Inpainting the metal artifact region in MRI images by using generative adversarial networks with gated convolution

Purpose Magnetic resonance imaging (MRI) plays an important role in clinical diagnosis, but it is susceptible to metal artifacts. The generative adversarial network GatedConv with gated convolution (GC) and contextual attention (CA) was used to inpaint the metal artifact region in MRI images. Method...

Full description

Saved in:
Bibliographic Details
Published in:Medical physics (Lancaster) 2022-10, Vol.49 (10), p.6424-6438
Main Authors: Xie, Kai, Gao, Liugang, Lu, Zhengda, Li, Chunying, Xi, Qianyi, Zhang, Fan, Sun, Jiawei, Lin, Tao, Sui, Jianfeng, Ni, Xinye
Format: Article
Language:English
Subjects:
gated convolution
generative adversarial network
image inpainting
metal artifact
MRI
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Purpose Magnetic resonance imaging (MRI) plays an important role in clinical diagnosis, but it is susceptible to metal artifacts. The generative adversarial network GatedConv with gated convolution (GC) and contextual attention (CA) was used to inpaint the metal artifact region in MRI images. Methods MRI images containing or near the teeth of 70 patients were collected, and the scanning sequence was a T1‐weighted high‐resolution isotropic volume examination sequence. A total of 10 000 slices were obtained after data enhancement, of which 8000 slices were used for training. MRI images were normalized to [−1,1]. Based on the randomly generated mask, U‐Net, pix2pix, PConv with partial convolution, and GatedConv were used to inpaint the artifact region of MRI images. The mean absolute error (MAE) and peak signal‐to‐noise ratio (PSNR) for the mask were used to compare the results of these methods. The inpainting effect on the test dataset using dental masks was also evaluated. Besides, the artifact area of clinical MRI images was inpainted based on the mask sketched by physicians. Finally, the earring artifacts and artifacts caused by abnormal signal foci were inpainted to verify the generalization of the models. Results GatedConv could directly and effectively inpaint the incomplete MRI images generated by masks in the image domain. For the results of U‐Net, pix2pix, PConv, and GatedConv, the masked MAEs were 0.1638, 0.1812, 0.1688, and 0.1596, respectively, and the masked PSNRs were 18.2136, 17.5692, 18.2258, and 18.3035 dB, respectively. Using dental masks, the results of U‐Net, pix2pix, and PConv differed more from the real images in terms of alveolar shape and surrounding tissue compared with GatedConv. GatedConv could inpaint the metal artifact region in clinical MRI images more effectively than the other models, but the increase in the mask area could reduce the inpainting effect. Inpainted MRI images by GatedConv and CT images with metal artifact reduction coincided with alveolar and tissue structure, and GatedConv could successfully inpaint artifacts caused by abnormal signal foci, whereas the other models failed. The ablation study demonstrated that GC and CA increased the reliability of the inpainting performance of GatedConv. Conclusion MRI images are affected by metal, and signal void areas appear near metal. GatedConv can inpaint the MRI metal artifact region in the image domain directly and effectively and improve image quality. Medical image inp
ISSN:0094-2405
2473-4209
DOI:10.1002/mp.15931