Abstract
IntroductionMRI gradient-fields may induce extrinsic voltage between electrodes and conductive neurostimulator enclosure of implanted deep brain stimulation (DBS) systems, and may cause unintended stimulation and/or malfunction. Electromagnetic (EM) simulations using detailed anatomical human models, therapy implant trajectories, and gradient coil models can be used to calculate clinically relevant induced voltage levels. Incorporating additional anatomical human models into the EM simulation library can help to achieve more clinically relevant and accurate induced voltage levels, however, adding new anatomical human models and developing implant trajectories is time-consuming, expensive and not always feasible.MethodsMRI gradient-field induced voltage levels are simulated in six adult human anatomical models, along clinically relevant DBS implant trajectories to generate the dataset. Predictive artificial neural network (ANN) regression models are trained on the simulated dataset. Leave-one-out cross validation is performed to assess the performance of ANN regressors and quantify model prediction errors.ResultsMore than 180,000 unique gradient-induced voltage levels are simulated. ANN algorithm with two fully connected layers is selected due to its superior generalizability compared to support vector machine and tree-based algorithms in this particular application. The ANN regression model is capable of producing thousands of gradient-induced voltage predictions in less than a second with mean-squared-error less than 200 mV.ConclusionWe have integrated machine learning (ML) with computational modeling and simulations and developed an accurate predictive model to determine MRI gradient-field induced voltage levels on implanted DBS systems.
Highlights
MRI gradient-fields may induce extrinsic voltage between electrodes and conductive neurostimulator enclosure of implanted deep brain stimulation (DBS) systems, and may cause unintended stimulation and/or malfunction
deep brain stimulator (DBS) systems should be designed to mitigate for unintended interactions between implanted systems and strong electromagnetic (EM) fields produced by MRI scanners, which may otherwise pose significant hazards to patients (Nyenhuis, 2003)
For each unique implant trajectory, gradient coil model set and scan z-axis landmark location configuration, final gradient-induced voltage levels are calculated by combining voltage levels due to X, Y, and Z-axis coils in a sum-of-magnitude fashion to conservatively account for all three axis simultaneously slewing at 200 T/m/s
Summary
MRI gradient-fields may induce extrinsic voltage between electrodes and conductive neurostimulator enclosure of implanted deep brain stimulation (DBS) systems, and may cause unintended stimulation and/or malfunction. Electromagnetic (EM) simulations using detailed anatomical human models, therapy implant trajectories, and gradient coil models can be used to calculate clinically relevant induced voltage levels. In the presence of AIMDs with long conductive components such as DBS leads and extensions, MRI gradient-field induced E-fields can generate extrinsic electric potential between spatially separated electrodes of an AIMD. Gradient-field induced extrinsic electric potential can be calculated by integrating the tangential component of the E-field along trajectory of the implanted system: L. MRI gradient-field induced extrinsic electric potential between DBS therapy electrodes and the implanted conductive neurostimulator are evaluated. Terms induced voltage and voltage levels are used interchangeably to refer to MRI gradient-field induced extrinsic potential between DBS electrodes and neurostimulator
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