The self-supervised fitting method based on similar neighborhood information of voxels for intravoxel incoherent motion diffusion-weighted MRI.

Medical physics Pub Date : 2025-04-14 DOI:10.1002/mp.17825

Lingfeng Luo, Chen Ye, Tianxian Li, Ming Zhong, Lihui Wang, Yuemin Zhu

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引用次数: 0

Abstract

Background: The intravoxel incoherent motion (IVIM) parameter estimation is affected by noise, while existing CNN-based fitting methods utilize neighborhood spatial features around voxels to obtain more robust parameters. However, due to the heterogeneity of tissue, neighborhood features with low similarity can lead to excessively smooth parameter maps and even loss of tissue details.

Purpose: To propose a novel neural network fitting approach, IVIM-CNN_similar, which utilizes similar neighborhood information of voxels to assist in the estimation of IVIM parameters in diffusion-weighted imaging (DWI).

Methods: The proposed fitting model is based on convolutional neural network (CNN), which first identifies the similar neighborhoods of voxels through cluster analysis and then uses CNN to learn the spatial features of similar neighborhoods to reduce the impact of noise on the parameter estimation of the voxel. To evaluate the performance of the proposed method, comparisons were conducted with the least squares (LSQ), Bayesian, PI-DNN, and IVIM-CNN_unet algorithms on both simulated and in vivo brains, including 23 healthy brains and three brain tumors, in terms of root mean square error (RMSE) of IVIM parameters and the parameter contrast ratio between the tumor and normal regions.

Results: The CNN-based methods, such as IVIM-CNN_similar and IVIM-CNN_unet, yield smoother parameter maps compared to voxel-based methods like nonlinear least squares, segmented nonlinear least squares, Bayesian, and PI-DNN. Additionally, the IVIM-CNN_similar retains more local tissue details while maintaining smoothness of parameter maps compared to the IVIM-CNN_unet. In simulated experiments, IVIM-CNN_similar outperforms IVIM-CNN_unet in terms of parameter estimation accuracy (SNR = 30; RMSE [ $D$ ] = 0.0168 vs. 0.0253; RMSE ( $F$ ) = 0.0001 vs. 0.0002; RMSE [ $D^{*}$ ] = 0.0266 vs. 0.0416). In addition, compared with other methods, the proposed IVIM-CNN_similar is more robust to noise, which is reflected in the lower RMSE of each parameter at different SNRs. For in vivo brains, compared to other methods, IVIM-CNN_similar achieved the highest PCR for most parameters when comparing the normal and tumor regions.

Conclusions: The IVIM-CNN_similar method uses similar neighborhood information to assist IVIM parameter fitting by reducing the impact of noise on voxel parameter estimation, thereby improving the accuracy of parameter estimation and increasing the potential for IVIM clinical application.

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基于体素相似邻域信息的体素内非相干运动扩散加权MRI自监督拟合方法。

背景：体素内非相干运动（IVIM）参数估计受到噪声的影响，而现有的基于cnn的拟合方法利用体素周围的邻域空间特征来获得更鲁棒的参数。然而，由于组织的异质性，低相似性的邻域特征会导致参数图过于光滑，甚至丢失组织细节。目的：提出一种新的神经网络拟合方法——IVIM- cnnsimilar，该方法利用体素的相似邻域信息来辅助扩散加权成像（DWI）中IVIM参数的估计。方法：提出的拟合模型基于卷积神经网络（CNN），首先通过聚类分析识别体素的相似邻域，然后利用CNN学习相似邻域的空间特征，减少噪声对体素参数估计的影响。为了评价该方法的性能，在模拟和活体大脑上，包括23个健康大脑和3个脑肿瘤，在IVIM参数的均方根误差（RMSE）和肿瘤与正常区域的参数对比度方面，与最小二乘（LSQ）、贝叶斯、PI-DNN和IVIM- cnnunet算法进行了比较。结果：与非线性最小二乘、分段非线性最小二乘、贝叶斯和PI-DNN等基于体素的方法相比，基于cnn的方法（如IVIM-CNNsimilar和IVIM-CNNunet）产生的参数映射更平滑。此外，与IVIM-CNNunet相比，IVIM-CNNsimilar保留了更多的局部组织细节，同时保持了参数图的平滑性。在模拟实验中，IVIM-CNNsimilar在参数估计精度上优于IVIM-CNNunet(信噪比= 30；RMSE [D$ D$] = 0.0168 vs. 0.0253；RMSE (F$ F$) = 0.0001 vs. 0.0002；RMSE [D * $D^{*}$] = 0.0266 vs. 0.0416)。此外，与其他方法相比，本文提出的ivim - cnnsimilarity对噪声具有更强的鲁棒性，体现在不同信噪比下各参数的RMSE较低。对于活体脑，与其他方法相比，在比较正常和肿瘤区域时，IVIM-CNNsimilar在大多数参数上获得了最高的PCR。结论：IVIM- cnn相似方法利用相似邻域信息辅助IVIM参数拟合，减少噪声对体素参数估计的影响，从而提高参数估计的准确性，增加IVIM临床应用的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Medical physics

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