猴运动前区皮层神经元在顺序行为中的放电活动

本工作猴运动前区（ＰＭ）皮层神经元在视觉图表引导的有序运动行为中的放电活动,并在与记忆信息完成的空间顺序行为（ＭＳＳ）中的活动作了比较。为为训练三只猴同时学会ＦＲＳ和ＭＳＳ任务。对１１１个神经元的统计分析表明,它们在ＦＲＭＳ和ＭＳＳ暗示期中发生放电频率变化的均有一半以上。反应期里有放电频率变化的比例也很高;图形期里,ＦＲＳ中的比例比ＭＳＳ中的高出很多。它们对不同运动顺序呈现明显的选择性。对在动物完     

猕猴F2及F4区皮层神经元在图形引导的有序运动中放电活动的比较

用细胞外记录的方法研究了猕猴在执行图形辨认引导的有序运动（ＦＲＳ）时大脑皮层弓形沟距周围背外侧运动前皮层（ＰＭｄ）Ｆ２区和腹外侧运动前皮层（ＰＭｖ）Ｆ４区的放电活动在ＦＲＳ的暗示期,Ｆ２和Ｆ４区中分别有５２％（３９／７５）和１６．９％（１３／７７）的细胞发生放电变化;在触摸反应期,各有５１％（３８／７５）和８７％（６７／７７）的细胞发生放电变化,经统计检验,均有显著差异。Ｆ２区比Ｆ４区有更多细胞对     

延髓头端腹外侧区神经元电活动与心血管活动相干性的研究

本文分析了大鼠延头端腹外侧区（ＲＶＬＭ）神经元单位活动与心血管活动的相干性,观察了ＲＶＬＭ区神经元电 对电刺激中脑防御反应区的诱发反应,以及对压力感受性反射的反应,并用ＦＦＴ对ＲＶＬＭ区神经元自发单位放电和血压波进行频域的相干性分析,以判断是具有心节律。还分析了ＲＶＬＭ区单位放电变异性与心率变异性的相干性。结果显示：ＲＶＬＭ区大多数神经元对电刺激中脑防御反应区呈兴奋反应（６７％）,７０％神经元放电     

猫皮层18区神经元整合野特性的研究

用双重正弦调制移动光栅图形研究了猫皮层１８区神经元整合野特性。同在１７区所观察到的结果一样,在１８区神经元传统感受野（ＣＲＦ）的外面,也存在着大范围的易化或抑制性整合野（ＩＦ）。抑制和易化性ＩＦ神经元分别占７０％和３０％。ＩＦ对刺激光栅的时间频率、空间频率、方位和方向都有选择性。对大多数细胞来说,ＩＦ的这些调谐特性都与其对应的ＣＲＦ的特性相似。以上结果提示,１８区神经元能够对ＣＲＦ和ＩＦ内的图形特征进行整合,这种整合在复杂图形识别中起重要作用。     

刺激中缝背核调制小脑间位核神经元电活动

刺激中缝背核（ｄｏｒｓａｌｒａｐｈｅｎｕｃｌｅｕｓ,ＤＲ）可以引起小脑间位核（ｉｎｔｅｒｐｏｓｅｄｎｕｃｌｅｕｓ,ＩＮ）神经元抑制,兴奋和双相（抑制－兴奋和兴奋－抑制）３种不同类型的反应,其中以抑制反应为主（７６．０％）,多数细胞的反应潜伏期〈３０ｍｓ。ＩＮ细胞的自发放电频率为５－１２０Ｈｚ,自发放电频率高的神经元群体对ＤＲ刺激的反应率却比自发放电频率低的群体低。静脉注射５－ＨＴ２／１ｃ受体阻断剂     

刺激下丘脑弓状核或垂体前叶对丘脑束旁核神经元伤害性反应的抑制

采用电生理学方法,观察电刺激大鼠下丘脑弓状核（ＡＲＣ）或垂体前叶（ＡＬ）,对丘脑束旁核（Ｐｆ）神经元伤害性反应的影响。实验结果表明,电刺激ＡＲＣ能抑制Ｐｆ神经元的伤害性放电,这种抑制很快出现,也很快恢复,称为即时抑制。电刺激Ａ辄能抑制Ｐｆ神经元的伤害性放电,这种抑制的出现有一定的潜伏期,并持续较长时间,称为延迟抑制。摘除垂体减弱刺激ＡＲＣ的即时抑制,而损毁ＡＲＣ则减弱刺激ＡＬ的延迟抑制。地塞米松预     

