The UF family of hybrid phantoms of the developing human fetus for computational radiation dosimetry

Maynard, Matthew; Geyer, J; Aris, John P.; Shifrin, Roger Y.; Bolch, Wesley E.

doi:10.1088/0031-9155/56/15/014

Cited by 32 publications

(23 citation statements)

References 24 publications

(64 reference statements)

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“…Elemental compositions of fetal soft tissues were adopted from a combination of relevant literature sources (ICRP 2002;ICRU 1992). Mass densities of fetal soft tissues were adopted from Maynard et al (2011). Elemental compositions of fetal bone were derived through linear interpolating of the 38-week cranium and lumbar vertebrae elemental compositions reported by Pafundi et al (2009) and the ICRU reference adult cartilage elemental composition (ICRU 1992).…”

Section: Phantom Geometrymentioning

confidence: 99%

“…Elemental compositions of fetal bone were derived through linear interpolating of the 38-week cranium and lumbar vertebrae elemental compositions reported by Pafundi et al (2009) and the ICRU reference adult cartilage elemental composition (ICRU 1992). Mass densities of fetal bone (spongiosa) were linearly interpolated as needed from values given by Maynard et al (2011). Elemental compositions of maternal tissues were assumed to be equivalent to the blood-inclusive elemental compositions of the UF adult non-pregnant female phantom derived by Wayson (2012).…”

Section: Phantom Geometrymentioning

confidence: 99%

See 1 more Smart Citation

Fetal organ dosimetry for the Techa River and Ozyorsk Offspring Cohorts, part 2: radionuclide S values for fetal self-dose and maternal cross-dose

Maynard

Shagina

Толстых

et al. 2014

Radiat Environ Biophys

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One of the many objectives of the European Union's SOLO (Epidemiological Studies of Exposed Southern Urals Populations) project is to quantify the radiation dose-response following chronic in utero exposures to ionizing radiation. The project is presently conducting a pooled analysis of two cohorts of individuals born to exposed mothers-the Techa River Offspring Cohort (TROC) and the Ozyorsk Offspring Cohort (OOC). The TROC includes the offspring of mothers with external exposures to contaminated riverbanks and internal ingestions of (89)Sr, (90)Sr/(90)Y, and (137)Cs/(137m)Ba, while the OOC includes the offspring of mothers with external exposures seen within the Mayak plutonium production facilities and internal inhalation of (239)Pu and possibly (131)I. In the present study, a newly created Urals-based series of fetal and maternal models is employed to assess S values for all seven radionuclides. Among all fetal ages, S values ranged in magnitude from 10(-14) to 10(-10) Gy per Bq-s for fetal source organs and from 10(-18) to 10(-14) Gy per Bq-s from maternal source organs, depending upon particle type, particle energy, and fetal age. For a given radionuclide and fetal age, S values for fetal source organs were approximately two orders of magnitude higher than for maternal source organs. Little variation in S values was observed among fetal source organs, while variations of over 100 % with respect to the mean were observed for maternal source organs near the fetus. S value variations from maternal cross-fire were highly dependent on fetal position and separation distance from the maternal source organ. These radionuclide S values have been coupled with biokinetic models for use in cohort dose assessment within the SOLO project.

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Section: Phantom Geometrymentioning

confidence: 99%

Section: Phantom Geometrymentioning

confidence: 99%

Fetal organ dosimetry for the Techa River and Ozyorsk Offspring Cohorts, part 2: radionuclide S values for fetal self-dose and maternal cross-dose

Maynard

Shagina

Толстых

et al. 2014

Radiat Environ Biophys

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“…The paper by Lee et al [51] was also rated one of the 10 best papers in 2007 by Physics in Medicine and Biology. In 2011, Maynard et al [117] from the UF produced a family of NURBS-based fetal phantoms. The phantoms were based on CT and MR images from fetal specimens of various ages between 10 and 30 weeks and were modified to conform to reference values.…”

Section: Brep Phantoms From 2000s To Presentmentioning

confidence: 99%

Computational Phantoms for Organ Dose Calculations in Radiation Protection and Imaging

2013

The Phantoms of Medical and Health Physics

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Dosimetry for ionizing radiation has to do with the determination of amount and distribution pattern of the energy deposited in a part or parts of the human body from internal or external radiation sources. To protect against occupational exposures, dose limits for radiosensitive organs are recommended by international organizations and are adopted as national regulations. In both diagnostic radiology and nuclear medicine, X-ray photons and gamma rays traverse through body tissues to form images of the anatomy, depositing radiation energy in organs along the pathway via secondary electrons. Accurate radiation dosimetry is essential but also quite challenging for three reasons: (1) there are many diverse exposure scenarios resulting in unique spatial and temporal relationships between the source and human body; (2) an exposure can involve multiple radiation types, each of which is governed by different radiation physics principles, such as photons (X-ray photons, gamma rays, and positrons), electrons, alpha particles, neutrons, and protons; (3) the human body consists of a large number of anatomical structures of diverse shape, composition and density, leading to complex radiation interaction patterns. Since it is inconvenient to place a dosimeter inside the human body, organ dose estimates have been obtained mostly using a physical phantom or a computational phantom that mimics the interior and exterior anatomical features of the human body.Historically, the term phantom was used in most radiological science literature to mean a physical model of the human body. In the radiation protection community, however, the term has also been used to refer to a mathematically defined anatomical model that is distinctly different from a physiologically based model such as that related to respiration or blood flow. In this chapter, the phrases, ''computational phantom'' and ''physical phantom,'' are used to avoid confusion.

