Abstract
Parallel magnetic resonance imaging (MRI) technique is able to accelerate MRI speed for reducing costs and enhancing patient’s comfortability. Parallel MRI can be categorized into two types: image-based and k-space-based methods. For k-space-based parallel MRI, missing k-space data is reconstructed by interpolating existing acquired k-space data with appropriate coefficients, which is generally considered as a linear process. However, noise cannot be suppressed or removed during the linear reconstruction process and therefore reconstructed image often suffers serious noise, especially when the acceleration factor is high. Non-linear filters are known to remove non-linear noise better. Based on the Volterra series that discovers and removes the second-order non-linear noise, we proposed a non-linear reconstruction strategy called adaptive Volterra generalized autocalibrating partial parallel acquisition (AV-GRAPPA) to reconstruct the unacquired k-space signals. For the proposed AV-GRAPPA, optimal selection of the second-order Volterra series terms is adjusted and determined for optimizing reconstruction quality. Experimental results show that the proposed method is able to better remove the reconstruction noise and suppress aliasing artifacts.
Highlights
Magnetic resonance imaging (MRI) [1–3] is a non-invasive imaging technique
Reconstructions by the proposed method achieve a good performance compared to other methods
The proposed method focuses on removing noise rather than suppressing aliasing artifacts, so the result of the proposed AV-generalized autocalibrating partially parallel acquisitions (GRAPPA) still has tiny aliasing artifacts
Summary
Magnetic resonance imaging (MRI) [1–3] is a non-invasive imaging technique. Different from computed tomography and other imaging technologies, MRI has the advantages of non-ionizing radiation, multiple parameter imaging, high contrast, etc. MRI has its own shortcomings, such as long scan time, which limit its application in many clinical situations. Investigators have been exploring rapid magnetic resonance imaging methods since the invention of MRI technology. This has led to the development of methods for spiral acquisition, radial acquisition, parallel imaging, and so forth. Those methods have greatly improved the imaging speed to some extent.
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