反差极性敏感型运动边缘检测神经元的计算模型

在栖类、在和哺乳类某些运动的视觉系统中发现 对刺激反差极性（变亮或变暗）敏感的运动边缘检测神经元。为揭示这类神经元的信息加工原理,以Ｗｉｍｂｂａｕｅｒ等人提出了捍延ｉｎｓｋｅｒ网络为基础,将不同的时空动态受野线性组合,建立了蟾蜍神经节Ｒ３类神经元和家鸽岛豆（ｎＬＭ）神经元的感受野模型,并模拟了Ｒ３凶对蠕虫样刺激物的“头／尾偏爱”特征,细胞对刺激物的选择性以及ｎＬＭ神经元对运动边缘的反差、方向、边缘     

神经元诱发反应与自发放电的关系

分析上丘神经元光诱发反应与其背景放电频率的关系。结果见到：根据密度迭加直方图判断呈兴奋反应的单位,背景放电频率高的反应变化率小,反之则大。呈抑制反应的单位,背景放电频率低的反应变化率小,反之则大。部分无明显反应的单位,背景放电频率低时,呈兴奋反应,北京放电频率高时,呈抑制反应。提示：对神经元活动的分析,如果仅以密度迭加直方图判断有无反应而忽视与背景放电频率的关系,将丢失部分阳性反应单位。     

蛋白激酶A介导慢性压迫背根节神经元的肾上腺素能兴奋反应

本实验在奶节（ＤＲＧ）慢性压迫模型上,采用离体灌流ＤＲＧ和单纤维记录神经元自发放电的方法研究了初级感觉神经元的交感－感觉耦联作用及其细胞内机制。用外源性支甲肾上腺素（ＮＥ,１０μｍｏｌ／Ｌ）浸浴损伤的ＤＲＧ时,在９５个ＤＲＧ神经元中有８５个自发放电的神经元产生明显反应。其中,４４个呈现单纯兴奋效应,２１个表现先兴奋后抑制效应,６个出现兴奋－抑制交替振荡现象,１４个表现抑制效应。ＮＥ对损伤神经元的兴     

免疫分子起源和进化研究新进展

脑如何控制眼睛运动,一直是神经科学家研究的前沿课题之一。近日,中国科学家在家鸽外展神经核里记录到297个神经元,按放电模式与眼睛运动的关系分为3类：位移神经元在扫视前20毫秒开始放电,持续到扫视结束;振荡神经元每次发放5～6簇脉冲,每簇脉冲对应眼睛的1次振荡;扫视神经元则在持续性放电的同时,对应眼睛振荡产生几簇脉冲。     

Monochromatic and polychromatic visual backgrounds influence the response of area 17 and 18 neurons after stimulation with stationary and moving light bars

The role of colour vision in night-active cats has not been elucidated completely hitherto. In order to assess the colour sensitivity in cat cortical neurons we used large isoluminant computer-generated monochromatic and polychromatic background stimuli which were superimposed on moving and stationary (on/off) light bars. Background stimuli were moved at different speeds either inphase or antiphase. The modulatory effect of the visual noise on the neuronal bar was the primary objective of the study. The maximum amplitudes of some 40% of the neurons tested was influenced by both moving and stationary bars. About two thirds of amplitude-sensitive cells showed aldo altered direction selectivity. Latencies and field widths, on the other hand, turned out to be rather stable. The retino-cortical conduction time was not influenced either. In conclusion, a large portion of cat cortical visual neurons is remarkably sensitive to the spectral composition of the visual noise process surrounding the stimulating light bar.     

Isoluminant monochromatic and polychromatic visual backgrounds alter response characteristics of cat visual neurons after stimulation with stationary and moving light bars

The role of colour vision in night-active cats has not been elucidated completely hitherto. In order to assess the colour sensitivity in cat cortical neurons we used large isoluminant computer-generated monochromatic and polychromatic background stimuli which were superimposed on moving and stationary (on/off) light bars. Background stimuli were moved at different speeds either inphase or antiphase. The modulatory effect of the visual noise on the neuronal bar was the primary objective of the study. The maximum PSTH peaks of some 40% of the neurons tested was influenced by both moving and stationary bars. About 2 thirds of maximum peak-sensitive cells showed also altered direction selectivity. Latencies and field widths, on the other hand, turned out to be rather stable. The retino-cortical conduction time was not influenced either. In conclusion, a large portion of cat cortical visual neurons is remarkably sensitive to the spectral composition of the visual noise process surrounding the stimulating light bar.     

