The UF series of tomographic computational phantoms of pediatric patients.

Two classes of anthropomorphic computational phantoms exist for use in Monte Carlo radiation transport simulations: tomographic voxel phantoms based upon three-dimensional (3D) medical images, and stylized mathematical phantoms based upon 3D surface equations for internal organ definition. Tomographic phantoms have shown distinct advantages over the stylized phantoms regarding their similarity to real human anatomy. However, while a number of adult tomographic phantoms have been developed since the early 1990s, very few pediatric tomographic phantoms are presently available to support dosimetry in pediatric diagnostic and therapy examinations. As part of a larger effort to construct a series of tomographic phantoms of pediatric patients, five phantoms of different ages (9-month male, 4-year female, 8-year female, 11-year male, and 14-year male) have been constructed from computed tomography (CT) image data of live patients using an IDL-based image segmentation tool. Lungs, bones, and adipose tissue were automatically segmented through use of window leveling of the original CT numbers. Additional organs were segmented either semiautomatically or manually with the aid of both anatomical knowledge and available image-processing techniques. Layers of skin were created by adding voxels along the exterior contour of the bodies. The phantoms were created from fused images taken from head and chest-abdomen-pelvis CT exams of the same individuals (9-month and 4-year phantoms) or of two different individuals of the same sex and similar age (8-year, 11-year, and 14-year phantoms). For each model, the resolution and slice positions of the image sets were adjusted based upon their anatomical coverage and then fused to a single head-torso image set. The resolutions of the phantoms for the 9-month, 4-year, 8-year, 11-year, and 14-year are 0.43 x 0.43 x 3.0 mm, 0.45 x 0.45 x 5.0 mm, 0.58 x 0.58 x 6.0 mm, 0.47 X 0.47 x 6.00 mm, and 0.625 x 0.625 x 6.0 mm, respectively. While organ masses can be matched to reference values in both stylized and tomographic phantoms, side-by-side comparisons of organ doses in both phantom classes indicate that organ shape and positioning are equally important parameters to consider in accurate determinations of organ absorbed dose from external photon irradiation. Preliminary studies of external photon irradiation of the 11-year phantom indicate significant departures of organ dose coefficients from that predicted by the existing stylized phantom series. Notable differences between pediatric stylized and tomographic phantoms include anterior-posterior (AP) and right lateral (RLAT) irradiation of the stomach wall, left lateral (LLAT) and right lateral (RLAT) irradiation of the thyroid, and AP and posterior-anterior (PA) irradiation of the urinary bladder.

[1]  M Zankl,et al.  Construction of a computed tomographic phantom for a Japanese male adult and dose calculation system , 2001, Radiation and environmental biophysics.

[2]  M G Stabin,et al.  MIRDOSE: personal computer software for internal dose assessment in nuclear medicine. , 1996, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[3]  George Sgouros,et al.  MIRD Pamphlet No 19: absorbed fractions and radionuclide S values for six age-dependent multiregion models of the kidney. , 2003, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[4]  W E Bolch,et al.  A comparison of newborn stylized and tomographic models for dose assessment in paediatric radiology. , 2003, Physics in medicine and biology.

[5]  Nina Petoussi-Henss,et al.  The GSF family of voxel phantoms , 2002, Physics in medicine and biology.

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

[7]  X. Xu,et al.  Conversion coefficients based on the VIP-Man anatomical model and EGS4. , 2001, Health physics.

[8]  P. Dimbylow FDTD calculations of the whole-body averaged SAR in an anatomically realistic voxel model of the human body from 1 MHz to 1 GHz. , 1997, Physics in medicine and biology.

[9]  N Petoussi-Henss,et al.  Organ dose conversion coefficients for external photon irradiation of male and female voxel models , 2002, Physics in medicine and biology.

[10]  M. Zankl,et al.  Computational Models Employed for Dose Assessment in Diagnostic Radiology , 1993 .

[12]  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.

[13]  W E Bolch,et al.  Surface area overestimation within three-dimensional digital images and its consequence for skeletal dosimetry. , 2002, Medical physics.

[14]  W. Bolch,et al.  A video analysis technique for organ dose assessment in pediatric fluoroscopy: applications to voiding cystourethrograms (VCUG). , 2003, Medical physics.

[15]  W E Bolch,et al.  Creation of two tomographic voxel models of paediatric patients in the first year of life. , 2002, Physics in medicine and biology.

[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]  James A. Scott Photon, Electron, Proton and Neutron Interaction Data for Body Tissues ICRU Report 46. International Commission on Radiation Units and Measurements, Bethesda, 1992, $40.00 , 1993 .

[18]  P B Hoffer,et al.  Computerized three-dimensional segmented human anatomy. , 1994, Medical physics.

[19]  G Drexler,et al.  The construction of computer tomographic phantoms and their application in radiology and radiation protection , 1988, Radiation and environmental biophysics.

[20]  T. Beck,et al.  Handbook of selected organ doses for projections common in diagnostic radiology , 1979 .

[21]  D. G. Jones A Realistic Anthrompomorphic Phantom for Calculating Specific Absorbed Fractions of Energy Deposited from Internal Gamma Emitters , 1998 .

[22]  Choonsik Lee,et al.  The effect of unrealistic thyroid vertical position on thyroid dose in the MIRD phantom. , 2004, Medical physics.

[23]  W E Bolch,et al.  Tissue-equivalent materials for construction of tomographic dosimetry phantoms in pediatric radiology. , 2003, Medical physics.

[24]  J. W. Vieira,et al.  All about FAX: a Female Adult voXel phantom for Monte Carlo calculation in radiation protection dosimetry. , 2003, Physics in medicine and biology.

[25]  Michael G Stabin,et al.  OLINDA/EXM: the second-generation personal computer software for internal dose assessment in nuclear medicine. , 2005, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.