Program Information
BEST IN PHYSICS (JOINT IMAGING-THERAPY) - Modeling Tumor Evolution for Adaptive Radiation Therapy
Y Liu1*, TCY Chan1,2 , CG Lee1 , YB Cho1,3,4 , MK Islam1,3,4 , (1) University of Toronto, Toronto, ON, (2) Techna Institute for the Advancement of Technology for Health, (3) Princess Margaret Hospital, Toronto, ON, (4) Ontario Consortium for Adaptive Interventions in Radiation Oncology (OCAIRO).
Presentations
TH-A-BRF-2 Thursday 7:30AM - 9:30AM Room: Ballroom FPurpose: To develop mathematical models of tumor geometry changes under radiotherapy that may support future adaptive paradigms.
Methods: A total of 29 cervical patients were scanned using MRI, once for planning and weekly thereafter for treatment monitoring. Using the tumor volumes contoured by a radiologist, three mathematical models were investigated based on the assumption of a stochastic process of tumor evolution. The "weekly MRI" model predicts tumor geometry for the following week from the last two consecutive MRI scans, based on the voxel transition probability. The other two models use only the first pair of consecutive MRI scans, and the transition probabilities were estimated via tumor type classified from the entire data set. The classification is based on either measuring the tumor volume (the "weekly volume" model), or implementing an auxiliary "Markov chain" model. These models were compared to a constant volume approach that represents the current clinical practice, using various model parameters; e.g., the threshold probability β converts the probability map into a tumor shape (larger threshold implies smaller tumor). Model performance was measured using volume conformity index (VCI), i.e., the union of the actual target and modeled target volume squared divided by product of these two volumes.
Results: The "weekly MRI" model outperforms the constant volume model by 26% on average, and by 103% for the worst 10% of cases in terms of VCI under a wide range of β. The "weekly volume" and "Markov chain" models outperform the constant volume model by 20% and 16% on average, respectively. They also perform better than the "weekly MRI" model when β is large.
Conclusion: It has been demonstrated that mathematical models can be developed to predict tumor geometry changes for cervical cancer undergoing radiotherapy. The models can potentially support adaptive radiotherapy paradigm by reducing normal tissue dose.
Funding Support, Disclosures, and Conflict of Interest: This research was supported in part by the Ontario Consortium for Adaptive Interventions in Radiation Oncology (OCAIRO) funded by the Ontario Research Fund (ORF) and the MITACS Accelerate Internship Program. Purpose: To develop mathematical models of tumor geometry changes under radiotherapy that may support future adaptive paradigms.
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