Litcius/Paper detail

Whole-body magnetic resonance imaging at 0.05 Tesla

Yujiao Zhao, Ye Ding, Vick Lau, Christopher Man, Shi Su, Linfang Xiao, Alex T. L. Leong, EX Wu

2024Science103 citationsDOIOpen Access PDF

Abstract

Despite a half-century of advancements, global magnetic resonance imaging (MRI) accessibility remains limited and uneven, hindering its full potential in health care. Initially, MRI development focused on low fields around 0.05 Tesla, but progress halted after the introduction of the 1.5 Tesla whole-body superconducting scanner in 1983. Using a permanent 0.05 Tesla magnet and deep learning for electromagnetic interference elimination, we developed a whole-body scanner that operates using a standard wall power outlet and without radiofrequency and magnetic shielding. We demonstrated its wide-ranging applicability for imaging various anatomical structures. Furthermore, we developed three-dimensional deep learning reconstruction to boost image quality by harnessing extensive high-field MRI data. These advances pave the way for affordable deep learning-powered ultra-low-field MRI scanners, addressing unmet clinical needs in diverse health care settings worldwide.

Topics & Concepts

Magnetic resonance imagingNuclear magnetic resonanceResonance (particle physics)PhysicsMedicineAtomic physicsRadiologyAdvanced MRI Techniques and ApplicationsMedical Imaging Techniques and ApplicationsAdvanced X-ray and CT Imaging