Affiliation:
1. Department of Biomedical Engineering Columbia University in the City of New York New York New York USA
2. Columbia Magnetic Resonance Research Center Columbia University in the City of New York New York New York USA
3. Department of Diagnostic, Molecular and Interventional Radiology, Icahn School of Medicine at Mount Sinai The Biomedical Engineering and Imaging Institute New York New York USA
Abstract
AbstractPresently, magnetic resonance imaging (MRI) magnets must deliver excellent magnetic field (B0) uniformity to achieve optimum image quality. Long magnets can satisfy the homogeneity requirements but require considerable superconducting material. These designs result in large, heavy, and costly systems that aggravate as field strength increases. Furthermore, the tight temperature tolerance of niobium titanium magnets adds instability to the system and requires operation at liquid helium temperature. These issues are crucial factors in the disparity of MR density and field strength use across the globe. Low‐income settings show reduced access to MRI, especially to high field strengths. This article summarizes the proposed modifications to MRI superconducting magnet design and their impact on accessibility, including compact, reduced liquid helium, and specialty systems. Reducing the amount of superconductor inevitably entails shrinking the magnet size, resulting in higher field inhomogeneity. This work also reviews the state‐of‐the‐art imaging and reconstruction methods to overcome this issue. Finally, we summarize the current and future challenges and opportunities in the design of accessible MRI.
Subject
Spectroscopy,Radiology, Nuclear Medicine and imaging,Molecular Medicine
Cited by
3 articles.
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