Paul Rugieri scite author profile

Purpose: To assess magnetic resonance imaging (MRI)-related heating for a neurostimulation system (Activa Tremor Control System, Medtronic, Minneapolis, MN) used for chronic deep brain stimulation (DBS). Materials and Methods:Different configurations were evaluated for bilateral neurostimulators (Soletra® Model 7426), extensions, and leads to assess worst-case and clinically relevant positioning scenarios. In vitro testing was performed using a 1.5-T/64-MHz MR system and a gelfilled phantom designed to approximate the head and upper torso of a human subject. MRI was conducted using the transmit/receive body and transmit/receive head radio frequency (RF) coils. Various levels of RF energy were applied with the transmit/receive body (whole-body averaged specific absorption rate (SAR); range, 0.98 -3.90 W/kg) and transmit/receive head (whole-body averaged SAR; range, 0.07-0.24 W/kg) coils. A fluoroptic thermometry system was used to record temperatures at multiple locations before (1 minute) and during (15 minutes) MRI.Results: Using the body RF coil, the highest temperature changes ranged from 2.5°-25.3°C. Using the head RF coil, the highest temperature changes ranged from 2.3°-7.1°C.Thus, these findings indicated that substantial heating occurs under certain conditions, while others produce relatively minor, physiologically inconsequential temperature increases. Conclusion:The temperature increases were dependent on the type of RF coil, level of SAR used, and how the lead wires were positioned. Notably, the use of clinically relevant positioning techniques for the neurostimulation system and low SARs commonly used for imaging the brain generated little heating. Based on this information, MR safety guidelines are provided. These observations are restricted to the tested neurostimulation system.

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MR safety in patients with implanted deep brain stimulation systems (DBS)

Sharan

Rezai

Nyenhuis

et al. 2003

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Neurostimulators: Potential for excessive heating of deep brain stimulation electrodes during magnetic resonance imaging

Rezai¹,

Finelli²,

Rugieri³

et al. 2001

Magnetic Resonance Imaging

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Gelled vs non-gelled phantom material for measurement of temperature rise by the MRI RF-magnetic field

Park

Nyenuis

Lim

et al.

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Paul Rugieri

Neurostimulation systems for deep brain stimulation: In vitro evaluation of magnetic resonance imaging–related heating at 1.5 tesla

MR safety in patients with implanted deep brain stimulation systems (DBS)

Neurostimulators: Potential for excessive heating of deep brain stimulation electrodes during magnetic resonance imaging

Gelled vs non-gelled phantom material for measurement of temperature rise by the MRI RF-magnetic field

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