Feasibility study on dose conversion using a deep learning algorithm for retrospective dosimetry

IF 1.6 3区物理与天体物理 Q2 NUCLEAR SCIENCE & TECHNOLOGY

Radiation Measurements Pub Date : 2025-02-01 DOI:10.1016/j.radmeas.2025.107382

Hyoungtaek Kim, Byoungil Jeon, Min Chae Kim, Yoomi Choi

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引用次数: 0

Abstract

The application of deep learning-based artificial intelligence (AI) models for dose estimation has garnered significant attention in dosimetric research, aiming to supplement or replace Monte Carlo (MC) particle transport simulations. The present study explores the feasibility of AI-based dose conversion techniques for retrospective dosimetry in radiological emergencies, particularly focusing on scenarios where a rapid estimation of body dose is required using measured doses from fortuitous dosimeters placed on or near the body during exposure. With the modeling of an International Commission on Radiation Units and Measurements (ICRU) slab phantom (presuming a human body) and glass plates (presuming fortuitous dosimeters), a large amount of dose data was generated through MC simulations with respect to randomly generated point sources (¹⁹²Ir, ¹³⁷Cs, and ⁶⁰Co) within a radius of 3 m from the phantom center. A deep learning (DL) model was trained to estimate doses and dose conversion coefficients (DCCs) between the phantom and the glass plates using the input of exposure structures, i.e. the position and energy of the source. Data scaling, such as logarithmic or power transformations, was essential for the dose data due to its highly biased distribution. The results showed that 98% of the estimated doses had relative differences (RDs) within ±3% when compared to MC simulations. To assess the impact of data volume on performance, datasets of varying sizes (55 k, 108 k, 216 k, and 432 k) were used for training, revealing a strong dependence of model performance on data volume. Outlier reduction methods, such as dose averaging and data reduction near the center, were applied, reducing the max-min RD range by a factor of 3–10. From the results, the potential and necessity of an AI dose estimation model for more complicated geometries, such as those involving anthropomorphic phantoms, were discussed.

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应用深度学习算法进行剂量转换的可行性研究

应用基于深度学习的人工智能（AI）模型进行剂量估计在剂量学研究中得到了广泛关注，旨在补充或取代蒙特卡罗（MC）粒子输运模拟。本研究探讨了基于人工智能的剂量转换技术在放射性紧急情况中用于回顾性剂量测定的可行性，特别侧重于需要使用暴露期间放置在身体上或身体附近的偶然剂量计测量剂量来快速估计人体剂量的情况。通过对国际辐射单位与测量委员会（ICRU）平板幻影（假设人体）和玻璃板（假设偶发剂量计）的建模，通过MC模拟，在距离幻影中心3 m半径范围内随机生成的点源（192Ir、137Cs和60Co）产生了大量剂量数据。利用暴露结构的输入，即源的位置和能量，训练深度学习（DL）模型来估计幻影和玻璃板之间的剂量和剂量转换系数（DCCs）。由于剂量数据的分布高度偏倚，数据缩放（如对数或功率转换）对剂量数据至关重要。结果表明，与MC模拟相比，98%的估计剂量的相对差异（RDs）在±3%以内。为了评估数据量对性能的影响，使用不同大小的数据集（55 k、108 k、216 k和432 k）进行训练，揭示了模型性能对数据量的强烈依赖性。采用离群值减少方法，如剂量平均和中心附近的数据减少，将最大-最小RD范围减少了3-10倍。根据结果，讨论了人工智能剂量估计模型用于更复杂几何形状（如涉及拟人化幻影的几何形状）的潜力和必要性。

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来源期刊

Radiation Measurements 工程技术-核科学技术

CiteScore

4.10

自引率

20.00%

发文量

116

审稿时长

48 days

期刊介绍： The journal seeks to publish papers that present advances in the following areas: spontaneous and stimulated luminescence (including scintillating materials, thermoluminescence, and optically stimulated luminescence); electron spin resonance of natural and synthetic materials; the physics, design and performance of radiation measurements (including computational modelling such as electronic transport simulations); the novel basic aspects of radiation measurement in medical physics. Studies of energy-transfer phenomena, track physics and microdosimetry are also of interest to the journal. Applications relevant to the journal, particularly where they present novel detection techniques, novel analytical approaches or novel materials, include: personal dosimetry (including dosimetric quantities, active/electronic and passive monitoring techniques for photon, neutron and charged-particle exposures); environmental dosimetry (including methodological advances and predictive models related to radon, but generally excluding local survey results of radon where the main aim is to establish the radiation risk to populations); cosmic and high-energy radiation measurements (including dosimetry, space radiation effects, and single event upsets); dosimetry-based archaeological and Quaternary dating; dosimetry-based approaches to thermochronometry; accident and retrospective dosimetry (including activation detectors), and dosimetry and measurements related to medical applications.