Subject-specific computational modeling of DBS in the PPTg area

Zitella, Laura M.; Teplitzky, Benjamin A.; Yager, Paul; Hudson, Heather M.; Brintz, Katelynn; Duchin, Yuval; Harel, Noam; Vitek, Jerrold L.; Baker, Kenneth B.; Johnson, Matthew D.

doi:10.3389/fncom.2015.00093

Cited by 9 publications

(8 citation statements)

References 55 publications

(70 reference statements)

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“…This region was used as a seedpoint mask for tractography for both the lenticular fasciculus and for the thalamic fasciculus, with the globus pallidus and the thalamus used as termination masks, respectively. After generating the fiber tract trajectories, the tracts were populated with myelinated axons of 2 μm fiber diameter (FLUT length 10 μm; STIN length 57.7 μm; MYSA length 3 μm; node diameter 1.4 μm; axon diameter 1.6 μm; node length 1 μm; number lamellae 30; passive first and last nodes) using the threshold-contour mapping procedure described in [41]. Axons that overlapped with the DBS lead were removed from subsequent simulations.…”

Section: Methodsmentioning

confidence: 99%

Multi-objective particle swarm optimization for postoperative deep brain stimulation targeting of subthalamic nucleus pathways

et al. 2018

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Section: Methodsmentioning

confidence: 99%

Multi-objective particle swarm optimization for postoperative deep brain stimulation targeting of subthalamic nucleus pathways

et al. 2018

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“…While this study used a simplistic homogeneous and isotropic model of tissue conductance to obtain extracellular potential values at the axonal nodes of Ranvier, one may consider using more complex models of brain tissue with the PSO algorithm. For example, studies have shown that finite element models that incorporate inhomogeneous and anisotropic tissue properties (assigning different conductance values to various tissue types) improve modeling results and may better reflect the physiological properties of the brain [11], [32], [57]. Finally, while the implementation presented here was designed for programming a set of electrodes that have already been implanted, it is conceivable to leverage the efficiency of this approach for pre-surgical planning of DBS lead placement.…”

Section: Discussionmentioning

confidence: 99%

Particle swarm optimization for programming deep brain stimulation arrays

et al. 2017

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Objective Deep brain stimulation (DBS) therapy relies on both precise neurosurgical targeting and systematic optimization of stimulation settings to achieve beneficial clinical outcomes. One recent advance to improve targeting is the development of DBS arrays (DBSAs) with electrodes segmented both along and around the DBS lead. However, increasing the number of independent electrodes creates the logistical challenge of optimizing stimulation parameters efficiently. Approach Solving such complex problems with multiple solutions and objectives is well known to occur in biology, in which complex collective behaviors emerge out of swarms of individual organisms engaged in learning through social interactions. Here, we developed a particle swarm optimization (PSO) algorithm to program DBSAs using a swarm of individual particles representing electrode configurations and stimulation amplitudes. Using a finite element model of motor thalamic DBS, we demonstrate how the PSO algorithm can efficiently optimize a multi-objective function that maximizes predictions of axonal activation in regions of interest (ROI, cerebellar-receiving area of motor thalamus), minimizes predictions of axonal activation in regions of avoidance (ROA, somatosensory thalamus), and minimizes power consumption. Main Results The algorithm solved the multi-objective problem by producing a Pareto front. ROI and ROA activation predictions were consistent across swarms (<1% median discrepancy in axon activation). The algorithm was able to accommodate for (1) lead displacement (1 mm) with relatively small ROI (≤9.2%) and ROA (≤1%) activation changes, irrespective of shift direction; (2) reduction in maximum per-electrode current (by 50% and 80%) with ROI activation decreasing by 5.6% and 16%, respectively; and (3) disabling electrodes (n=3 and 12) with ROI activation reduction by 1.8% and 14%, respectively. Additionally, comparison between PSO predictions and multi-compartment axon model simulations showed discrepancies of <1% between approaches. Significance The PSO algorithm provides a computationally efficient way to program DBS systems especially those with higher electrode counts.

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“…The quasistatic finite element models used for predicting tissue voltage in this study were idealized as isotropic and were homogeneous within bulk neural tissue. Increasingly complex models that more precisely model tissue conductivity using diffusion weighted imaging have been introduced in the past decade and have been shown to impact biophysical simulation results (Butson et al, 2007 ; Chaturvedi et al, 2010 ; Zitella et al, 2015 ), particularly for modeling of electrical stimulation near white matter fiber tracts (Butson et al, 2007 ; Schmidt and van Rienen, 2012 ). Further, the conductance values utilized in the tissue models presented here rely on experimentally determined values for conductance that are subject to uncertainty as evident by the range of values reported within the scientific literature (Gabriel C. et al, 1996 ; Faes et al, 1999 ).…”

Section: Discussionmentioning

confidence: 99%

Model-Based Comparison of Deep Brain Stimulation Array Functionality with Varying Number of Radial Electrodes and Machine Learning Feature Sets

Teplitzky

Zitella

Xiao

et al. 2016

Front. Comput. Neurosci.

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Deep brain stimulation (DBS) leads with radially distributed electrodes have potential to improve clinical outcomes through more selective targeting of pathways and networks within the brain. However, increasing the number of electrodes on clinical DBS leads by replacing conventional cylindrical shell electrodes with radially distributed electrodes raises practical design and stimulation programming challenges. We used computational modeling to investigate: (1) how the number of radial electrodes impact the ability to steer, shift, and sculpt a region of neural activation (RoA), and (2) which RoA features are best used in combination with machine learning classifiers to predict programming settings to target a particular area near the lead. Stimulation configurations were modeled using 27 lead designs with one to nine radially distributed electrodes. The computational modeling framework consisted of a three-dimensional finite element tissue conductance model in combination with a multi-compartment biophysical axon model. For each lead design, two-dimensional threshold-dependent RoAs were calculated from the computational modeling results. The models showed more radial electrodes enabled finer resolution RoA steering; however, stimulation amplitude, and therefore spatial extent of the RoA, was limited by charge injection and charge storage capacity constraints due to the small electrode surface area for leads with more than four radially distributed electrodes. RoA shifting resolution was improved by the addition of radial electrodes when using uniform multi-cathode stimulation, but non-uniform multi-cathode stimulation produced equivalent or better resolution shifting without increasing the number of radial electrodes. Robust machine learning classification of 15 monopolar stimulation configurations was achieved using as few as three geometric features describing a RoA. The results of this study indicate that, for a clinical-scale DBS lead, more than four radial electrodes minimally improved in the ability to steer, shift, and sculpt axonal activation around a DBS lead and a simple feature set consisting of the RoA center of mass and orientation enabled robust machine learning classification. These results provide important design constraints for future development of high-density DBS arrays.

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Subject-specific computational modeling of DBS in the PPTg area

Cited by 9 publications

References 55 publications

Multi-objective particle swarm optimization for postoperative deep brain stimulation targeting of subthalamic nucleus pathways

Multi-objective particle swarm optimization for postoperative deep brain stimulation targeting of subthalamic nucleus pathways

Particle swarm optimization for programming deep brain stimulation arrays

Model-Based Comparison of Deep Brain Stimulation Array Functionality with Varying Number of Radial Electrodes and Machine Learning Feature Sets

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