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It is not uncommon for complete drug pharmacokinetic profiles to remain elusive in pharmacokinetics. This necessitates certain educated assumptions by pharmacokineticists to determine appropriate dosage regimens without comprehensive pharmacokinetic data from animal or human studies. One prevalent assumption is setting the bioavailability factor, denoted as F, to 1 or 100%. This assumption caters to the scenario where a drug doesn't achieve full systemic absorption, resulting in the patient...
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Federated learning (FL) enables collaborative training of deep learning models for dose prediction without sharing patient data. FL outperforms individual training and matches centralized training under ideal conditions, showing promise for medical data collaboration.

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Area of Science:

  • Medical Physics
  • Artificial Intelligence
  • Radiotherapy

Background:

  • Dose prediction is crucial for knowledge-based planning (KBP) in radiotherapy.
  • Deep learning methods require large datasets, necessitating data sharing.
  • Federated learning (FL) offers a privacy-preserving approach for collaborative model training.

Purpose of the Study:

  • To evaluate the performance of federated learning (FL) for deep learning-based dose prediction.
  • To compare FL against centralized and individual training strategies.
  • To assess the impact of data distribution (IID vs. non-IID) on FL performance.

Main Methods:

  • Developed the FedKBP framework to train dose prediction models.
  • Simulated FL and individual training using 8 sites from the OpenKBP dataset.
  • Implemented Independent and Identically Distributed (IID) and non-IID data distributions to test model robustness.

Main Results:

  • FL consistently outperformed individual training in speed and accuracy.
  • FL achieved performance comparable to centralized training under IID conditions.
  • Non-IID data distribution led to performance disparities, with larger sites outperforming smaller ones by up to 19%.

Conclusions:

  • Federated learning is a viable, privacy-preserving alternative to centralized training for dose prediction.
  • Data heterogeneity in FL (non-IID) necessitates advanced methods beyond simple averaging.
  • Collaboration via FL is essential for improving dose prediction accuracy in radiotherapy planning.