小鸡视网膜神经节细胞的反应特性: 多电极记录研究

视网膜主要进行视觉信息的初级加工和处理. 应用多电极记录技术, 对一小块保持功能活性的小鸡视网膜上的多个神经节细胞的电活动进行同步记录, 然后通过相关非线性分析方法检测提取动作电位. 对视网膜神经节细胞群体活动特性的分析, 说明了视觉信息不仅为神经元的放电频率所编码, 也为相邻神经元的协同放电活动所携带.     

视网膜神经节细胞的信息编码特性

在脊椎动物的视觉系统中,信息的初级处理发生在视网膜。视网膜神经节细胞是视网膜唯一的输出神经元,在不同视觉刺激条件下会表现出不同的放电活动模式。研究表明视网膜神经节细胞可以利用多种编码方式,包括频率编码、时间结构编码以及群体协同编码等,有效地编码外界刺激。另外,大千世界的视觉场景变化几乎是无限的,长期的进化赋予了视网膜良好的适应能力,以实现通过有限的神经元活动对无限变化的视觉场景的编码。本文回顾了近年来关于视网膜神经节细胞编码方式和适应特性的相关研究,对多种编码方式在不同刺激下的动态改变、适应特性及生理功能进行讨论。     

视网膜神经节细胞对自然刺激的时空反应模式

神经系统信息处理的理论研究和计算结果表明,视皮层可以通过稀疏编码 (sparse coding) 模式来处理自然刺激信息.神经元群体中,单个神经元在大多数时间里没有强的脉冲发放 (时间维稀疏性,lifetime sparseness),而针对某一刺激,只有少数神经元在特定的时间内发放 (空间维稀疏性,population sparseness).从神经元放电的时间和空间模式两个方面考察了视网膜神经节细胞群体对自然刺激(电影)的编码方式,并同实验室常用的伪随机棋盘格刺激下视网膜的反应模式进行比较,分析了视网膜神经节细胞反应的稀疏性指标,并深入探讨了其内在的时间和空间特点.结果提示,视觉系统在其最初阶段——视网膜——即开始采用一种高效节能的稀疏编码方式来处理自然视觉信息,单个神经元的时间维稀疏性节省了代谢能量消耗,而群体神经元中邻近神经元的动态成组协同发放,提高了信息向突触后神经元传递的有效性.     

四指马鲅视网膜早期发育的组织学研究

本文采用石蜡连续切片技术、H.E染色和显微测量法,对四指马鲅(Eleutheronema tetradactylum)早期发育过程中视网膜的结构、分化和形成过程以及视觉特性进行了研究。结果显示,受精后8 h54 min,视杯已经形成。初孵仔鱼视网膜没有分化。2日龄仔鱼可以清晰的辨认出色素上皮层、外核层、内核层和神经节细胞层。3日龄仔鱼内核层已经分化出水平细胞、双极细胞和无长突细胞。4日龄仔鱼视网膜10层结构完整。9日龄至14日龄,外核层胞核数目与神经节细胞数目的比值增大,视网膜会聚程度升高,是该鱼视觉特性发生变化的过渡期,这与其从浮游到浅海中下层和泥沙质海底活动的生态迁移相适应。在生长发育的早期阶段,其视网膜内核层水平细胞仅有1到2层,属于感光系统不甚发达的类型。该鱼在仔鱼浮游生活阶段,视敏度较高,视觉对其行为和摄食活动具有重要作用,适应生活于光照较充足的环境中,转入浅海中下层和泥沙质海底后,光敏度和视敏度均较差,视觉在其行为和摄食活动中不具有主要作用。     

猫视网膜年龄相关的形态学变化

取老年猫(12龄,3～3．5kg)和青年猫(1～3龄,2～2．5kg)各4只的视网膜,经4％多聚甲醛处理后,用H．E．染色以显示视网膜结构,Nissl染色显示神经节细胞,免疫组织化学ABC法染色以显示星形胶质细胞特征性标志物胶质纤维酸性蛋白(GFAP)的阳性反应细胞的分布。显微镜下观察测量视网膜厚度,计数神经节细胞、GFAP免疫反应阳性细胞数。与青年猫比较,老年猫视网膜总厚度以及外核层、外网状层、内核层和内网状层厚度均显著减小;神经节细胞层的细胞密度显著下降;GFAP免疫反应阳性细胞显著增加,GFAP阳性细胞阳性反应强,胞体明显膨胀,突起稠密粗大。推测在衰老过程中视网膜细胞有神经元丢失现象,可能是造成视觉功能衰退的重要原因之一;视网膜星形胶质细胞的功能增强可能会延缓衰老。     

