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- Background: Temporal interference stimulation (TIS) has been proposed as a non-invasive, focal, and steerable deep brain stimulation method. However, the mechanisms underlying experimentally observed TIS effects are unknown, and prior simulation studies have limitations in the representations of the TIS electric field (E-field) and cerebral neurons. Objective: To examine the E-field and neural response characteristics for TIS and other transcranial alternating current stimulation modalities. Methods: We simulated a range of stimulation parameters in layer 5 pyramidal neurons, including different orientations, frequencies, amplitude ratios, amplitude modulation, and phase difference of the E-fields, and obtained thresholds for both activation and block. Results: TIS has unique E-field characteristics. At the target region in the cortex, where the two E-fields have similar amplitudes, TIS generates an amplitude-modulated total E-field. The TIS E-field also exhibits rotation where the E-field orientations are not aligned, which generally co-localizes with the target. TIS activation thresholds are similar to high-frequency stimulation with or without modulation and/or rotation (75–230 V/m). Outside the target region, the TIS E-field is dominated by the high-frequency carrier, with minimal amplitude modulation and/or rotation, and it is less effective at activation and more effective at block. TIS creates block for some combinations of E-field orientations and amplitude ratios at very high amplitudes (>1700 V/m), whereas amplitude modulated single-carrier high-frequency stimulation cannot achieve similar effects, regardless of orientation. Conclusion: All observed effects occurred at E-field strengths that are too high to be delivered tolerably through scalp electrodes, suggesting limited significance of suprathreshold TIS. ... [Read More]
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- Total Size
- 4 files (2.45 GB)
- Data Citation
- Wang, B., Aberra, A. S., Grill, W. M., Peterchev, A. V. (2022). Data from: Responses of model cortical neurons to temporal interference stimulation and other transcranial alternating current stimulation modalities. Duke Research Data Repository. https://doi.org/10.7924/r4n87d05r
- Related Materials
- Aberra, A. S., Wang, B., Grill, W. M., & Peterchev, A. V. (2020). Simulation of transcranial magnetic stimulation in head model with morphologically-realistic cortical neurons. Brain stimulation, 13(1), 175-189. https://doi.org/10.1016/j.brs.2019.10.002.
- Wang, B., Aberra, A. S., Grill, W. M., & Peterchev, A. V. (2023). Responses of model cortical neurons to temporal interference stimulation and related transcranial alternating current stimulation modalities. Journal of neural engineering, 19(6), 066023. https://doi.org/10.1088/1741-2552/acab30.
- Aberra, A. S., Peterchev, A. V., & Grill, W. M. (2018). Biophysically realistic neuron models for simulation of cortical stimulation. Journal of neural engineering, 15(6), 066023. https://doi.org/10.1088/1741-2552/aadbb1.
- Funding Agency
- National Institutes of Health
- Grant Number
- No. R01NS117405
- No. R01NS088674
- Title
- Data from: Responses of model cortical neurons to temporal interference stimulation and other transcranial alternating current stimulation modalities
