Abstract
Objective. During deep brain stimulation (DBS), it is well understood that extracellular cathodic stimulation can cause activation of passing axons. Activation can be predicted from the second derivative of the electric potential along an axon, which depends on axonal orientation with respect to the stimulation source. We hypothesize that fiber orientation influences activation thresholds and that fiber orientations can be selectively targeted with DBS waveforms. Approach. We used bioelectric field and multicompartment NEURON models to explore preferential activation based on fiber orientation during monopolar or bipolar stimulation. Preferential fiber orientation was extracted from the principal eigenvectors and eigenvalues of the Hessian matrix of the electric potential. We tested cathodic, anodic, and charge-balanced pulses to target neurons based on fiber orientation in general and clinical scenarios. Main results. Axons passing the DBS lead have positive second derivatives around a cathode, whereas orthogonal axons have positive second derivatives around an anode, as indicated by the Hessian. Multicompartment NEURON models confirm that passing fibers are activated by cathodic stimulation, and orthogonal fibers are activated by anodic stimulation. Additionally, orthogonal axons have lower thresholds compared to passing axons. In a clinical scenario, fiber pathways associated with therapeutic benefit can be targeted with anodic stimulation at 50% lower stimulation amplitudes. Significance. Fiber orientations can be selectively targeted with simple changes to the stimulus waveform. Anodic stimulation preferentially activates orthogonal fibers, approaching or leaving the electrode, at lower thresholds for similar therapeutic benefit in DBS with decreased power consumption.
Highlights
Two decades after initial approval of deep brain stimulation (DBS), it has grown into an established surgical intervention for movement disorders such as essential tremor, Parkinson’s disease, and dystonia (Pizzolato and Mandat 2012, Wichmann and DeLong 2006) as well as a potential treatment option for a number of intractable psychiatric disorders
With NEURON modeling, we aimed to explore the differences between activation patterns of anodic stimulation and cathodic stimulation on fiber pathways associated with therapeutic benefits and side effects
We found that cathodic stimulation and anodic stimulation each activate certain fiber orientations selectively as indicated by the primary, secondary, and tertiary eigenvector directions
Summary
Two decades after initial approval of deep brain stimulation (DBS), it has grown into an established surgical intervention for movement disorders such as essential tremor, Parkinson’s disease, and dystonia (Pizzolato and Mandat 2012, Wichmann and DeLong 2006) as well as a potential treatment option for a number of intractable psychiatric disorders. Target selection can be challenging, computational modeling has been used to help visualize stimulation spread to neural targets like nuclei or fiber tracts to improve our understanding of target activation (Butson et al 2007, Butson et al 2013, Noecker et al 2018). In an effort to save computational time by avoiding NEURON simulations, a number of methods approximate activation with ellipsoidal fits of the VTA (Mädler and Coenen 2012, Chaturvedi et al 2013), voltage isosurfaces (Martens et al 2011), electric field isolevels (Åström et al 2012), and second difference thresholds (Anderson et al 2018). The spread of activation can help determine which regions might correspond to clinical benefits or side effects. We expand upon prior work in Anderson et al (2018) by using the Hessian of the electric potential to explore the role of orientation in axon activation
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