Edge preference of retinal and tectal neurons in common toads (Bufo bufo) in response to worm-like moving stripes: the question of behaviorally relevant ‘position indicators’

Summary Previous experiments have shown that during prey-catching behavior (orienting, snapping) in response to a worm-like moving stripe common toads.Bufo bufo (L.) exhibit a contrast-and direction-dependent edge preference. To a black (b) stripe moving against a white (w) background (b/w), they respond (R^*) preferably toward the leading (l) rather the trailing (t) edge (R _l ^* > R _t ^* ), thus displaying head preference. If the contrastdirection is reversed (w/b), the stripe's trailing edge is preferred (R _l ^* < R _t ^* ), hence showing tail preference. In the present study, neuronal activities of retinal classes R2 and R3 and tectal classes T5(2) and T7 have been extracellularly recorded in response to leading and trailing edges of a 3 ° × 30 ° stripe simulating a worm and traversing the centers of their excitatory receptive fields (ERF) horizontally at a constant angular velocity in variable movement direction (temporo-nasal or naso-temporal).The behavioral contrast-direction dependent edge preferences are best resembled by the responses (R) of prey-selective class T5(2) neurons (R_l R_t=101 for b/w, 0.31 for w/b) and T7 neurons (R_lR_t=61 for b/w, 0.41 for w/b); the T7 responses may be dendritic spikes. This property can be traced back to off-responses dominated retinal class R3 neurons (R_lR_t=61 for b/w, 0.51 for w/b), but not to class R2 (R_lR_t =1.21 for b/w and 0.91 for w/b). The respective edge preference phenomena are independent of the direction of movement.When stimuli were moved against a stationary black-white structured background, the head preference to the black stripe and the tail preference to the white stripe were maintained in class R3, T5(2), and T7 neurons. If the stripe traversed the ERF together with the structured background in the same direction at the same velocity, the responses of tectal class T5(2) and T7 neurons were strongly inhibited, particularly in the former. Responses of retinal R2 neurons in comparable situations could be reduced by about 50%, while class R3 neurons responded to both the stimulus and the moving background structure.The results support the concept that the prey feature analyzing system in toads applies principles of (i) parallel and (ii) hierarchial information processing. These are (i) divergence of retinal R3 neuronal output contributes to stimulus edge positioning and (in combination with R2 output) area evaluation intectal neurons and to stimulus area evaluation and (in combination with R4 output) sensitivity for moving background structures inpre tectal neurons; (ii) convergence of tectal excitatory and pretectal inhibitory inputs specify the property of prey-selective tectal T5(2) neurons which are known to project to bulbar/spinal motor systems.Abbreviations ERF excitatory receptive field - IRF inhibitory receptive field - N nasal - T temporal - R _w response to a worm-like stripe moving in the direction of its longer axis - R _A response to an antiworm-like stripe whose longer axis is oriented perpendicular to the direction of movement - R _l response to the leading edge of a worm-like moving stripe - R _t response to the trailing edge of a worm-like moving stripe - b/w black stimulus against a white background - w/b white stimulus against a black background - sm structured moving background - ss structured stationary background - u minimal structure width of a structured background consisting of rectangular black and white patches in random distribution - HRP horseradish peroxidase     

Iterative cooperation between parallel pathways for object and background motion

In a typical visual scene, one or more objects move relative to a larger background, which can itself be in motion as a result of the observer’s eyes moving with respect to the outside world. Here we show that accurate estimation of the background motion from an image velocity field can be accomplished through an iterative cooperation between two modules: one that specializes in calculating a weighted average velocity and another one calculating a velocity contrast map. We build on our analysis to provide a model for the tectum-pretectum loop in the nonmammalian midbrain. Our model accounts for some of the known properties of the tectal neurons (sensitivity to relative motion) and pretectal neurons (sensitivity to whole-field motion). It also agrees with our knowledge of the pretectotectal projection (divergent and inhibitory), and with the results of lesion studies in which the pretectal input to the tectum was removed, leading to hyperactivity of the tectal neurons and the animal. Our model also makes a testable prediction regarding the tectopretectal projection, i.e., that the presence of a larger object and a bigger discrepancy between the directions of motion for the object and the background lead to a larger error by the pretectum in estimating the background motion when the tectal input is abolished.     

Responses of tectal neurons to contrasting stimuli: an electrophysiological study in the barn owl

The saliency of visual objects is based on the center to background contrast. Particularly objects differing in one feature from the background may be perceived as more salient. It is not clear to what extent this so called "pop-out" effect observed in humans and primates governs saliency perception in non-primates as well. In this study we searched for neural-correlates of pop-out perception in neurons located in the optic tectum of the barn owl. We measured the responses of tectal neurons to stimuli appearing within the visual receptive field, embedded in a large array of additional stimuli (the background). Responses were compared between contrasting and uniform conditions. In a contrasting condition the center was different from the background while in the uniform condition it was identical to the background. Most tectal neurons responded better to stimuli in the contrsating condition compared to the uniform condition when the contrast between center and background was the direction of motion but not when it was the orientation of a bar. Tectal neurons also preferred contrasting over uniform stimuli when the center was looming and the background receding but not when the center was receding and the background looming. Therefore, our results do not support the hypothesis that tectal neurons are sensitive to pop-out per-se. The specific sensitivity to the motion contrasting stimulus is consistent with the idea that object motion and not large field motion (e.g., self-induced motion) is coded in the neural responses of tectal neurons.     

