MIRD Pamphlet No. 28, Part 1: MIRDcalc—A Software Tool for Medical Internal Radiation Dosimetry

Kesner, Adam; Carter, Lukas M.; Ramos, Juan Camilo Ocampo; Lafontaine, Daniel; Olguin, Edmond A.; Brown, Justin; President, Bonnie; Jokisch, Derek W.; Fisher, Darrell R.; Bolch, Wesley E.

doi:10.2967/jnumed.122.264225

Cited by 16 publications

(11 citation statements)

References 39 publications

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“…The calculation of RI for different radiopharmaceuticals, begins with estimates of the organ‐specific absorbed doses. To achieve this, we utilized reference radiopharmaceutical time‐integrated activity coefficients published in ICRP Publication 128 19 as input, calculations were performed using MIRDcalc software, 14 which yielded organs absorbed dose, E , E DW , LAR, and RI as output. The number of source regions used in each calculation was dependent on how the biokinetic data were provided in ICRP publication 128, but typically 4−8.…”

Section: Methodsmentioning

confidence: 99%

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The risk index as a basis for risk/benefit analyses and protocol optimization in diagnostic nuclear imaging

Ocampo Ramos,

Carter,

Brown

et al. 2023

Medical Physics

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BackgroundPotential risk associated with low‐dose radiation exposures is often expressed using the effective dose (E) quantity. Other risk‐related quantities have been proposed as alternatives. The recently introduced risk index (RI) shares similarities with E but expands the metric to incorporate medical imaging‐appropriate risks factors including patient‐specific size, age, and sex.PurposeThe aim of this work is to examine the RI metric for quantifying stochastic radiation risk and demonstrate its applications in nuclear imaging. The advantages in this improved metric may help the field progress toward stratified risk consideration in the course of patient management, improve efforts for procedure optimization, and support an evolution in the science of radiation risk assessment.MethodsIn this study we describe, implement, and calculate RI for various diagnostic nuclear imaging scenarios using reference biokinetics published in ICRP Publication 128 for commonly utilized radiopharmaceuticals. All absorbed dose, E and RI calculations were performed using the freely available MIRDcalc nuclear medicine dosimetry software; the organ specific risk parameters used in the software are also benchmarked in this text. The resulting RI and E values are compared and various trends in RI values identified.ResultsE and RI coefficients were calculated for 3016 use cases. Notably RI values vary depending on patient characteristics. Overall, across the population, global trends in RI values can be identified. In general, RI values were 2.15 times higher for females than males, due to higher risk coefficients and activities being distributed in smaller reference masses. The pediatric patients showed higher RIs than adults, as younger patients generally receive higher absorbed doses per administered activity, and are more radiosensitive, and have a longer projected lifespan at risk. A compendium of E and RI values is also provided in table format to serve as a reference for the community.ConclusionsRI is a rational quantity that could be used for justification, risk communication and protocol optimization in medical imaging. It has some advantages when compared to the long‐utilized E value with respect to personalization, since accounts for patient size, age, sex, and natural incidence of cancer risk.

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Section: Methodsmentioning

confidence: 99%

“…Of note, the RI calculation for radiopharmaceutical applications is integrated into the newly released MIRDcalc nuclear medicine dosimetry software, 14 freely available at http://www.mirdsoft.org (example use cases of RI can be found in the MIRDcalc manual).…”

Section: Introductionmentioning

confidence: 99%

The risk index as a basis for risk/benefit analyses and protocol optimization in diagnostic nuclear imaging

Ocampo Ramos,

Carter,

Brown

et al. 2023

Medical Physics

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“…Earlier studies have shown variations in effective doses due to photons, electron [20] and 18 F-FDG [21] estimated using a voxel-based model from those estimated using stylized phantoms. The UF/NCI and PRC phantoms have been used to compute SAF values for electrons and photons of various energies [22][23][24], which in turn are used to compute S values and organ doses for medical intake scenarios [24,25]. These studies only focus on dose computation for medical protection pathways such as intravenous and oral administration, while leaving out the inhalation pathway required for radiological protection.…”