高浓度葡萄糖对C57小鼠视网膜神经节细胞的视觉反应特性的影响——一项离体生理研究

本研究旨在观察视网膜神经节细胞在高浓度葡萄糖下的视觉反应特性.实验中,视杯平铺于记录腔,Ames缓冲液灌流,单细胞外记录小鼠(Mus musculus)视网膜神经节细胞.实验结果表明,高糖条件下,ON神经节细胞的平均感受野大小(34.1±2.9,n=14)明显小于OFF神经节细胞的(49.3±0.3,n=12)(P0.0001).高渗条件下,可以观察到类似的模式,即ON神经节细胞的平均感受野大小小于OFF的(P0.0001).ON神经节细胞的平均亮度阈值在高糖(P0.0001)或者高渗(P0.0002)条件下明显升高.OFF神经节细胞的平均亮度阈值在相同条件下(高糖:P0.01;高渗:P0.0002)也有升高.在高渗条件下,ON神经节细胞的平均对比增益明显低于OFF神经节细胞的(P0.015).而在高糖条件下,ON神经节细胞的平均增益明显高于OFF神经节细胞的(P0.0001).这些结果表明,高糖可缩小神经节细胞的感受野,降低亮度敏感度,减弱对比增益.高糖对ON和OFF神经节细胞的影响可能是通过不同的机制进行的.     

江豚和白鱀豚视网膜神经节细胞的研究

江豚和白暨豚视网膜神经节细胞根据其形态结构可分为1、2两型。其密度分布在大多数江豚和1头白(既鱼)豚呈两个高密度区。第一高密度区位于视网膜鼻侧偏腹方,第二高密度区位于颞侧偏背方。第一和第二高密度区的细胞的最高密度在江豚大多数分别为每平方毫米250和210左右,在一例白暨豚约180和140以上。其组成、密度分布及细胞总数在采自长江和黄海沿岸的江豚之间差异不显著。在白(既鱼)豚由于大神经节细胞相对增多,细胞平均直径比江豚的大;细胞数在40微米左右处形成特有的第二个峰;2型的细胞极少,且没有发现典型的星形神经节细胞。 几种豚类的视网膜神经节细胞的比较表明,在适应弱光环境的过程中,视网膜神经节细胞的组成发生了一些改变:2型的神经节细胞逐渐减少甚至消失;大神经节细胞相对增多;神经节细胞密度减小。视觉敏度提高,锐度下降。     

青光眼视网膜神经节细胞凋亡机制研究进展

青光眼是由视网膜神经节细胞(Retinal ganglion cells,RGCs)死亡引起的一种疾病,最终能导致失明。近年来,关于高眼压(elevated intraocular pressure,IOP)引发的视网膜的特定分子途径等方面的信息逐渐增多。青光眼中视网膜神经节细胞的状态取决于视网膜神经节细胞促存活和促死亡途径之间的平衡,而有关这些反应的具体机制有较多的研究,但仍只能解释部分现象。本文综述了关于视网膜神经节细胞的凋亡、凋亡通路途径及可能引发损伤条件的最新研究进展。     

非成像视觉的光信号转导与环路结构功能

感知外界环境并做出响应是生物体的基本特征,而感光是多数生物最重要的感知觉之一.生命体为此特化出了复杂的感光机制,不仅用于形成图像视觉,也帮助生物根据光环境调节相应的生理功能,如瞳孔光反射和生物节律的光授时.这些感光功能统称为非成像视觉功能,主要由一类新近发现的自感光视网膜神经节细胞所介导.自感光视网膜神经节细胞有别于传统的视锥视杆细胞,自发现以来,逐渐积累的研究证实了这类神经元投射到丰富的皮层下结构,并参与包括睡眠节律和情绪调节等多种生理功能.本文旨在回顾有关自感光视网膜神经节细胞光信号转导与皮层下环路的重要发现和最新进展,并针对领域的趋势和待解决问题进行展望.     

视觉系统皮层下细胞的方位和方向敏感性

视觉方位、方向选择性曾被认为是高等哺乳动物视皮层细胞的特有功能。近年来大量的实验结果表明,视皮层下的外膝体神经元和视网膜神经节细胞都具一定程度的方位和方向敏感性,这些性质是遗传决定的,不受后天环境的影响。在外膝体内,已为视皮层细胞高度的方位、方向选择性和功能柱的形成做出了初步的分类与编组,提供了前级安排。这种皮层下的方位、方向敏感性细胞在发育过程中传递和加工了环境视觉信息,促进了视皮层更强的方位、方向选择性机制和方位功能柱的形成。外膝体在视觉信息平行处理通道的形成上起着分类集聚的重要作用。     

Visual pattern recognition based on spatio-temporal patterns of retinal ganglion cells’ activities

