Mengze Gao, Zachary Shah, Xiaozhi Cao, Nan Wang, Daniel Abraham, Kawin Setsompop
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引用次数: 0
摘要
B0-不均匀性和扩散编码引起的涡流所产生的时空磁场变化会对螺旋、EPI 和三维锥体等快速图像编码方案造成损害,从而导致不良的图像伪影。在这项工作中,通过将自动对焦指标与深度学习相结合,并利用预期场缺陷的紧凑基础表示法,开发了一种数据驱动的自动估计这些场缺陷的方法。该方法被应用于高 b 值的单次螺旋扩散核磁共振成像,获得了 B0 和涡流的精确估计,从而无需额外的外部校准即可进行高质量的图像重建。
ACE-Net: AutofoCus-Enhanced Convolutional Network for Field Imperfection Estimation with application to high b-value spiral Diffusion MRI.
Spatiotemporal magnetic field variations from B0-inhomogeneity and diffusion-encoding-induced eddy-currents can be detrimental to rapid image-encoding schemes such as spiral, EPI and 3D-cones, resulting in undesirable image artifacts. In this work, a data driven approach for automatic estimation of these field imperfections is developed by combining autofocus metrics with deep learning, and by leveraging a compact basis representation of the expected field imperfections. The method was applied to single-shot spiral diffusion MRI at high b-values where accurate estimation of B0 and eddy were obtained, resulting in high quality image reconstruction without need for additional external calibrations.