Please use this identifier to cite or link to this item: doi:10.22028/D291-48146
Title: Machine Learning Prediction of Excess Relative Risk for Radiation-Induced Solid Thyroid Cancer Among Nuclear Medicine Healthcare Professionals: A Computational Modeling Study
Author(s): Chouchen, Mariem
Barki, Chamseddine
Dergaa, Ismail
Ceylan, Halil İbrahim
de Giorgio, Andrea
Bragazzi, Nicola Luigi
Rahmouni, Hanene Boussi
Language: English
Title: Bioengineering
Volume: 13
Issue: 6
Publisher/Platform: MDPI
Year of Publication: 2026
Free key words: absorbed dose
computational modeling
decision tree
excess relative risk
I-131 exposure
machine learning
multilayer perceptron
nuclear medicine
occupational exposure
random forest
thyroid cancer
DDC notations: 500 Science
Publikation type: Journal Article
Abstract: Background: Nuclear medicine healthcare professionals (NMHP) sustain chronic occupational exposure to iodine-131 (I-131), conferring an elevated risk of radiation-induced solid thyroid cancer. Established radiobiological prediction tools derive risk coefficients from atomic bomb survivor data but are not configured for rapid individualized risk assessment in occupational exposure settings. This study examined whether machine learning algorithms can serve as high-precision computational surrogates for excess relative risk estimation in NMHP. Aim: The study aimed to (i) develop and validate three machine learning algorithms for predicting the excess relative risk per unit absorbed dose for radiation-induced solid thyroid cancer (ERR/Gy.RST), (ii) characterize relationships between dosimetric and demographic features and predicted risk, and (iii) identify the optimal algorithm for deployment in occupational health surveillance. Methods: A dataset of 4657 observations was constructed from Life Span Study-derived ERR/Gy parameters, adapted to occupational low-dose conditions, using a dose-and-dose-rate effectiveness factor of 2.0, per ICRP Publication 103. Five features (gender, age at exposure, current age, distance from the I-131 source, and cumulative absorbed dose in the thyroid) were used to train a decision tree regressor (dtcr), a random forest regressor (rfr), and a multilayer perceptron (MLP) neural network algorithm. Results: Cumulative absorbed dose in the thyroid correlated positively with ERR/Gy.RST (r = 0.63, p < 0.01), while radiation source distance demonstrated a strong inverse association (r = −0.38, p < 0.01). The MLP algorithm achieved R2 score = 0.999, MSE = 0.002, and MAE = 0.010, substantially outperforming the rfr (R2 score = 0.700, MSE = 0.410, MAE = 0.295) and the dtcr (R2 score = 0.510, MSE = 0.654, MAE = 0.289). Conclusions: The MLP algorithm provides a high-fidelity surrogate for established ERR/Gy.RST projection tools in the NMHP context, enabling computationally efficient, feature-integrated occupational radiation-induced thyroid cancer risk quantification. These findings suggest that machine learning-based surrogate modeling is a practical, scalable complement for occupational health practitioners and radiation protection officers to support individualized surveillance of radiation-induced thyroid cancer risk in nuclear medicine departments.
DOI of the first publication: 10.3390/bioengineering13060696
URL of the first publication: https://doi.org/10.3390/bioengineering13060696
Link to this record: urn:nbn:de:bsz:291--ds-481466
hdl:20.500.11880/42108
http://dx.doi.org/10.22028/D291-48146
ISSN: 2306-5354
Date of registration: 29-Jun-2026
Faculty: NT - Naturwissenschaftlich- Technische Fakultät
Department: NT - Pharmazie
Professorship: NT - Prof. Dr. Thorsten Lehr
Collections:SciDok - Der Wissenschaftsserver der Universität des Saarlandes

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