通过神经架构搜索联合学习加速磁共振成像的通用重构技术

Ruoyou Wu, Cheng Li, Juan Zou, Xinfeng Liu, Hairong Zheng, Shanshan Wang
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引用次数: 0

摘要

由不同扫描设备和成像协议采集的异构数据会影响深度学习磁共振(MR)重建模型的泛化性能。虽然集中式训练模型能有效缓解这一问题,但它会引发隐私保护方面的担忧。联合学习是一种分布式训练模式,可以利用多机构数据进行协作训练,而无需共享数据。然而,现有的联合学习磁共振图像重建方法依赖于专家手动设计的模型,这些模型复杂且计算成本高,在面对异构数据分布时性能下降。此外,这些方法对公平性问题考虑不足,即确保模型的训练不会对任何特定数据集的分布产生偏差。为此,本文提出了一种可通用的联合神经架构搜索框架,用于加速磁共振成像(GAutoMRI)。具体来说,我们研究了自动神经架构搜索,以便对来自不同中心的磁共振图像进行有效和高效的神经网络表征学习。此外,我们还设计了一种公平性调整方法,使模型能从不同设备和中心的不一致分布中公平地学习特征,从而促进模型对未见中心的良好泛化。大量实验表明,与七种最先进的联合学习方法相比,我们提出的 GAutoMRI 具有更好的性能和泛化能力。此外,GAutoMRI 模型明显更轻便,使其成为磁共振图像重建任务的有效选择。代码将公布在 https://github.com/ternencewu123/GAutoMRI 网站上。
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Generalizable Reconstruction for Accelerating MR Imaging via Federated Learning with Neural Architecture Search.

Heterogeneous data captured by different scanning devices and imaging protocols can affect the generalization performance of the deep learning magnetic resonance (MR) reconstruction model. While a centralized training model is effective in mitigating this problem, it raises concerns about privacy protection. Federated learning is a distributed training paradigm that can utilize multi-institutional data for collaborative training without sharing data. However, existing federated learning MR image reconstruction methods rely on models designed manually by experts, which are complex and computationally expensive, suffering from performance degradation when facing heterogeneous data distributions. In addition, these methods give inadequate consideration to fairness issues, namely ensuring that the model's training does not introduce bias towards any specific dataset's distribution. To this end, this paper proposes a generalizable federated neural architecture search framework for accelerating MR imaging (GAutoMRI). Specifically, automatic neural architecture search is investigated for effective and efficient neural network representation learning of MR images from different centers. Furthermore, we design a fairness adjustment approach that can enable the model to learn features fairly from inconsistent distributions of different devices and centers, and thus facilitate the model to generalize well to the unseen center. Extensive experiments show that our proposed GAutoMRI has better performances and generalization ability compared with seven state-of-the-art federated learning methods. Moreover, the GAutoMRI model is significantly more lightweight, making it an efficient choice for MR image reconstruction tasks. The code will be made available at https://github.com/ternencewu123/GAutoMRI.

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