Section: Introductionmentioning

confidence: 99%

¹³¹I dose coefficients for a reference population using age-specific models

Singh,

Patni,

Roy

et al. 2023

J. Radiol. Prot.

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Age-specific dose coefficients are required to assess internal exposure to the general public. This study utilizes reference age-specific biokinetic models of iodine to estimate total numbers of nuclear disintegrations ã(rS,τ) occurring in source regions (rS) during the commitment time (τ). Age-specific S values are estimated for 35 target regions due to 131I present in 22 rS using 10 paediatric reference computational (PRC) phantoms (representing 5 ages for both sexes) data recently published by International Commission of Radiation Protection (ICRP). Monte Carlo transport simulations are performed in FLUKA code. The estimated ã(rS,τ) and S values are then used to compute committed tissue equivalent dose HT(τ) for 27 radiosensitive tissues and dose coefficients e(τ) for all 5 ages due to inhalation and ingestion of 131I. The derived ã(rS,τ) values in the thyroid source are observed to be increasing with age due to increased retention of iodine in the thyroid. S values are found to be decreasing with age mainly due to increase in target masses. Generally, HT(τ) values are observed to decrease with age, indicating the predominant behaviour of S values over ã(rS,τ) . On an average, ingestion dose coefficients are 63% higher than inhalation for all ages. The maximum contribution to dose coefficients is from thyroid, accounting for 96% in the case of new-born and 98-99% for all other ages. Furthermore, the estimated e(τ) values for the reference public are observed to be lower than previously published values by the ICRP. The estimated S, HT(τ), and e(τ) values can be used to improve the estimation of internal doses to organs/whole body for members of the public in cases of 131I exposure. The estimated dose coefficients can also be interpolated for other ages to accurately evaluate the doses received by the general public during 131I therapy or during a radiological emergency.

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“…TO THE EDITOR: The journal has recently published MIRD pamphlet no. 28, parts 1 and 2, which describe and provide validation for the nuclear medicine software code MIRDcalc, part of the MIRDsoft.org series of freely accessible software for the field of nuclear medicine (1,2). We wish this letter to serve as an addendum clarifying an important technical aspect of the work in regard to some of the graphical presentations of the library of phantom computational models used to generate radionuclide S values, which form the computational engine of organ dosimetry in the MIRDcalc code.…”

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confidence: 99%

Addendum to MIRD Pamphlet No. 28

Kesner¹,

Carter²,

Bolch³

2023

J Nucl Med

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In the article "Multicenter Evaluation of Frequency and Impact of Activity Infiltration in PET Imaging, Including Microscale Modeling of Skin-Absorbed Dose" by Sunderland et al. (J Nucl Med. 2023;64:1095-1101), the legend in Figure 2A mistakenly states units of MBq, whereas kBq are the correct units. Additionally, the y-axis in Figure 3 should read 0.41 MBq rather than 0.83 MBq. The authors regret the errors.

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MIRD Pamphlet No. 28, Part 1: MIRDcalc—A Software Tool for Medical Internal Radiation Dosimetry

Cited by 16 publications

References 39 publications

The risk index as a basis for risk/benefit analyses and protocol optimization in diagnostic nuclear imaging

The risk index as a basis for risk/benefit analyses and protocol optimization in diagnostic nuclear imaging

¹³¹I dose coefficients for a reference population using age-specific models

Addendum to MIRD Pamphlet No. 28

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MIRD Pamphlet No. 28, Part 1: MIRDcalc—A Software Tool for Medical Internal Radiation Dosimetry

Cited by 16 publications

References 39 publications

The risk index as a basis for risk/benefit analyses and protocol optimization in diagnostic nuclear imaging

The risk index as a basis for risk/benefit analyses and protocol optimization in diagnostic nuclear imaging

131I dose coefficients for a reference population using age-specific models

Addendum to MIRD Pamphlet No. 28

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¹³¹I dose coefficients for a reference population using age-specific models