关键的发现是,DBS似乎调整的是一组的大脑区域,而不仅仅是电极周围的区域。
The crucial discovery is that DBS seems to tune an array of brain regions, not just the area around the electrode.
通过调整背电极浆料和电池基片厚度,探索了减少太阳电池弯曲度的途径。
The approaches have been explored to reduce the bending of solar cell by adjusting the back electrode paste and the thickness of silicon substrate.
数值模拟结果表明,在放电期间恰当地调整电极上的驱动电位,可以改变介质层表面电荷积累,获得较高的壁电压。
The results show that after triggering discharge, the wall charges can be varied by adjusting the driving waveform, and the high wall voltage can be obtained.
它可以根据水的电导率,自动调整电极的电流值。
It can be based on the conductivity of the water current and automatically adjust the value of the electrode.
调整电极位置,改进电极结构;
结论MRI图像直接定位STN较准确,微电极记录和植入电极刺激能对靶点定位作进一步验证和适当调整。
Conclusions Direct MRI targeting is an accurate method for STN localization. Microelectrode recording and macrostimulation are helpful targeting adjunct.
结论MRI图像直接定位STN较准确,微电极记录和植入电极刺激能对靶点定位作进一步验证和适当调整。
Conclusions Direct MRI targeting is an accurate method for STN localization. Microelectrode recording and macrostimulation are helpful targeting adjunct.
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