使用深度 CNN-Transformer 模型从小鼠加速的径向 k 空间弥散加权 MRI 中学习 ADC 图。

Learning ADC maps from accelerated radial k-space diffusion-weighted MRI in mice using a deep CNN-transformer model.

机构信息

Center for Biomedical Image Computing and Analytics (CBICA), Perelman School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania, USA.

Department of Radiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania, USA.

出版信息

Magn Reson Med. 2024 Jan;91(1):105-117. doi: 10.1002/mrm.29833. Epub 2023 Aug 20.

DOI:10.1002/mrm.29833

PMID:37598398

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10691280/

Abstract

PURPOSE

To accelerate radially sampled diffusion weighted spin-echo (Rad-DW-SE) acquisition method for generating high quality ADC maps.

METHODS

A deep learning method was developed to generate accurate ADC maps from accelerated DWI data acquired with the Rad-DW-SE method. The deep learning method integrates convolutional neural networks (CNNs) with vision transformers to generate high quality ADC maps from accelerated DWI data, regularized by a monoexponential ADC model fitting term. A model was trained on DWI data of 147 mice and evaluated on DWI data of 36 mice, with acceleration factors of 4× and 8× compared to the original acquisition parameters.

RESULTS

Ablation studies and experimental results have demonstrated that the proposed deep learning model generates higher quality ADC maps from accelerated DWI data than alternative deep learning methods under comparison when their performance is quantified in whole images as well as in regions of interest, including tumors, kidneys, and muscles.

CONCLUSIONS

The deep learning method with integrated CNNs and transformers provides an effective means to accurately compute ADC maps from accelerated DWI data acquired with the Rad-DW-SE method.

摘要

目的

加速径向采样扩散加权回波（Rad-DW-SE）采集方法以生成高质量的 ADC 图。

方法

开发了一种深度学习方法，用于从 Rad-DW-SE 方法获得的加速 DWI 数据中生成准确的 ADC 图。该深度学习方法将卷积神经网络（CNNs）与视觉转换器集成在一起，从加速的 DWI 数据生成高质量的 ADC 图，并通过单指数 ADC 模型拟合项进行正则化。在 147 只小鼠的 DWI 数据上训练了一个模型，并在 36 只小鼠的 DWI 数据上进行了评估，与原始采集参数相比，加速因子分别为 4×和 8×。

结果

消融研究和实验结果表明，与对比的其他深度学习方法相比，所提出的深度学习模型在整个图像以及感兴趣区域（包括肿瘤、肾脏和肌肉）中定量评估时，从加速的 DWI 数据中生成的 ADC 图质量更高。

结论

集成 CNNs 和转换器的深度学习方法为从 Rad-DW-SE 方法获得的加速 DWI 数据准确计算 ADC 图提供了一种有效手段。

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