• PDF / 1,122,638 Bytes
• 8 Pages / 439.363 x 666.131 pts Page_size
• 39 Downloads / 187 Views

DOWNLOAD

REPORT

Department of Radiology and BRIC, University of North Carolina at Chapel Hill, NC 2 Department of Neurology, University of North Carolina at Chapel Hill, NC

Abstract. Advancements in 7T MR imaging bring higher spatial resolution and clearer tissue contrast, in comparison to the conventional 3T and 1.5T MR scanners. However, 7T MRI scanners are less accessible at the current stage due to higher costs. Through analyzing the appearances of 7T images, we could improve both the resolution and quality of 3T images by properly mapping them to 7T-like images; thus, promoting more accurate post-processing tasks, such as segmentation. To achieve this method based on an unique dataset acquired both 3T and 7T images from same subjects, we propose novel multi-level Canonical Correlation Analysis (CCA) method and group sparsity as a hierarchical framework to reconstruct 7T-like MRI from 3T MRI. First, the input 3T MR image is partitioned into a set of overlapping patches. For each patch, the local coupled 3T and 7T dictionaries are constructed by extracting the patches from a neighboring region from all aligned 3T and 7T images in the training set. In the training phase, we have both 3T and 7T MR images scanned from each training subject. Then, these two patch sets are mapped to the same space using multi-level CCA. Next, each input 3T MRI patch is sparsely represented by the 3T dictionary and then the obtained sparse coefficients are utilized to reconstruct the 7T patch with the corresponding 7T dictionary. Group sparsity is further utilized to maintain the consistency between neighboring patches. Such reconstruction is performed hierarchically with adaptive patch size. The experiments were performed on 10 subjects who had both 3T and 7T MR images. Experimental results demonstrate that our proposed method is capable of recovering rich structural details and outperforms other methods, including the sparse representation method and CCA method.

1

Introduction

Magnetic Resonance Imaging (MRI) is a noninvasive method of observing the human body without the use of surgery, harmful dyes or x-rays, making this approach widely used in medical imaging, as using MRIs can help to detect problems at early stages. High resolution MRI is always desirable in research and c Springer International Publishing Switzerland 2015  N. Navab et al. (Eds.): MICCAI 2015, Part II, LNCS 9350, pp. 659–666, 2015. DOI: 10.1007/978-3-319-24571-3_79

660

K. Bahrami et al.

clinical practice, since it has smaller voxel size, which provides greater structural details. In contrast, low-resolution MRI is affected by partial volume effect, in which a voxel captures signals from multiple tissue types, resulting in fuzzy tissue boundaries. The introduction of ultra-high-field MR (7 Tesla (7T)) scanners have allowed for high resolution MRI scanning. In theory, the signal-to-noise ratio (SNR) should be almost linearly related to the magnetic field. For instance, the SNR of 7T should be 2.3 times of the SNR of 3T. Therefore, 7T MRI should provide images with higher reso

Recommend Documents

Generator from Edges: Reconstruction of Facial Images

104 87 149MB

Improving Amide Proton Transfer-Weighted MRI Reconstruction Using T2-Weighted Images

141 27 154MB

Multilevel Synthesis From the Group to the Individual

137 43 5MB

Fast Reconstruction of Accelerated Dynamic MRI Using Manifold Kernel Regression

157 3 110MB

Identification of Tongue Muscle Fibre Group Contraction from MR Images

163 59 7MB

Improving Proximity Bounds Using Sparsity

172 11 7MB

Calibrationless Parallel Dynamic MRI with Joint Temporal Sparsity

125 25 46MB

Risk-free WHO grading of astrocytoma using convolutional neural networks from MRI images

181 70 1MB

Enhanced MRI Reconstruction Network Using Neural Architecture Search

181 4 135MB

Probabilistic 3D Surface Reconstruction from Sparse MRI Information

169 95 126MB

MRI Image Reconstruction via Learning Optimization Using Neural ODEs

188 15 154MB

Skull Stripping for MRI Images Using Morphological Operators

183 31 5MB