Patient-specific dose estimation for pediatric chest CT

Current methods for organ and effective dose estimations in pediatric CT are largely patient generic. Physical phantoms and computer models have only been developed for standard/limited patient sizes at discrete ages (e.g., 0, 1, 5, 10, 15 years old) and do not reflect the variability of patient ana...

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Bibliographic Details
Published in:Medical physics (Lancaster) 2008-12, Vol.35 (12), p.5821-5828
Main Authors: Li, Xiang, Samei, Ehsan, Segars, W. Paul, Sturgeon, Gregory M., Colsher, James G., Frush, Donald P.
Format: Article
Language:English
Subjects:
Adolescent
Anatomy
anthropometry
cardiology
CHEST
Child
Child, Preschool
Computed tomography
Computer modeling
computerised tomography
COMPUTERIZED SIMULATION
COMPUTERIZED TOMOGRAPHY
dosimetry
Dosimetry/exposure assessment
effective dose
Female
HEART
Humans
Image scanners
Infant
Infant, Newborn
lung
LUNGS
Male
Medical imaging
Medical Physics Letters
MONTE CARLO METHOD
Monte Carlo methods
Monte Carlo simulations
OPTIMIZATION
organ dose
Organ structure
patient-specific
PATIENTS
pediatric
PEDIATRICS
Pediatrics - methods
Phantoms, Imaging
Radiation Dosage
RADIATION DOSES
RADIATION PROTECTION AND DOSIMETRY
Radiography, Thoracic - methods
Radiometry - methods
Tomography, X-Ray Computed - methods
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Summary:Current methods for organ and effective dose estimations in pediatric CT are largely patient generic. Physical phantoms and computer models have only been developed for standard/limited patient sizes at discrete ages (e.g., 0, 1, 5, 10, 15 years old) and do not reflect the variability of patient anatomy and body habitus within the same size/age group. In this investigation, full-body computer models of seven pediatric patients in the same size/protocol group (weight: 11.9 – 18.2 kg ) were created based on the patients’ actual multi-detector array CT (MDCT) data. Organs and structures in the scan coverage were individually segmented. Other organs and structures were created by morphing existing adult models (developed from visible human data) to match the framework defined by the segmented organs, referencing the organ volume and anthropometry data in ICRP Publication 89. Organ and effective dose of these patients from a chest MDCT scan protocol (64 slice LightSpeed VCT scanner, 120 kVp , 70 or 75 mA , 0.4 s gantry rotation period, pitch of 1.375, 20 mm beam collimation, and small body scan field-of-view) was calculated using a Monte Carlo program previously developed and validated to simulate radiation transport in the same CT system. The seven patients had normalized effective dose of 3.7 – 5.3 mSv ∕ 100 mAs (coefficient of variation: 10.8%). Normalized lung dose and heart dose were 10.4 – 12.6 mGy ∕ 100 mAs and 11.2 – 13.3 mGy ∕ 100 mAs , respectively. Organ dose variations across the patients were generally small for large organs in the scan coverage ( < 7 % ) , but large for small organs in the scan coverage (9%–18%) and for partially or indirectly exposed organs (11%–77%). Normalized effective dose correlated weakly with body weight (correlation coefficient: r = − 0.80 ). Normalized lung dose and heart dose correlated strongly with mid-chest equivalent diameter (lung: r = − 0.99 , heart: r = − 0.93 ); these strong correlation relationships can be used to estimate patient-specific organ dose for any other patient in the same size/protocol group who undergoes the chest scan. In summary, this work reported the first assessment of dose variations across pediatric CT patients in the same size/protocol group due to the variability of patient anatomy and body habitus and provided a previously unavailable method for patient-specific organ dose estimation, which will help in assessing patient risk and optimizing dose reduction strategies, including the develop
ISSN:0094-2405
2473-4209
0094-2405
DOI:10.1118/1.3026593