Neural information is processed based on integrated activities of relevant neurons. Concerted population activity is one of the important ways for retinal ganglion cells to efficiently organize and process visual information. In the present study, the spike activities of bullfrog retinal ganglion cells in response to three different visual patterns (checker-board, vertical gratings and horizontal gratings) were recorded using multi-electrode arrays. A measurement of subsequence distribution discrepancy (MSDD) was applied to identify the spatio-temporal patterns of retinal ganglion cells' activities in response to different stimulation patterns. The results show that the population activity patterns were different in response to different stimulation patterns, such difference in activity pattern was consistently detectable even when visual adaptation occurred during repeated experimental trials. Therefore, the stimulus pattern can be reliably discriminated according to the spatio-temporal pattern of the neuronal activities calculated using the MSDD algorithm.     

Chicken retinal ganglion cells response characteristics: multi-channel electrode recording study

The first stage of visual processing occurs in the retina, the function of which is to process the raw information obtained from the outside world. In the present study, the electrical activities of a group of retinal ganglion cells were recorded from a small functioning piece of retina, using multi-electrode array (MEA), and the action potentials were detected by applying nonlinear algorithm. By analyzing the ensemble retinal ganglion output characteristics, it is revealed that both firing rates and correlated activity between adjacent neurons in the retina contribute to visual information encoding.     

Chicken retinal ganglion cells response characteristics: multi-channel electrode recording study

A fundamental question in neuroscience is how the information relevant to behavior is presented in the activity of neurons[1]. The visual system, especially the retina, offers some advantage to explore the neural code owing to its explicitly layered structure and relatively simple neuron types[2]. However, most of what we know about retinal signaling is derived from single neuron recordings[2,3]. The assumptions underlying this approach are that individual neuron acts as a unique element dedi…     

GABAergic neurotransmission and retinal ganglion cell function

Ganglion cells are the output retinal neurons that convey visual information to the brain. There are ~20 different types of ganglion cells, each encoding a specific aspect of the visual scene as spatial and temporal contrast, orientation, direction of movement, presence of looming stimuli; etc. Ganglion cell functioning depends on the intrinsic properties of ganglion cell’s membrane as well as on the excitatory and inhibitory inputs that these cells receive from other retinal neurons. GABA is one of the most abundant inhibitory neurotransmitters in the retina. How it modulates the activity of different types of ganglion cells and what is its significance in extracting the basic features from visual scene are questions with fundamental importance in visual neuroscience. The present review summarizes current data concerning the types of membrane receptors that mediate GABA action in proximal retina; the effects of GABA and its antagonists on the ganglion cell light-evoked postsynaptic potentials and spike discharges; the action of GABAergic agents on centre-surround organization of the receptive fields and feature related ganglion cell activity. Special emphasis is put on the GABA action regarding the ON–OFF and sustained–transient ganglion cell dichotomy in both nonmammalian and mammalian retina.     

Redundancy in the population code of the retina

We have explored the manner in which the population of retinal ganglion cells collectively represent the visual world. Ganglion cells in the salamander were recorded simultaneously with a multielectrode array during stimulation with both artificial and natural visual stimuli, and the mutual information that single cells and pairs of cells conveyed about the stimulus was estimated. We found significant redundancy between cells spaced as far as 500 mum apart. When we used standard methods for defining functional types, only ON-type and OFF-type cells emerged as truly independent information channels. Although the average redundancy between nearby cell pairs was moderate, each ganglion cell shared information with many neighbors, so that visual information was represented approximately 10-fold within the ganglion cell population. This high degree of retinal redundancy suggests that design principles beyond coding efficiency may be important at the population level.     

Activity-induced long-term potentiation of excitatory synapses in developing zebrafish retina in vivo

Neural activity-induced long-term potentiation (LTP) of synaptic transmission is believed to be one of the cellular mechanisms underlying experience-dependent developmental refinement of neural circuits. Although it is well established that visual experience and neural activity are critical for the refinement of retinal circuits, whether and how LTP occurs in the retina remain unknown. Using in?vivo perforated whole-cell recording and two-photon calcium imaging, we find that both repeated electrical and visual stimulations can induce LTP at excitatory synapses formed by bipolar cells on retinal ganglion cells in larval but not juvenile zebrafish. LTP induction requires the activation of postsynaptic N-methyl-D-aspartate receptors, and its expression involves arachidonic acid-dependent presynaptic changes in calcium dynamics and neurotransmitter release. Physiologically, both electrical and visual stimulation-induced LTP can enhance visual responses of retinal ganglion cells. Thus, LTP exists in developing retinae with a presynaptic locus and may serve for visual experience-dependent refinement of retinal circuits.     

