Reconfigurable MRI coil technology can substantially reduce RF heating of deep brain stimulation implants: First in-vitro study of RF heating reduction in bilateral DBS leads at 1.5 T.
Laleh GolestaniradEhsan KazemivalipourBoris KeilSean DownsJohn KirschBehzad ElahiJulie PilitsisLawrence L WaldPublished in: PloS one (2019)
Patients with deep brain stimulation (DBS) implants can significantly benefit from magnetic resonance imaging (MRI), however access to MRI is restricted in these patients because of safety concerns due to RF heating of the leads. Recently we introduced a patient-adjustable reconfigurable transmit coil for low-SAR imaging of DBS at 1.5T. A previous simulation study demonstrated a substantial reduction in the local SAR around single DBS leads in 9 unilateral lead models. This work reports the first experimental results of temperature measurement at the tips of bilateral DBS leads with realistic trajectories extracted from postoperative CT images of 10 patients (20 leads in total). A total of 200 measurements were performed to record temperature rise at the tips of the leads during 2 minutes of scanning with the coil rotated to cover all accessible rotation angles. In all patients, we were able to find an optimum coil rotation angle and reduced the heating of both left and right leads to a level below the heating produced by the body coil. An average heat reduction of 65% was achieved for bilateral leads. When considering each lead alone, an average heat reduction of 80% was achieved. Our results suggest that reconfigurable coil technology introduces a promising approach for imaging of patients with DBS implants.
Keyphrases
- deep brain stimulation
- magnetic resonance imaging
- parkinson disease
- end stage renal disease
- obsessive compulsive disorder
- high resolution
- newly diagnosed
- chronic kidney disease
- peritoneal dialysis
- contrast enhanced
- prognostic factors
- case report
- emergency department
- mass spectrometry
- depressive symptoms
- deep learning
- patient reported outcomes
- soft tissue
- optical coherence tomography
- fluorescence imaging