Abstract
BackgroundMagnetic resonance imaging (MRI) is corrupted by Rician noise, which is image dependent and computed from both real and imaginary images. Rician noise makes image-based quantitative measurement difficult. The non-local means (NLM) filter has been proven to be effective against additive noise.MethodsConsidering the characteristics of both Rician noise and the NLM filter, this study proposes a frame for a pre-smoothing NLM (PSNLM) filter combined with image transformation. In the PSNLM frame, noisy MRI is first transformed into an image in which noise can be treated as additive noise. Second, the transformed MRI is pre-smoothed via a traditional denoising method. Third, the NLM filter is applied to the transformed MRI, with weights that are computed from the pre-smoothed image. Finally, inverse transformation is performed on the denoised MRI to obtain the denoising results.ResultsTo test the performance of the proposed method, both simulated and real patient data are used, and various pre-smoothing (Gaussian, median, and anisotropic filters) and image transformation [squared magnitude of the MRI, and forward and inverse variance-stabilizing trans-formations (VST)] methods are used to reduce noise. The performance of the proposed method is evaluated through visual inspection and quantitative comparison of the peak signal-to-noise ratio of the simulated data. The real data include Alzheimer’s disease patients and normal controls. For the real patient data, the performance of the proposed method is evaluated by detecting atrophy regions in the hippocampus and the parahippocampal gyrus.ConclusionsThe comparison of the experimental results demonstrates that using a Gaussian pre-smoothing filter and VST produce the best results for the peak signal-to-noise ratio (PSNR) and atrophy detection.
Highlights
MethodsConsidering the characteristics of both Rician noise and the non-local means (NLM) filter, this study proposes a frame for a pre-smoothing NLM (PSNLM) filter combined with image transformation
Magnetic resonance imaging (MRI) is corrupted by Rician noise, which is image dependent and computed from both real and imaginary images
Magnetic resonance imaging (MRI) images of the brain have an important role in diagnosing many neurological diseases, such as Parkinson’s disease, Alzheimer’s disease (AD), brain tumors, and stroke
Summary
The proposed method includes four steps: (1) transformation of noisy MRI, (2) presmoothing of the transformed MRI, (3) noise removal by the NLM filter, and (4) unbiased correction (inverse transformation) of the denoised image. In these figures, the bright area is the brain region, whereas the dark area is the background. The Pre-smooth Non-local Means Filter (PSNLM) Before using the NLM filter, MRI |z| is first transformed into It via forward transformation f (squared magnitude or variance stabilization) It is smoothed by a traditional filter S (Gaussian, median, or anisotropic) to become Is. When the NLM filter is used to remove noise, the weight and normalizing constant are calculated from Is as follows: It 1⁄4 f ðjzjÞ; Is 1⁄4 SðItÞ k ð Þ ð Þk Ga e−. To test the performance of the proposed method, 20 NCs and 20 AD patients with T1-weighted MRI images of the baseline are randomly selected from the database
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