Features and functions of nonlinear spatial integration by retinal ganglion cells

Ganglion cells in the vertebrate retina integrate visual information over their receptive fields. They do so by pooling presynaptic excitatory inputs from typically many bipolar cells, which themselves collect inputs from several photoreceptors. In addition, inhibitory interactions mediated by horizontal cells and amacrine cells modulate the structure of the receptive field. In many models, this spatial integration is assumed to occur in a linear fashion. Yet, it has long been known that spatial integration by retinal ganglion cells also incurs nonlinear phenomena. Moreover, several recent examples have shown that nonlinear spatial integration is tightly connected to specific visual functions performed by different types of retinal ganglion cells. This work discusses these advances in understanding the role of nonlinear spatial integration and reviews recent efforts to quantitatively study the nature and mechanisms underlying spatial nonlinearities. These new insights point towards a critical role of nonlinearities within ganglion cell receptive fields for capturing responses of the cells to natural and behaviorally relevant visual stimuli. In the long run, nonlinear phenomena of spatial integration may also prove important for implementing the actual neural code of retinal neurons when designing visual prostheses for the eye.     

Retinal ganglion cells are autonomous circadian oscillators synthesizing N-acetylserotonin during the day

Retinal ganglion cells send visual and circadian information to the brain regarding the environmental light-dark cycles. We investigated the capability of retinal ganglion cells of synthesizing melatonin, a highly reliable circadian marker that regulates retinal physiology, as well as the capacity of these cells to function as autonomous circadian oscillators. Chick retinal ganglion cells presented higher levels of melatonin assessed by radioimmunoassay during both the subjective day in constant darkness and the light phase of a light-dark cycle. Similar changes were observed in mRNA levels and activity of arylalkylamine N-acetyltransferase, a key enzyme in melatonin biosynthesis, with the highest levels of both parameters during the subjective day. These daily variations were preceded by the elevation of cyclic-AMP content, the second messenger involved in the regulation of melatonin biosynthesis. Moreover, cultures of immunopurified retinal ganglion cells at embryonic day 8 synchronized by medium exchange synthesized a [3H]melatonin-like indole from [3H]tryptophan. This [3H]indole was rapidly released to the culture medium and exhibited a daily variation, with levels peaking 8 h after synchronization, which declined a few hours later. Cultures of embryonic retinal ganglion cells also showed self-sustained daily rhythms in arylalkylamine N-acetyltransferase mRNA expression during at least three cycles with a period near 24 h. These rhythms were also observed after the application of glutamate. The results demonstrate that chick retinal ganglion cells may function as autonomous circadian oscillators synthesizing a melatonin-like indole during the day.     

High Accuracy Decoding of Dynamical Motion from a Large Retinal Population

Motion tracking is a challenge the visual system has to solve by reading out the retinal population. It is still unclear how the information from different neurons can be combined together to estimate the position of an object. Here we recorded a large population of ganglion cells in a dense patch of salamander and guinea pig retinas while displaying a bar moving diffusively. We show that the bar’s position can be reconstructed from retinal activity with a precision in the hyperacuity regime using a linear decoder acting on 100+ cells. We then took advantage of this unprecedented precision to explore the spatial structure of the retina’s population code. The classical view would have suggested that the firing rates of the cells form a moving hill of activity tracking the bar’s position. Instead, we found that most ganglion cells in the salamander fired sparsely and idiosyncratically, so that their neural image did not track the bar. Furthermore, ganglion cell activity spanned an area much larger than predicted by their receptive fields, with cells coding for motion far in their surround. As a result, population redundancy was high, and we could find multiple, disjoint subsets of neurons that encoded the trajectory with high precision. This organization allows for diverse collections of ganglion cells to represent high-accuracy motion information in a form easily read out by downstream neural circuits.     

An instructive role for patterned spontaneous retinal activity in mouse visual map development

Complex neural circuits in the mammalian brain develop through a combination of genetic instruction and activity-dependent refinement. The relative role of these factors and the form of neuronal activity responsible for circuit development is a matter of significant debate. In the mammalian visual system, retinal ganglion cell projections to the brain are mapped with respect to retinotopic location and eye of origin. We manipulated the pattern of spontaneous retinal waves present during development without changing overall activity levels through the transgenic expression of β2-nicotinic acetylcholine receptors in retinal ganglion cells of mice. We used this manipulation to demonstrate that spontaneous retinal activity is not just permissive, but instructive in the emergence of eye-specific segregation and retinotopic refinement in the mouse visual system. This suggests that specific patterns of spontaneous activity throughout the developing brain are essential in the emergence of specific and distinct patterns of neuronal connectivity.