MOST: MR reconstruction Optimization for multiple downStream Tasks via continual learning

Hwihun Jeong, Se Young Chun, Jongho Lee
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Abstract

Deep learning-based Magnetic Resonance (MR) reconstruction methods have focused on generating high-quality images but they often overlook the impact on downstream tasks (e.g., segmentation) that utilize the reconstructed images. Cascading separately trained reconstruction network and downstream task network has been shown to introduce performance degradation due to error propagation and domain gaps between training datasets. To mitigate this issue, downstream task-oriented reconstruction optimization has been proposed for a single downstream task. Expanding this optimization to multi-task scenarios is not straightforward. In this work, we extended this optimization to sequentially introduced multiple downstream tasks and demonstrated that a single MR reconstruction network can be optimized for multiple downstream tasks by deploying continual learning (MOST). MOST integrated techniques from replay-based continual learning and image-guided loss to overcome catastrophic forgetting. Comparative experiments demonstrated that MOST outperformed a reconstruction network without finetuning, a reconstruction network with na\"ive finetuning, and conventional continual learning methods. This advancement empowers the application of a single MR reconstruction network for multiple downstream tasks. The source code is available at: https://github.com/SNU-LIST/MOST
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MOST:通过持续学习优化多个下行流任务的磁共振重构
基于深度学习的磁共振(MR)重建方法专注于生成高质量图像,但往往忽略了对利用重建图像的下游任务(如分割)的影响。为了缓解这一问题,针对单下游任务提出了面向下游任务的重建优化。将这种优化扩展到多任务场景并非易事。在这项工作中,我们将这一优化扩展到连续引入的多个下游任务,并证明通过部署持续学习(MOST),可以针对多个下游任务优化单个磁共振重建网络。MOST 整合了基于回放的持续学习和图像引导损失技术,以克服灾难性遗忘。对比实验表明,MOST的性能优于不带微调的重建网络、带微调的重建网络和传统的持续学习方法。这一进步有助于将单一的磁共振重建网络应用于多个下游任务。源代码见:https://github.com/SNU-LIST/MOST
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