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Relationship between Neural Activation and Electric Field Distribution during Deep Brain Stimulation

2014; Institute of Electrical and Electronics Engineers; Volume: 62; Issue: 2 Linguagem: Inglês

10.1109/tbme.2014.2363494

1558-2531

Mattias Åström, Elin Diczfalusy, H.C.F. Martens, Karin Wårdell,

EEG and Brain-Computer Interfaces

Models and simulations are commonly used to study deep brain stimulation (DBS). Simulated stimulation fields are often defined and visualized by electric held isolevels or volumes of tissue activated (VTA). The aim of the present study was to evaluate the relationship between stimulation held strength as defined by the electric potential V, the electric held E, and the divergence of the electric held ∇ 2 V, and neural activation. Axon cable models were developed and coupled to finite-element DBS models in three-dimensional (3-D). Field thresholds (V T , E T , and ∇ 2 V T ) were derived at the location of activation for various stimulation amplitudes (1 to 5 V), pulse widths (30 to 120 μs), and axon diameters (2.0 to 7.5 μm). Results showed that thresholds for V T and ∇ 2 V T were highly dependent on the stimulation amplitude while E T were approximately independent of the amplitude for large axons. The activation held strength thresholds presented in this study may be used in future studies to approximate the VTA during model-based investigations of DBS without the need of computational axon models.