, X-ray-induced skin injuries may occur due to high absorbed patient skin doses from complex fluoroscopically guided interventions (FGI). Suitable action levels for patient-specific follow-up could improve the clinical practice.There is a need for a refined metric regarding follow-up of X-ray-induced patient injuries and the knowledge gap regarding skin dose-related patient information from fluoroscopy devices must be filled. The most useful metric to indicate a risk of erythema, epilation or greater skin injury that also includes actionable information is the peak skin dose, that is, the largest dose to a region of skin. Materials and Methods: The report is based on a comprehensive review of best practices and methods to estimate peak skin dose found in the scientific literature and situates the importance of the Digital Imaging and Communication in Medicine (DICOM) standard detailing pertinent information contained in the Radiation Dose Structured Report (RDSR) and DICOM image headers for FGI devices. Furthermore, the expertise of the task group members and consultants have been used to bridge and discuss different methods and associated available DICOM information for peak skin dose estimation.

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Radiation field and dose inhomogeneities using an X‐ray cabinet in radiation biology research

et al. 2021

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Purpose: X-ray cabinets are replacing 137 Cs/ 60 Co sources in radiation biology research due to advantages in size, handling, and radiation protection. However, because of their different physical properties, X-ray cabinets are more susceptible to experimental influences than conventional sources. The aim of this study was to examine the variations related to the experimental setups typically used to investigate biological radiation effects with X-ray cabinets. Materials and methods: A combined approach of physical dose measurements by thermoluminescence dosimetry and detection of biological effects by quantification of γH2AX and 53BP1 foci was used to analyze field inhomogeneity and evaluate the influence of the components of the experimental setup. Results: Irradiation was performed using an X-ray tube (195 kV,10 mA,0.5-mmthick copper filter, dose rate of 0.59 Gy/min). Thermoluminescence dosimetry revealed inhomogeneity and a dose decrease of up to 42.3% within the beam area (diameter 31.1 cm) compared to the dose at the center. This dose decrease was consistent with the observed decline in the number of radiation-induced foci by up to 55.9 %. Uniform dose distribution was measured after reducing the size of the radiation field (diameter 12.5 cm). However, when using 15-ml test tubes placed at different positions within this field, the dose decreased by up to 17% in comparison to the central position. Analysis of foci number revealed significant differences between the tubes for γH2AX (1 h) and 53BP1 (4 h) at different time points after irradiation. Neither removal of some tubes nor of the caps improved the dose decrease significantly. By contrast, when using 1.5-ml tubes, dose differences were less than 4%, and no significant differences in foci number were detected. Conclusion: X-ray cabinets are user-friendly irradiation units for investigating biological radiation effects. However, field inhomogeneities and experimental setup components considerably affect the delivered irradiation doses. For this reason, strict dosimetric monitoring of experimental irradiation setups is mandatory for reliable studies.

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Technical Note: Characterization of x‐ray beam profiles for a fluoroscopic system incorporating copper filtration

Cited by 5 publications

References 9 publications

The American College of Radiology Fluoroscopy Dose Index Registry Pilot: Technical Considerations and Dosimetric Performance of the Interventional Fluoroscopes

The American College of Radiology Fluoroscopy Dose Index Registry Pilot: Technical Considerations and Dosimetric Performance of the Interventional Fluoroscopes

Estimation of patient skin dose in fluoroscopy: summary of a joint report by AAPM TG357 and EFOMP

Radiation field and dose inhomogeneities using an X‐ray cabinet in radiation biology research

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