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Privacy-preserving Federated Brain Tumour Segmentation.

Wenqi Li1, Fausto Milletarì1, Daguang Xu1

  • 1NVIDIA.

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Summary
This summary is machine-generated.

Federated learning enables training AI models on private medical data. Differential privacy techniques can protect patient information, but may impact model performance, showing a trade-off between privacy and accuracy in brain tumor segmentation.

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Area of Science:

  • Medical Artificial Intelligence
  • Machine Learning Privacy
  • Neuroimaging Analysis

Background:

  • Medical data privacy regulations hinder centralized data collection for AI model training.
  • Federated learning (FL) addresses this by training models locally and sharing updates, not raw data.
  • However, FL model updates can still inadvertently leak sensitive patient information.

Purpose of the Study:

  • To investigate the feasibility of applying differential privacy (DP) techniques within a federated learning framework.
  • To assess the effectiveness of DP in protecting patient data during federated model training.
  • To evaluate the impact of DP on the performance of AI models for brain tumor segmentation.

Main Methods:

  • Implementation of federated learning systems for brain tumor segmentation.
  • Integration and evaluation of differential privacy mechanisms into the federated learning process.
  • Performance assessment using the BraTS dataset, comparing models with and without DP.

Main Results:

  • Differential privacy can be applied to federated learning setups for medical data.
  • Experimental results demonstrate a clear trade-off between the level of privacy protection and the achieved model performance.
  • The study successfully implemented and evaluated practical systems for privacy-preserving federated learning.

Conclusions:

  • Differential privacy is a viable approach to enhance patient data protection in federated learning for medical applications.
  • Balancing privacy guarantees and model accuracy is crucial when implementing DP in federated learning systems.
  • Further research is needed to optimize this trade-off for clinical utility in neuroimaging.