An efficient and practical electrode optimization method for transcranial electrical stimulation_Journal of Biomedical Engineering

Authors：

XIE Xu ^1,2 ,  WANG Minmin ^1,2 , ZHANG Shaomin ²

1. College of Biomedical Engineering & Instrument science, Zhejiang University, Hangzhou 310027, P. R. China;
2. Key Laboratory for Biomedical Engineering of Ministry of Education, Qiushi Academy for Advanced Studies, Zhejiang University, Hangzhou 310027, P. R. China;

Corresponding?author：

WANG Minmin, Email: minminwang@zju.edu.cn

Keywords：

Transcranial electrical stimulation; Electrode optimization; Efficient computation; Finite element

DOI：

10.7507/1001-5515.202308016

Video：

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Transcranial electrical stimulation (TES) is a non-invasive neuromodulation technique with great potential. Electrode optimization methods based on simulation models of individual TES field could provide personalized stimulation parameters according to individual variations in head tissue structure, significantly enhancing the stimulation accuracy of TES. However, the existing electrode optimization methods suffer from prolonged computation times (typically exceeding 1 d) and limitations such as disregarding the restricted number of output channels from the stimulator, further impeding their clinical applicability. Hence, this paper proposes an efficient and practical electrode optimization method. The proposed method simultaneously optimizes both the intensity and focality of TES within the target brain area while constraining the number of electrodes used, and it achieves faster computational speed. Compared to commonly used electrode optimization methods, the proposed method significantly reduces computation time by 85.9% while maintaining optimization effectiveness. Moreover, our method considered the number of available channels for the stimulator to distribute the current across multiple electrodes, further improving the tolerability of TES. The electrode optimization method proposed in this paper has the characteristics of high efficiency and easy operation, potentially providing valuable supporting data and references for the implementation of individualized TES.

Citation： XIE Xu, WANG Minmin, ZHANG Shaomin. An efficient and practical electrode optimization method for transcranial electrical stimulation. Journal of Biomedical Engineering, 2024, 41(4): 724-731, 741. doi: 10.7507/1001-5515.202308016 Copy

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2.	Palm U, Hasan A, Strube W, et al. tDCS for the treatment of depression: a comprehensive review. European Archives of Psychiatry and Clinical Neuroscience, 2016, 266(8): 681-694..
3.	Sudbrack-Oliveira P, Barbosa M Z, Thome-Souza S, et al. Transcranial direct current stimulation (tDCS) in the management of epilepsy: a systematic review. Seizure, 2021, 86: 85-95..
4.	楊鈺琳, 常萬鵬, 丁江濤, 等. 經顱直流電刺激不同靶點治療帕金森病效果的網狀Meta分析. 中國組織工程研究, 2024, 28(11): 1797-1804..
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6.	Javadi A H, Cheng P. Transcranial direct current stimulation (tDCS) enhances reconsolidation of long-term memory. Brain Stimulation, 2013, 6(4): 668-674..
7.	亓朔, 劉宇, 王曉慧. 經顱直流電刺激提升運動表現的生理機制. 神經解剖學雜志, 2023, 39(1): 119-122..
8.	張娜, 劉卉, 苗雨, 等. 經顱電刺激技術用于運動表現提升的研究進展. 中國生物醫學工程學報, 2022, 41(2): 214-223..
9.	郭婭美, 李啟杰, 姜勁, 等. 基于認知訓練和經顱直流電刺激組合的認知增強技術綜述. 生物醫學工程學雜志, 2020, 37(5): 903-909..
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11.	劉盼, 劉世文. 經顱直流電刺激的研究及應用. 中國組織工程研究與臨床康復, 2011, 15(39): 7379-7383..
12.	Caulfield K A, George M S. Optimized APPS-tDCS electrode position, size, and distance doubles the on-target stimulation magnitude in 3000 electric field models. Scientific Reports. 2022, 12(1): 20116..
13.	關龍舟, 魏云, 李小俚. 經顱電刺激—一項具有發展前景的腦刺激技術. 中國醫療設備, 2015, 30(11): 1-5..
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21.	Zhu S, Wang M, Ma M, et al. An optimization approach for transcranial direct current stimulation using nondominated sorting genetic algorithm II. Annu Int Conf IEEE Eng Med Biol Soc, 2021: 4337-4340..
22.	Wang M, Lou K, Liu Z, et al. Multi-objective optimization via evolutionary algorithm (MOVEA) for high-definition transcranial electrical stimulation of the human brain. NeuroImage, 2023, 280: 120331..
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24.	Esmaeilpour Z, Milosevic M, Azevedo K, et al. Intracranial voltage recording during transcranial direct current stimulation (TDCS) in human subjects with validation of a standard model. Brain Stimulation, 2017, 10: 72-75..
25.	Huang Y, Dmochowski J P, Su Y, et al. Automated MRI segmentation for individualized modeling of current flow in the human head. Journal of Neural Engineering. 2013, 10(6): 066004..
26.	朱晟華. 經顱直流電刺激的電極優化及應用. 杭州: 浙江大學, 2021..
27.	Ashburner J, Friston K J. Unified segmentation. NeuroImage, 2005, 26(3): 839-851..
28.	Huang Y, Datta A, Bikson M, et al. Realistic volumetric-approach to simulate transcranial electric stimulation–ROAST–a fully automated open-source pipeline. Journal of Neural Engineering. 2019, 16(5): 056006..
29.	Caulfield K A, Indahlastari A, Nissim N R, et al. Electric field strength from prefrontal transcranial direct current stimulation determines degree of working memory response: a potential application of reverse-calculation modeling?. Neuromodulation: Technology at the Neural Interface, 2022, 25(4): 578-587..
30.	Faria P, Hallett M, Miranda P C. A finite element analysis of the effect of electrode area and inter-electrode distance on the spatial distribution of the current density in tDCS. Journal of Neural Engineering, 2011, 8(6): 066017..
31.	Lynch C J, Elbau I G, Ng T H, et al. Automated optimization of TMS coil placement for personalized functional network engagement. Neuron, 2022, 110(20): 3263-3277..

