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视网膜神经元对高频刺激的反应。

The response of retinal neurons to high-frequency stimulation.

机构信息

VA Boston Healthcare System, Boston, MA, USA.

出版信息

J Neural Eng. 2013 Jun;10(3):036009. doi: 10.1088/1741-2560/10/3/036009. Epub 2013 Apr 18.

DOI:10.1088/1741-2560/10/3/036009
PMID:23594620
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3712762/
Abstract

OBJECTIVE

High-rate pulse trains have proven to be effective in cochlear prosthetics and, more recently, have been shown to elicit a wide range of interesting response properties in axons of the peripheral nervous system. Surprisingly, the effectiveness of such trains for use in retinal prostheses has not been explored.

APPROACH

Using cell-attached patch clamp methods, we measured the in vitro response of two rabbit retinal ganglion cell types, OFF-brisk transient (OFF-BT) and ON-OFF directionally selective (DS), to trains of biphasic pulses delivered at 2000 pulses per second (PPS).

MAIN RESULTS

For OFF-BT cells, response onset occurred at 20 µA, and maximum response occurred at ~40 µA. Interestingly, spiking levels decreased for further increases in amplitude. In contrast, DS cells had a spiking onset at ~25 µA and maintained strong spiking as stimulus amplitude was increased, even at the highest levels tested. Thus, a low-amplitude stimulus train at 2000 PPS (25 µA) will activate OFF-BT cells strongly, while simultaneously activating DS cells only weakly. In contrast, a high amplitude train (~75 µA) will activate DS cells strongly while suppressing responses in OFF-BT cells.

SIGNIFICANCE

The response differences between cell types suggest some forms of preferential activation may be possible, and further testing is warranted. Further, the scope of the response differences found here suggests activation mechanisms that are more complex than those described in previous studies.

摘要

目的

高通率脉冲串已被证明在耳蜗假体中非常有效,最近,它们在周围神经系统的轴突中也表现出了广泛的有趣的反应特性。令人惊讶的是,这种脉冲串在视网膜假体中的有效性尚未得到探索。

方法

使用细胞贴附式膜片钳方法,我们测量了两种兔视网膜神经节细胞类型,OFF 型瞬态(OFF-BT)和 ON-OFF 方向选择性(DS),对每秒 2000 个脉冲(PPS)的双相脉冲串的体外反应。

主要结果

对于 OFF-BT 细胞,反应起始发生在约 20 µA,最大反应发生在约 40 µA。有趣的是,随着振幅的进一步增加, spikes 水平下降。相比之下,DS 细胞在约 25 µA 时开始 spikes,并随着刺激幅度的增加保持强烈的 spikes,即使在测试的最高水平也是如此。因此,2000 PPS(约 25 µA)的低幅度刺激脉冲串将强烈激活 OFF-BT 细胞,而同时仅弱激活 DS 细胞。相比之下,高幅度脉冲串(约 75 µA)将强烈激活 DS 细胞,同时抑制 OFF-BT 细胞的反应。

意义

细胞类型之间的反应差异表明可能存在某种形式的优先激活,需要进一步测试。此外,这里发现的反应差异范围表明激活机制比以前的研究中描述的更复杂。

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