DYNAMIC IMAGING USING DEEP BILINEAR UNSUPERVISED LEARNING (DEBLUR).

Proceedings. IEEE International Symposium on Biomedical Imaging Pub Date : 2021-04-01 Epub Date: 2021-05-25 DOI:10.1109/isbi48211.2021.9433882

Abdul Haseeb Ahmed, Prashant Nagpal, Stanley Kruger, Mathews Jacob

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引用次数: 4

Abstract

Bilinear models such as low-rank and compressed sensing, which decompose the dynamic data to spatial and temporal factors, are powerful and memory efficient tools for the recovery of dynamic MRI data. These methods rely on sparsity and energy compaction priors on the factors to regularize the recovery. Motivated by deep image prior, we introduce a novel bilinear model, whose factors are regularized using convolutional neural networks. To reduce the run time, we initialize the CNN parameters by pre-training them on pre-acquired data with longer acquistion time. Since fully sampled data is not available, pretraining is performed on undersampled data in an unsupervised fashion. We use sparsity regularization of the network parameters to minimize the overfitting of the network to measurement noise. Our experiments on on free-breathing and ungated cardiac CINE data acquired using a navigated golden-angle gradient-echo radial sequence show the ability of our method to provide reduced spatial blurring as compared to low-rank and SToRM reconstructions.

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使用深度双线性无监督学习(去模糊)的动态成像。

低秩压缩感知等双线性模型将动态数据分解为空间因子和时间因子，是恢复动态MRI数据的有效工具。这些方法依赖于稀疏性和能量压实先验因素来规范采收率。在深度图像先验的激励下，我们引入了一种新的双线性模型，并利用卷积神经网络对其因素进行正则化。为了减少运行时间，我们通过在较长采集时间的预采集数据上进行预训练来初始化CNN参数。由于没有完全采样的数据，所以以无监督的方式对欠采样数据进行预训练。我们使用网络参数的稀疏正则化来最小化网络对测量噪声的过拟合。我们对使用导航黄金角梯度回波径向序列获得的自由呼吸和非门控心脏CINE数据进行的实验表明，与低秩和SToRM重建相比，我们的方法能够提供更少的空间模糊。

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Proceedings. IEEE International Symposium on Biomedical Imaging

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