1. Nitsche M A, Paulus W. Excitability changes induced in the human motor cortex by weak transcranial direct current stimulation. Journal of Physiology, 2000, 527(3): 633-639..
2. Palm U, Hasan A, Strube W, et al. tDCS for the treatment of depression: a comprehensive review. European Archives of Psychiatry and Clinical Neuroscience, 2016, 266(8): 681-694..
3. Sudbrack-Oliveira P, Barbosa M Z, Thome-Souza S, et al. Transcranial direct current stimulation (tDCS) in the management of epilepsy: a systematic review. Seizure, 2021, 86: 85-95..
4. 楊鈺琳, 常萬鵬, 丁江濤, 等. 經顱直流電刺激不同靶點治療帕金森病效果的網狀Meta分析. 中國組織工程研究, 2024, 28(11): 1797-1804..
5. 徐盼盼, 練濤. 經顱直流電刺激在記憶障礙治療的研究進展. 安徽醫藥, 2023, 27(6): 1069-1072..
6. Javadi A H, Cheng P. Transcranial direct current stimulation (tDCS) enhances reconsolidation of long-term memory. Brain Stimulation, 2013, 6(4): 668-674..
7. 亓朔, 劉宇, 王曉慧. 經顱直流電刺激提升運動表現的生理機制. 神經解剖學雜志, 2023, 39(1): 119-122..
8. 張娜, 劉卉, 苗雨, 等. 經顱電刺激技術用于運動表現提升的研究進展. 中國生物醫學工程學報, 2022, 41(2): 214-223..
9. 郭婭美, 李啟杰, 姜勁, 等. 基于認知訓練和經顱直流電刺激組合的認知增強技術綜述. 生物醫學工程學雜志, 2020, 37(5): 903-909..
10. Edwards D J, Cortes M, Wortman-Jutt S, et al. Transcranial direct current stimulation and sports performance. Frontiers in Human Neuroscience, 2017, 11: 243..
11. 劉盼, 劉世文. 經顱直流電刺激的研究及應用. 中國組織工程研究與臨床康復, 2011, 15(39): 7379-7383..
12. Caulfield K A, George M S. Optimized APPS-tDCS electrode position, size, and distance doubles the on-target stimulation magnitude in 3000 electric field models. Scientific Reports. 2022, 12(1): 20116..
13. 關龍舟, 魏云, 李小俚. 經顱電刺激—一項具有發展前景的腦刺激技術. 中國醫療設備, 2015, 30(11): 1-5..
14. Edwards D, Cortes M, Datta A, et al. Physiological and modeling evidence for focal transcranial electrical brain stimulation in humans: a basis for high-definition tDCS. NeuroImage, 2013, 74: 266-275..
15. Dmochowski J P, Datta A, Bikson M, et al. Optimized multi-electrode stimulation increases focality and intensity at target. Journal of Neural Engineering. 2011, 8(4): 046011..
16. Khan A, Haueisen J, Wolters C H, et al. Constrained maximum intensity optimized multi-electrode tDCS targeting of human somatosensory network. Annu Int Conf IEEE Eng Med Biol Soc, 2019: 5894-5897..
17. Khan A, Antonakakis M, Vogenauer N, et al. Individually optimized multi-channel tDCS for targeting somatosensory cortex. Clinical Neurophysiology. 2022, 134: 9-26..
18. Wagner S, Burger M, Wolters C H. An optimization approach for well-targeted transcranial direct current stimulation. SIAM Journal on Applied Mathematics. 2016, 76(6): 2154-2174..
