Reference-Based MRI
TLDR
In this paper, the authors present a framework for fast MRI by exploiting a reference image (FASTMER), which is based on an iterative reconstruction approach that supports cases in which similarity to the reference scan is not guaranteed.Abstract:
Purpose: In many clinical MRI scenarios, existing imaging information can be used to significantly shorten acquisition time or to improve Signal to Noise Ratio (SNR). In this paper the authors present a framework for fast MRI by exploiting a reference image (FASTMER).
Methods: The proposed approach utilizes the possible similarity of the reference image that exists in many clinical MRI imaging scenarios. Such scenarios include similarity between adjacent slices in high resolution MRI, similarity between various contrasts in the same scan and similarity between different scans of the same patient. The authors take into account that the reference image may exhibit low similarity with the acquired image and develop an iterative weighted approach for reconstruction, which tunes the weights according to the degree of similarity.
Results: Experimental results demonstrate the performance of the method in three different clinical MRI scenarios: SNR improvement in high resolution brain MRI, exploiting similarity between T2-weighted and fluid-attenuated inversion recovery (FLAIR) for fast FLAIR scanning and utilizing similarity between baseline and follow-up scans for fast follow-up. Results outperform reconstruction results of existing state-of-the-art methods.
Conclusions: The authors present a method for fast MRI by exploiting a reference image. The method is based on an iterative reconstruction approach that supports cases in which similarity to the reference scan is not guaranteed, which enables the applicability of the method to a variety of MRI applications. Thanks to the existence of reference images in various clinical imaging scenarios, the proposed framework can play a major part in improving reconstruction in many MR applications.read more
Citations
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Low-rank magnetic resonance fingerprinting
TL;DR: This work introduces a new approach for quantitative MRI using MRF, called magnetic resonance fingerprinting with low rank (FLOR), and demonstrates improved parameter accuracy compared to other compressed-sensing and low-rank based methods for MRF.
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HYDRA: Hybrid deep magnetic resonance fingerprinting.
TL;DR: This work proposes a HYbrid Deep magnetic resonance fingerprinting approach, referred to as HYDRA, which significantly improves inference speed by eliminating the time-consuming dictionary matching operation, and alleviates discretization errors by outputting continuous-valued parameters.
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MSMANet: A multi-scale mesh aggregation network for brain tumor segmentation
TL;DR: Wang et al. as mentioned in this paper proposed a multi-scale mesh aggregation network (MSMANet) for brain tumor segmentation, where an improved Inception module was introduced to replace the standard convolution in the encoder to extract effective information from different receptive fields.
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Low Rank Magnetic Resonance Fingerprinting
TL;DR: In this article, the authors proposed Magnetic Resonance Fingerprinting with Low-Rank (FLOR) method for quantitative MRI using MRF, which exploits the low rank property of the concatenated temporal imaging contrasts, on top of which the MRF signal is sparsely represented in the generated dictionary domain.
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PEAR: PEriodic And fixed Rank separation for fast fMRI
TL;DR: PEAR as mentioned in this paper decomposes the fMRI signal into a component which has fixed rank and a component consisting of a sum of periodic signals which is sparse in the temporal Fourier domain, which is performed by solving a constrained problem that enforces a fixed, moderate rank on one of the components, and a limited number of temporal frequencies on the other.
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