Abstract
In this work, novel denoising and super resolution (SR) approaches for magnetic resonance (MR) images are addressed, and are integrated in a unified framework, which do not require example low resolution (LR)/high resolution (HR)/cross-modality/noise-free images and prior information of noise–noise variance. The proposed method categorizes the patches as either smooth or textured and then denoises them by deploying different denoising strategies for efficient denoising. The denoising algorithm is integrated into the SR approach, which uses a gradient profile-based constraint in a sparse representation-based framework to improve the resolution of MR images with reduced smearing of image details. This constraint regularizes the estimation of HR images such that the estimated HR image has gradient profiles similar to the gradient profiles of the original HR image. For this, the gradient profile sharpness (GPS) values of an unknown HR image are estimated using an approximated piece-wise linear relation among GPS values of LR and upsampled LR images. The experiments are performed on three different publicly available datasets. The proposed SR approach outperforms the existing unsupervised SR approach addressed for real MR images that exploits low rank and total variation (LRTV) regularization, by an average peak signal to noise ratio (PSNR) of 0.73 dB and 0.38 dB for upsampling factors 2 and 3, respectively. For the super resolution of noisy real MR images (degraded with 2% noise), the proposed approach outperforms the LRTV approach by an average PSNR of 0.54 dB and 0.46 dB for upsampling factors 2 and 3, respectively. The qualitative analysis is shown for real MR images from healthy subjects and subjects with Alzheimer’s disease and structural deformity, i.e., cavernoma.
Highlights
High quality magnetic resonance (MR) images are generally desired for precise medical diagnosis and analysis, and are typically characterized by high spatial resolution and high signal to noise ratio (SNR)
The performance of the proposed algorithm is evaluated for SR of noisy MR images as well as individually for the denoising approach and super resolution along three directions, i.e., in-plane and slice-select direction
Higher feature similarity index metric (FSIM) indicates the higher subjective evaluation based on image gradient magnitude and phase congruency, and is generally used to indicate better features related to edge information [56]
Summary
High quality magnetic resonance (MR) images are generally desired for precise medical diagnosis and analysis, and are typically characterized by high spatial resolution and high signal to noise ratio (SNR). Different paradigms of machine learning approaches : The limited availability of example/training MR images makes it crucial to classify the existing denoising and SR approaches based on the requirement of paired/labeled example data as (i) supervised and (ii) unsupervised. The supervised approaches require paired example images for learning the mapping between input and ground truth images. Several unsupervised approaches have been addressed in the literature which require unpaired/unlabeled data to learn the mapping between input and ground truth images. The cycle-generative adversarial networks (GAN)-based unsupervised SR approach exploits transductive learning and requires example low resolution (LR) and high resolution (HR) images without any correspondences among them [3]. Several hybrid versions for supervised and unsupervised frameworks exist such as a semi-supervised framework which requires a few paired and many unpaired example MR images, for example cycle GAN-based methods [18]
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