Your search keyword '"Guo, Jiefeng"' showing total 2 results

1. A plug-and-play synthetic data deep learning for undersampled magnetic resonance image reconstruction

Author

Xiao, Min, Wang, Zi, Guo, Jiefeng, Qu, Xiaobo, Xiao, Min, Wang, Zi, Guo, Jiefeng, and Qu, Xiaobo

Abstract

Magnetic resonance imaging (MRI) plays an important role in modern medical diagnostic but suffers from prolonged scan time. Current deep learning methods for undersampled MRI reconstruction exhibit good performance in image de-aliasing which can be tailored to the specific k-space undersampling scenario. But it is very troublesome to configure different deep networks when the sampling setting changes. In this work, we propose a deep plug-and-play method for undersampled MRI reconstruction, which effectively adapts to different sampling settings. Specifically, the image de-aliasing prior is first learned by a deep denoiser trained to remove general white Gaussian noise from synthetic data. Then the learned deep denoiser is plugged into an iterative algorithm for image reconstruction. Results on in vivo data demonstrate that the proposed method provides nice and robust accelerated image reconstruction performance under different undersampling patterns and sampling rates, both visually and quantitatively., Comment: 5 pages, 3 figures

Published

2023

2. One for Multiple: Physics-informed Synthetic Data Boosts Generalizable Deep Learning for Fast MRI Reconstruction

Author

Wang, Zi, Yu, Xiaotong, Wang, Chengyan, Chen, Weibo, Wang, Jiazheng, Chu, Ying-Hua, Sun, Hongwei, Li, Rushuai, Li, Peiyong, Yang, Fan, Han, Haiwei, Kang, Taishan, Lin, Jianzhong, Yang, Chen, Chang, Shufu, Shi, Zhang, Hua, Sha, Li, Yan, Hu, Juan, Zhu, Liuhong, Zhou, Jianjun, Lin, Meijing, Guo, Jiefeng, Cai, Congbo, Chen, Zhong, Guo, Di, Yang, Guang, Qu, Xiaobo, Wang, Zi, Yu, Xiaotong, Wang, Chengyan, Chen, Weibo, Wang, Jiazheng, Chu, Ying-Hua, Sun, Hongwei, Li, Rushuai, Li, Peiyong, Yang, Fan, Han, Haiwei, Kang, Taishan, Lin, Jianzhong, Yang, Chen, Chang, Shufu, Shi, Zhang, Hua, Sha, Li, Yan, Hu, Juan, Zhu, Liuhong, Zhou, Jianjun, Lin, Meijing, Guo, Jiefeng, Cai, Congbo, Chen, Zhong, Guo, Di, Yang, Guang, and Qu, Xiaobo

Abstract

Magnetic resonance imaging (MRI) is a widely used radiological modality renowned for its radiation-free, comprehensive insights into the human body, facilitating medical diagnoses. However, the drawback of prolonged scan times hinders its accessibility. The k-space undersampling offers a solution, yet the resultant artifacts necessitate meticulous removal during image reconstruction. Although Deep Learning (DL) has proven effective for fast MRI image reconstruction, its broader applicability across various imaging scenarios has been constrained. Challenges include the high cost and privacy restrictions associated with acquiring large-scale, diverse training data, coupled with the inherent difficulty of addressing mismatches between training and target data in existing DL methodologies. Here, we present a novel Physics-Informed Synthetic data learning framework for Fast MRI, called PISF. PISF marks a breakthrough by enabling generalized DL for multi-scenario MRI reconstruction through a single trained model. Our approach separates the reconstruction of a 2D image into many 1D basic problems, commencing with 1D data synthesis to facilitate generalization. We demonstrate that training DL models on synthetic data, coupled with enhanced learning techniques, yields in vivo MRI reconstructions comparable to or surpassing those of models trained on matched realistic datasets, reducing the reliance on real-world MRI data by up to 96%. Additionally, PISF exhibits remarkable generalizability across multiple vendors and imaging centers. Its adaptability to diverse patient populations has been validated through evaluations by ten experienced medical professionals. PISF presents a feasible and cost-effective way to significantly boost the widespread adoption of DL in various fast MRI applications., Comment: 38 pages, 19 figures, 5 tables

Published

2023