多电极经颅电刺激能到达深部靶区吗?
Can transcranial electric stimulation with multiple electrodes reach deep targets?
机构信息
Department of Biomedical Engineering, City College of the City University of New York, United States.
Department of Biomedical Engineering, City College of the City University of New York, United States.
出版信息
Brain Stimul. 2019 Jan-Feb;12(1):30-40. doi: 10.1016/j.brs.2018.09.010. Epub 2018 Sep 26.
Abstract
To reach a deep target in the brain with transcranial electric stimulation (TES), currents have to pass also through the cortical surface. Thus, it is generally thought that TES cannot achieve focal deep brain stimulation. Recent efforts with interfering waveforms and pulsed stimulation have argued that one can achieve deeper or more intense stimulation in the brain. Here we argue that conventional transcranial stimulation with multiple current sources is just as effective as these new approaches. The conventional multi-electrode approach can be numerically optimized to maximize intensity or focality at a desired target location. Using such optimal electrode configurations we find in a detailed and realistic head model that deep targets may in fact be strongly stimulated, with cerebro-spinal fluid guiding currents deep into the brain.
摘要
为了用电刺激(transcranial electric stimulation, TES)到达大脑深处的目标,电流也必须穿过皮质表面。因此,人们普遍认为 TES 不能实现焦点深部脑刺激。最近使用干扰波形和脉冲刺激的研究表明,可以在大脑中实现更深或更强的刺激。在这里,我们认为传统的多电流源经颅刺激与这些新方法一样有效。传统的多电极方法可以通过数值优化,在所需的目标位置上最大限度地提高强度或聚焦性。使用这种最优的电极配置,我们在一个详细和现实的头部模型中发现,深部目标实际上可能受到强烈刺激,脑脊液引导电流深入大脑。
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