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Main Authors: Chen, Jingyun, Horowitz, David, Yuan, Yading
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.14507
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author Chen, Jingyun
Horowitz, David
Yuan, Yading
author_facet Chen, Jingyun
Horowitz, David
Yuan, Yading
contents Background: Deep learning has potential to improve the efficiency and consistency of radiation therapy planning, but clinical adoption is hindered by the limited model generalizability due to data scarcity and heterogeneity among institutions. Although aggregating data from different institutions could alleviate this problem, data sharing is a practical challenge due to concerns about patient data privacy and other technical obstacles. Purpose: This work aims to address this dilemma by developing FedKBP+, a comprehensive federated learning (FL) platform for predictive tasks in real-world applications in radiotherapy treatment planning. Methods: We implemented a unified communication stack based on Google Remote Procedure Call (gRPC) to support communication between participants whether located on the same workstation or distributed across multiple workstations. In addition to supporting the centralized FL strategies commonly available in existing open-source frameworks, FedKBP+ also provides a fully decentralized FL model where participants directly exchange model weights to each other through Peer-to-Peer communication. We evaluated FedKBP+ on three predictive tasks using scale-attention network (SA-Net) as the predictive model. Conclusions: Our results demonstrate that FedKBP+ is highly effective, efficient and robust, showing great potential as a federated learning platform for radiation therapy.
format Preprint
id arxiv_https___arxiv_org_abs_2505_14507
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Federated prediction for scalable and privacy-preserved knowledge-based planning in radiotherapy
Chen, Jingyun
Horowitz, David
Yuan, Yading
Distributed, Parallel, and Cluster Computing
Machine Learning
Medical Physics
Background: Deep learning has potential to improve the efficiency and consistency of radiation therapy planning, but clinical adoption is hindered by the limited model generalizability due to data scarcity and heterogeneity among institutions. Although aggregating data from different institutions could alleviate this problem, data sharing is a practical challenge due to concerns about patient data privacy and other technical obstacles. Purpose: This work aims to address this dilemma by developing FedKBP+, a comprehensive federated learning (FL) platform for predictive tasks in real-world applications in radiotherapy treatment planning. Methods: We implemented a unified communication stack based on Google Remote Procedure Call (gRPC) to support communication between participants whether located on the same workstation or distributed across multiple workstations. In addition to supporting the centralized FL strategies commonly available in existing open-source frameworks, FedKBP+ also provides a fully decentralized FL model where participants directly exchange model weights to each other through Peer-to-Peer communication. We evaluated FedKBP+ on three predictive tasks using scale-attention network (SA-Net) as the predictive model. Conclusions: Our results demonstrate that FedKBP+ is highly effective, efficient and robust, showing great potential as a federated learning platform for radiation therapy.
title Federated prediction for scalable and privacy-preserved knowledge-based planning in radiotherapy
topic Distributed, Parallel, and Cluster Computing
Machine Learning
Medical Physics
url https://arxiv.org/abs/2505.14507