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“…More recent methods for estimating radiation conceptus dose from CT exams of pregnant patients are typically based on MC simulations of pregnant patient anatomy representing a range of gestational ages and patient sizes. [14][15][16][17][18][19][20] However, many of these studies were limited in that they were either not based on actual pregnant patient anatomy, applied only to a single scanner model, or did not include a range of gestational ages. In addition, most of these methods have thus far been limited to fixed tube current (FTC) CT exams of pregnant patients.…”

Section: Introductionmentioning

confidence: 99%

Estimating fetal dose from tube current‐modulated (TCM) and fixed tube current (FTC) abdominal/pelvis CT examinations

et al. 2019

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Purpose The purpose of this work was to estimate scanner‐independent CTDIvol‐to‐fetal‐dose coefficients for tube current‐modulated (TCM) and fixed tube current (FTC) computed tomography (CT) examinations of pregnant patients of various gestational ages undergoing abdominal/pelvic CT examinations. Methods For 24 pregnant patients of gestational age from <5 to 36 weeks who underwent clinically indicated CT examinations, voxelized models of maternal and fetal (or embryo) anatomy were created from abdominal/pelvic image data. Absolute fetal dose (Dfetus) was estimated using Monte Carlo (MC) simulations of helical scans covering the abdomen and pelvis for TCM and FTC scans. Estimated TCM schemes were generated for each patient model using a validated method that accounts for patient attenuation and scanner output limits for one scanner model and were incorporated into MC simulations. FTC scans were also simulated for each patient model with multidetector row CT scanners from four manufacturers. Normalized fetal dose estimates, nDfetus, was obtained by dividing Dfetus from the MC simulations by CTDIvol. Patient size was described using water equivalent diameter (Dw) measured at the three‐dimensional geometric centroid of the fetus. Fetal depth (DEf) was measured from the anterior skin surface to the anterior part of the fetus. nDfetus and Dw were correlated using an exponential model to develop equations for fetal dose conversion coefficients for TCM and FTC abdominal/pelvic CT examinations. Additionally, bivariate linear regression was performed to analyze the correlation of nDfetus with Dw and fetal depth (DEf). For one scanner model, nDfetus from TCM was compared to FTC and the size‐specific dose estimate (SSDE) conversion coefficients (f‐factors) from American Association of Physicists in Medicine (AAPM) Report 204. nDfetus from FTC simulations was averaged across all scanners for each patient (nDfetus¯). nDitalicfetus¯ was then compared with SSDE f‐factors and correlated with Dw using an exponential model and with Dw and DEf using a bivariate linear model. Results For TCM, the coefficient of determination (R2) of nDfetus and Dw was observed to be 0.73 using an exponential model. Using the bivariate linear model with Dw and DEf, an R2 of 0.78 was observed. For the TCM technology modeled, TCM yielded nDfetus values that were on average 6% and 17% higher relative to FTC and SSDE f‐factors, respectively. For FTC, the R2 of nDitalicfetus¯ with respect to Dw was observed to be 0.64 using an exponential model. Using the bivariate linear model, an R2 of 0.75 was observed for nDitalicfetus¯ with respect to Dw and DEf. A mean difference of 0.4% was observed between nDitalicfetus¯ and SSDE f‐factors. Conclusion Good correlations were observed for nDfetus from TCM and FTC scans using either an exponential model with Dw or a bivariate linear model with both Dw and DEf. These results indicate that fetal dose from abdomen/pelvis CT examinations of pregnant patients of various gestational ages may be reasonably estimated with mod...

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The UF family of hybrid phantoms of the developing human fetus for computational radiation dosimetry

Cited by 32 publications

References 24 publications

Fetal organ dosimetry for the Techa River and Ozyorsk Offspring Cohorts, part 2: radionuclide S values for fetal self-dose and maternal cross-dose

Fetal organ dosimetry for the Techa River and Ozyorsk Offspring Cohorts, part 2: radionuclide S values for fetal self-dose and maternal cross-dose

Computational Phantoms for Organ Dose Calculations in Radiation Protection and Imaging

Estimating fetal dose from tube current‐modulated (TCM) and fixed tube current (FTC) abdominal/pelvis CT examinations

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