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or permanent magnets where the magnetic energy density can be stored without the use of cryogens. Other departures examined include nonswitched readout gradients built into the static magnet design (saving power, cooling, and reducing acoustic noise) [20], encoding by rotation of a built-in gradient (further reducing encoding electronics) [21–27], and shrinking the imaging field of view (FOV) even further to a subset of the organ and perhaps not fully encoding all spatial dimensions.

      3.3 Three Levels of POC Use

      Figure 3.1 Superconducting MRI systems recently introduced to the market to provide high-quality imaging with reduced siting needs. All employ conduction-cooled magnets to eliminate the need for “quench pipes” to vent cryogenic gases. From left to right: GE (Waukesha WI) 3-T “compact head scanner,” the Synaptive Medical (Toronto, ON, Canada) 0.5-T “Envry” compact scanner, and the Siemens Healthineers (Erlangen, Germany) 0.55-T “Free Max” compact 80-cm diameter patient-bore scanner (Siemens Healthcare GmbH).

      The second level would be a truly portable scanner that could be pushed down the hallways of the hospital by a single staff member who brings it into the ward or even to the bedside and powers it up for POC use. This device must operate using a standard electrical outlet or perhaps battery power, the latter allowing it to be embedded in an ambulance or mobile setting. The mobile POC scanner would likely operate at low field (50–200 mT), need unconventional EMI mitigation, and must operate with substantially reduced electrical power compared with conventional systems and without water cooling or cryogenics. This class of POC devices is being actively pursued by several companies and academic groups as discussed in Section 3.3.2.

      Finally, the third class is a more speculative device that extends MRI to a near “handheld” level, likely with a greatly reduced imaging capabilities, but inexpensive and small enough to be considered an MR detector or monitoring device more than a diagnostic imaging device. Such a lightweight device could reach into the bed and monitor an organ, perhaps using 1D imaging or just the MR signal itself. This rethinks the role of MRI as a tomographic imager and, as such, is the most distant from conventional MRI scanner architectures. Nonetheless, examples of this more speculative device are starting to emerge in the literature as outlined in Section 3.3.3.

      3.3.1 Brain MRI in an “Easy-to-Site Suite”

      3.3.2 Brain MRI with a Portable Device

      Figure 3.2 A potential portable brain magnetic resonance imaging cart based on a “Halbach bulb” permanent magnet array for bedside use in the emergency department or intensive care unit. Prototype magnet, gradient, and radiofrequency (top) and envisioned mobile cart (bottom); system approaches bed from head end and utilizes a double sliding mechanism (radiofrequency coil slides followed by magnet sliding down).

      3.3.3 Brain MRI as a Monitoring Device

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