A set of 4D pediatric XCAT reference phantoms for multimodality research.

PURPOSE The authors previously developed an adult population of 4D extended cardiac-torso (XCAT) phantoms for multimodality imaging research. In this work, the authors develop a reference set of 4D pediatric XCAT phantoms consisting of male and female anatomies at ages of newborn, 1, 5, 10, and 15 years. These models will serve as the foundation from which the authors will create a vast population of pediatric phantoms for optimizing pediatric CT imaging protocols. METHODS Each phantom was based on a unique set of CT data from a normal patient obtained from the Duke University database. The datasets were selected to best match the reference values for height and weight for the different ages and genders according to ICRP Publication 89. The major organs and structures were segmented from the CT data and used to create an initial pediatric model defined using nonuniform rational B-spline surfaces. The CT data covered the entire torso and part of the head. To complete the body, the authors manually added on the top of the head and the arms and legs using scaled versions of the XCAT adult models or additional models created from cadaver data. A multichannel large deformation diffeomorphic metric mapping algorithm was then used to calculate the transform from a template XCAT phantom (male or female 50th percentile adult) to the target pediatric model. The transform was applied to the template XCAT to fill in any unsegmented structures within the target phantom and to implement the 4D cardiac and respiratory models in the new anatomy. The masses of the organs in each phantom were matched to the reference values given in ICRP Publication 89. The new reference models were checked for anatomical accuracy via visual inspection. RESULTS The authors created a set of ten pediatric reference phantoms that have the same level of detail and functionality as the original XCAT phantom adults. Each consists of thousands of anatomical structures and includes parameterized models for the cardiac and respiratory motions. Based on patient data, the phantoms capture the anatomic variations of childhood, such as the development of bone in the skull, pelvis, and long bones, and the growth of the vertebrae and organs. The phantoms can be combined with existing simulation packages to generate realistic pediatric imaging data from different modalities. CONCLUSIONS The development of patient-derived pediatric computational phantoms is useful in providing variable anatomies for simulation. Future work will expand this ten-phantom base to a host of pediatric phantoms representative of the public at large. This can provide a means to evaluate and improve pediatric imaging devices and to optimize CT protocols in terms of image quality and radiation dose.

[1]  Alain Trouvé,et al.  Computing Large Deformation Metric Mappings via Geodesic Flows of Diffeomorphisms , 2005, International Journal of Computer Vision.

[2]  W P Segars,et al.  Realistic CT simulation using the 4D XCAT phantom. , 2008, Medical physics.

[3]  Chengyu Shi,et al.  RADAR Reference Adult, Pediatric, and Pregnant Female Phantom Series for Internal and External Dosimetry , 2012, The Journal of Nuclear Medicine.

[4]  Wenjuan Sun,et al.  Construction of boundary-surface-based Chinese female astronaut computational phantom and proton dose estimation , 2012, Journal of radiation research.

[5]  Wesley E Bolch,et al.  Whole-body voxel phantoms of paediatric patients—UF Series B , 2006, Physics in medicine and biology.

[6]  O. Linton,et al.  NCRP REPORT NO. 160, IONIZING RADIATION EXPOSURE OF THE POPULATION OF THE UNITED STATES, MEDICAL EXPOSURE—ARE WE DOING LESS WITH MORE, AND IS THERE A ROLE FOR HEALTH PHYSICISTS? , 2009, Health physics.

[7]  K. P. Kim,et al.  CT Scans in Young People in Great Britain: Temporal and Descriptive Patterns, 1993–2002 , 2012, Radiology research and practice.

[8]  W P Segars,et al.  Realistic reference adult and paediatric phantom series for internal and external dosimetry. , 2012, Radiation protection dosimetry.

[9]  X. Xu,et al.  Deformable adult human phantoms for radiation protection dosimetry: anthropometric data representing size distributions of adult worker populations and software algorithms , 2010, Physics in medicine and biology.

[10]  C Lee,et al.  SU-E-I-44: The UF/NCI Family of Hybrid Computational Phantoms Representing the Current US Population of Male and Female Children and Adolescents Applications to CT Organ Dosimetry. , 2012, Medical physics.

[11]  Wesley E Bolch,et al.  Organ and effective doses in pediatric patients undergoing helical multislice computed tomography examination. , 2007, Medical physics.

[12]  J J DeMarco,et al.  Estimating radiation doses from multidetector CT using Monte Carlo simulations: effects of different size voxelized patient models on magnitudes of organ and effective dose , 2007, Physics in medicine and biology.

[13]  V. Cassola,et al.  Standing adult human phantoms based on 10th, 50th and 90th mass and height percentiles of male and female Caucasian populations , 2011, Physics in medicine and biology.

[14]  Nevzat Karabulut,et al.  Comparison of low-dose and standard-dose helical CT in the evaluation of pulmonary nodules , 2002, European Radiology.

[15]  W. Segars,et al.  4D XCAT phantom for multimodality imaging research. , 2010, Medical physics.

[16]  M Caon,et al.  An EGS4-ready tomographic computational model of a 14-year-old female torso for calculating organ doses from CT examinations. , 1999, Physics in medicine and biology.

[17]  Martin Caon,et al.  Monte Carlo Calculated Effective Dose to Teenage Girls from Computed Tomography Examinations , 2000 .

[18]  W P Segars,et al.  Population of anatomically variable 4D XCAT adult phantoms for imaging research and optimization. , 2013, Medical physics.

[19]  D. Brenner,et al.  Estimated risks of radiation-induced fatal cancer from pediatric CT. , 2001, AJR. American journal of roentgenology.

[20]  J Farah,et al.  Construction of an extended library of adult male 3D models: rationale and results , 2011, Physics in medicine and biology.

[21]  Daniel Lodwick,et al.  Hybrid computational phantoms of the 15-year male and female adolescent: applications to CT organ dosimetry for patients of variable morphometry. , 2008, Medical physics.

[22]  Martin Caon,et al.  Voxel-based computational models of real human anatomy: a review , 2004, Radiation and Environmental Biophysics.

[23]  Daniel Lodwick,et al.  The UF family of reference hybrid phantoms for computational radiation dosimetry , 2010, Physics in medicine and biology.

[24]  Chengyu Shi,et al.  A boundary-representation method for designing whole-body radiation dosimetry models: pregnant females at the ends of three gestational periods—RPI-P3, -P6 and -P9 , 2007, Physics in medicine and biology.

[25]  J. Mathews,et al.  Cancer risk in 680 000 people exposed to computed tomography scans in childhood or adolescence: data linkage study of 11 million Australians , 2013, BMJ.

[26]  A. Bozkurt,et al.  VIP-MAN: AN IMAGE-BASED WHOLE-BODY ADULT MALE MODEL CONSTRUCTED FROM COLOR PHOTOGRAPHS OF THE VISIBLE HUMAN PROJECT FOR MULTI-PARTICLE MONTE CARLO CALCULATIONS , 2000, Health physics.

[27]  D R Dance,et al.  CT dosimetry: getting the best from the adult Cristy phantom. , 2005, Radiation protection dosimetry.

[28]  J. Valentin Basic anatomical and physiological data for use in radiological protection: reference values , 2002, Annals of the ICRP.