19. Wang Y, Brand J, Liu W. Stimulation montage achieves balanced focality and intensity. Algorithms. 2022, 15(5): 169..
20. Antal A, Alekseichuk I, Bikson M, et al. Low intensity transcranial electric stimulation: safety, ethical, legal regulatory and application guidelines. Clinical Neurophysiology. 2017, 128(9): 1774-1809..
21. Zhu S, Wang M, Ma M, et al. An optimization approach for transcranial direct current stimulation using nondominated sorting genetic algorithm II. Annu Int Conf IEEE Eng Med Biol Soc, 2021: 4337-4340..
22. Wang M, Lou K, Liu Z, et al. Multi-objective optimization via evolutionary algorithm (MOVEA) for high-definition transcranial electrical stimulation of the human brain. NeuroImage, 2023, 280: 120331..
23. Ruffini G, Fox M D, Ripolles O, et al. Optimization of multifocal transcranial current stimulation for weighted cortical pattern targeting from realistic modeling of electric fields. NeuroImage, 2014, 89(5): 216-225..
24. Esmaeilpour Z, Milosevic M, Azevedo K, et al. Intracranial voltage recording during transcranial direct current stimulation (TDCS) in human subjects with validation of a standard model. Brain Stimulation, 2017, 10: 72-75..
25. Huang Y, Dmochowski J P, Su Y, et al. Automated MRI segmentation for individualized modeling of current flow in the human head. Journal of Neural Engineering. 2013, 10(6): 066004..
26. 朱晟華. 經顱直流電刺激的電極優化及應用. 杭州: 浙江大學, 2021..
27. Ashburner J, Friston K J. Unified segmentation. NeuroImage, 2005, 26(3): 839-851..
28. Huang Y, Datta A, Bikson M, et al. Realistic volumetric-approach to simulate transcranial electric stimulation–ROAST–a fully automated open-source pipeline. Journal of Neural Engineering. 2019, 16(5): 056006..
29. Caulfield K A, Indahlastari A, Nissim N R, et al. Electric field strength from prefrontal transcranial direct current stimulation determines degree of working memory response: a potential application of reverse-calculation modeling?. Neuromodulation: Technology at the Neural Interface, 2022, 25(4): 578-587..
30. Faria P, Hallett M, Miranda P C. A finite element analysis of the effect of electrode area and inter-electrode distance on the spatial distribution of the current density in tDCS. Journal of Neural Engineering, 2011, 8(6): 066017..
31. Lynch C J, Elbau I G, Ng T H, et al. Automated optimization of TMS coil placement for personalized functional network engagement. Neuron, 2022, 110(20): 3263-3277..

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An efficient and practical electrode optimization method for transcranial electrical stimulation

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