Future of Neurology &amp; Technology: Neuroimaging Made Accessible Using Low-Field, Portable MRI

Parasuram, Nethra; Crawford, Anna; Mazurek, Mercy H; Chavva, Isha R; Beekman, Rachel; Gilmore, Emily J.; Petersen, Nils; Payabvash, Sam; Sze, Gordon; Iglesias, Juan Eugenio; Omay, Sacit Bulent; Matouk, Charles; Longbrake, Erin E.; Havenon, Adam de; Rosen, Matthew S.; Kimberly, W. Taylor; Sheth, Kevin N

doi:10.1212/wnl.0000000000207074

Cited by 5 publications

(3 citation statements)

References 14 publications

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“…Recent technical innovations in MRI physics and instrumentation have led to scanners operating at far lower magnetic fields than previously thought possible and have enabled 64 mT MRI scanners to be deployed at the patient bedside for POC use. These low-cost low-field MRI scanners can operate without the shielding and safety requirements of traditional high-field scanners, but their use to date has focused on neuroimaging in critical-care settings [6][7][8][9] .…”

mentioning

confidence: 99%

Single-sided magnetic resonance-based sensor for point-of-care evaluation of muscle

Sherman,

Zammit,

Heo

et al. 2024

Nat Commun

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Magnetic resonance imaging is a widespread clinical tool for the detection of soft tissue morphology and pathology. However, the clinical deployment of magnetic resonance imaging scanners is ultimately limited by size, cost, and space constraints. Here, we discuss the design and performance of a low-field single-sided magnetic resonance sensor intended for point-of-care evaluation of skeletal muscle in vivo. The 11 kg sensor has a penetration depth of >8 mm, which allows for an accurate analysis of muscle tissue and can avoid signal from more proximal layers, including subcutaneous adipose tissue. Low operational power and shielding requirements are achieved through the design of a permanent magnet array and surface transceiver coil. The sensor can acquire high signal-to-noise measurements in minutes, making it practical as a point-of-care tool for many quantitative diagnostic measurements, including T2 relaxometry. In this work, we present the in vitro and human in vivo performance of the device for muscle tissue evaluation.

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confidence: 99%

Single-sided magnetic resonance-based sensor for point-of-care evaluation of muscle

Sherman,

Zammit,

Heo

et al. 2024

Nat Commun

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“…8,[12][13][14][15][16][17][18] Substantial improvements in hardware and software have resulted in a resurgence in MR systems operating below 1.5 T. An array of different scanner geometries, field strengths, and different use-cases are found in this realm including an open-architecture, vertical (transverse) field 1.2 T scanner and the lower field strength (generally defined as MR systems operating in the range of 0.25 to 1.0 T) MR systems that have horizontal (longitudinal) or vertical (transverse) field magnets. 10,11,[19][20][21][22] Also operating below 1.5 T are scanners with unique features or designed for specialized applications such as a very-low-field (0.064 T), point-of-care MR system, 23,24 dedicated extremity scanners, 25,26 an upright MR system, 27 a neonatal scanner, 28 an MRI-guided, radiotherapy system, 29 and a single-sided, interventional MR scanner. 30,31 The growing worldwide utilization of these MR systems combined with the increasing incidence of patients with metallic implants that need MRI creates undesirable circumstances that include patients potentially being subjected to unsafe imaging conditions or being denied access to MRI because physicians often lack the knowledge to conduct a proper assessment of risk vs. benefit.…”

mentioning

confidence: 99%

“…Substantial improvements in hardware and software have resulted in a resurgence in MR systems operating below 1.5 T. An array of different scanner geometries, field strengths, and different use‐cases are found in this realm including an open‐architecture, vertical (transverse) field 1.2 T scanner and the lower field strength (generally defined as MR systems operating in the range of 0.25 to 1.0 T) MR systems that have horizontal (longitudinal) or vertical (transverse) field magnets 10,11,19–22 . Also operating below 1.5 T are scanners with unique features or designed for specialized applications such as a very‐low‐field (0.064 T), point‐of‐care MR system, 23,24 dedicated extremity scanners, 25,26 an upright MR system, 27 a neonatal scanner, 28 an MRI‐guided, radiotherapy system, 29 and a single‐sided, interventional MR scanner 30,31 …”

mentioning

confidence: 99%

Managing Patients With Unlabeled Passive Implants on MR Systems Operating Below 1.5 T

Shellock,

Rosen,

Webb

et al. 2023

Magnetic Resonance Imaging

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The standard of care for managing a patient with an implant is to identify the item and to assess the relative safety of scanning the patient. Because the 1.5 T MR system is the most prevalent scanner in the world and 3 T is the highest field strength in widespread use, implants typically have “MR Conditional” (i.e., an item with demonstrated safety in the MR environment within defined conditions) labeling at 1.5 and/or 3 T only. This presents challenges for a facility that has a scanner operating at a field strength below 1.5 T when encountering a patient with an implant, because scanning the patient is considered “off‐label.” In this case, the supervising physician is responsible for deciding whether to scan the patient based on the risks associated with the implant and the benefit of magnetic resonance imaging (MRI). For a passive implant, the MRI safety‐related concerns are static magnetic field interactions (i.e., force and torque) and radiofrequency (RF) field‐induced heating. The worldwide utilization of scanners operating below 1.5 T combined with the increasing incidence of patients with implants that need MRI creates circumstances that include patients potentially being subjected to unsafe imaging conditions or being denied access to MRI because physicians often lack the knowledge to perform an assessment of risk vs. benefit. Thus, physicians must have a complete understanding of the MRI‐related safety issues that impact passive implants when managing patients with these products on scanners operating below 1.5 T. This monograph provides an overview of the various clinical MR systems operating below 1.5 T and discusses the MRI‐related factors that influence safety for passive implants. Suggestions are provided for the management of patients with passive implants labeled MR Conditional at 1.5 and/or 3 T, referred to scanners operating below 1.5 T. The purpose of this information is to empower supervising physicians with the essential knowledge to perform MRI exams confidently and safely in patients with passive implants.Level of Evidence1Technical EfficacyStage 3

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Feasibility and tolerability of portable, low-field brain MRI for patients with multiple sclerosis

Ham,

Hacker,

Guo

et al. 2024

Multiple Sclerosis and Related Disorders

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Future of Neurology & Technology: Neuroimaging Made Accessible Using Low-Field, Portable MRI

Cited by 5 publications

References 14 publications

Single-sided magnetic resonance-based sensor for point-of-care evaluation of muscle

Single-sided magnetic resonance-based sensor for point-of-care evaluation of muscle

Managing Patients With Unlabeled Passive Implants on MR Systems Operating Below 1.5 T

Feasibility and tolerability of portable, low-field brain MRI for patients with multiple sclerosis

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