Samba R, Herrmann T, Zeck G
Natural and Medical Sciences Institute, Markwiesenstrasse 55, D-72770 Reutlingen, Germany.
J Neural Eng. 2015 Feb;12(1):016014. doi: 10.1088/1741-2560/12/1/016014. Epub 2015 Jan 14.
The aim of this study was to compare two different microelectrode materials--the conductive polymer composite poly-3,4-ethylenedioxythiophene (PEDOT)-carbon nanotube(CNT) and titanium nitride (TiN)--at activating spikes in retinal ganglion cells in whole mount rat retina through stimulation of the local retinal network. Stimulation efficacy of the microelectrodes was analyzed by comparing voltage, current and transferred charge at stimulation threshold.
Retinal ganglion cell spikes were recorded by a central electrode (30 μm diameter) in the planar grid of an electrode array. Extracellular stimulation (monophasic, cathodic, 0.1-1.0 ms) of the retinal network was performed using constant voltage pulses applied to the eight surrounding electrodes. The stimulation electrodes were equally spaced on the four sides of a square (400 × 400 μm). Threshold voltage was determined as the pulse amplitude required to evoke network-mediated ganglion cell spiking in a defined post stimulus time window in 50% of identical stimulus repetitions. For the two electrode materials threshold voltage, transferred charge at threshold, maximum current and the residual current at the end of the pulse were compared.
Stimulation of retinal interneurons using PEDOT-CNT electrodes is achieved with lower stimulation voltage and requires lower charge transfer as compared to TiN. The key parameter for effective stimulation is a constant current over at least 0.5 ms, which is obtained by PEDOT-CNT electrodes at lower stimulation voltage due to its faradaic charge transfer mechanism.
In neuroprosthetic implants, PEDOT-CNT may allow for smaller electrodes, effective stimulation in a safe voltage regime and lower energy-consumption. Our study also indicates, that the charge transferred at threshold or the charge injection capacity per se does not determine stimulation efficacy.
本研究旨在比较两种不同的微电极材料——导电聚合物复合材料聚3,4 - 乙烯二氧噻吩(PEDOT)- 碳纳米管(CNT)和氮化钛(TiN)——通过刺激局部视网膜网络来激活大鼠视网膜全层标本中视网膜神经节细胞的放电。通过比较刺激阈值时的电压、电流和转移电荷来分析微电极的刺激效果。
在电极阵列的平面网格中,用中心电极(直径30μm)记录视网膜神经节细胞的放电。使用施加到八个周围电极上的恒压脉冲对视网膜网络进行细胞外刺激(单相、阴极、0.1 - 1.0 ms)。刺激电极在正方形(400×400μm)的四条边上等距分布。阈值电压被确定为在50%的相同刺激重复中,在规定的刺激后时间窗口内诱发网络介导的神经节细胞放电所需的脉冲幅度。比较了两种电极材料的阈值电压、阈值时的转移电荷、最大电流和脉冲结束时的残余电流。
与TiN相比,使用PEDOT - CNT电极刺激视网膜中间神经元所需的刺激电压更低,电荷转移量也更低。有效刺激的关键参数是至少0.5 ms的恒定电流,由于其法拉第电荷转移机制,PEDOT - CNT电极在较低的刺激电压下就能获得该电流。
在神经假体植入中,PEDOT - CNT可能允许使用更小的电极,在安全的电压范围内进行有效刺激并降低能耗。我们的研究还表明,阈值时转移的电荷或电荷注入能力本身并不能决定刺激效果。