Saccadic tracking of a light grey target in the mantis,Tenodera aridifolia

I presented a horizontally moving square on a computer display to the mantis, Tenodera aridifolia, and examined the effects of target brightness and velocity, and background brightness on its tracking behavior. The mantis tracked a light grey square with more saccadic head movements than a black square, although these squares moved on a homogeneous background. The amplitude of saccades was larger when the light grey square moved at a lower velocity. The background brightness had little effect on the type (smooth or saccadic) of tracking behavior. These results suggest that the saccadic tracking of light grey objects on a homogeneous background may not be caused by low contrast, i.e., the difficulty in discriminating the object from the background. The possible biological significance of saccadic tracking on a homogenous background is discussed.     

Deep tectal cells in pigeons respond to kinematograms

Summary Deep tectal neurons in pigeons respond selectively to moving visual stimuli, and are inhibited by large background patterns moved in-phase with these stimuli. In this investigation we demonstrate that these same deep tectal neurons respond equally well to kinematograms as they do to traditional luminance contrast stimuli typically employed in visual experiments.Computer generated kinematograms, the motion domain equivalents of random dot stereograms, were used as stimuli in these experiments. These kinematograms, where a small centrally located set of random dots is moved coherently in one direction while the remaining dots are moved in a different direction, thus constitute a pure motion stimulus where the stimulus form is only visible in the dynamic pattern, but does not exist on any single frame. Both object configured and hole configured kinematograms were employed; the former appearing as regions of texture moving over, or in front of, the background texture, while the latter appear as windows through which a more distant textured surface is revealed.Extracellular recordings from isolated deep tectal cells showed that all units responded in a very similar manner whether the stimulus was an object configured kinematogram or the more traditional luminance contrast variety. This similarity included directional selectivity, the in-phase inhibition anti-phase facilitation effect, and sensitivity to opposed motion independent of direction. However, when the kinematograms were configured as holes none of the units tested responded to these stimuli. The significance of these observations for tectal functioning, image segmentation through motion and animal camouflage is discussed.     

蜻蜒运动检测神经元的光谱反应

蜻蜒腹神经束上存在着自运动检测神经元和目标运动检测神经元.我们采用了两种视觉刺激条件来测试自运动检测神经元的光谱反应.当采用控制强度和波长的闪光进行测试时、它们的光谱反应曲线与绿色光感受器的光谱灵敏度曲线极其相似,峰值位于500nm处.然而采用运动的条纹进行测试时,它们的峰值却位于560nm处.当用一种颜色的运动图案作为目标放置在另一种颜色背景的前方测试时,发现存在某个目标的照明强度值能使反应下降到自发放电的水平,这表明自运动检测器无法检测这二种颜色的差别,即它们是色盲的、它主要接受来自绿色光感受器的信号.目标运动检测神经元的光谱反应特性与自运动检测神经元的不同,目标运动检测神经元在以380nm至580nm的范围中有着平坦的光谱反应曲线,有时在紫外频段出现峰有(?)前景与背景颜色不同且固定背景光的颜色与强度而改变前景的光强时,神经元的反应不会下降到自发放电水平,当背景为绿色而目标为另一个颜色.特别是兰色时,神经元反应强烈,但当背景为兰色而目标为绿色时,它们的反应相对较弱.这些结果表明目标运动检测神经元是对颜色敏感的.     

Responses of medullary neurons to moving visual stimuli in the common toad

The concept of coded 'command releasing systems' proposes that visually specialized descending tectal (and pretectal) neurons converge on motor pattern generating medullary circuits and release--in goal-specific combination--specific action patterns. Extracellular recordings from medullary neurons of the medial reticular formation of the awake immobilized toad in response to moving visual stimuli revealed the following main results. (i) Properties of medullary neurons were distinguished by location, shape, and size of visual receptive fields (ranging from relatively small to wide), by trigger features of various moving configural stimulus objects (including prey- and predator-selective properties), by tactile sensitivity, and by firing pattern characteristics (sluggish, tonic, warming-up, and cyclic). (ii) Visual receptive fields of medullary neurons and their responses to moving configural objects suggest converging inputs of tectal (and pretectal) descending neurons. (iii) In contrast to tectal monocular 'small-field' neurons, the excitatory visual receptive fields of comparable medullary neurons were larger, ellipsoidally shaped, mostly oriented horizontally, and not topographically mapped in an obvious fashion. Furthermore, configural feature discrimination was sharper. (iv) The observation of multiple properties in most medullary neurons (partly showing combined visual and cutaneous sensitivities) suggests integration of various inputs by these cells, and this is in principle consistent with the concept of command releasing systems. (v) There is evidence for reciprocal tectal/medullary excitatory pathways suitable for premotor warming-up. (vi) Cyclic bursting of many neurons, spontaneously or as a post-stimulus sustaining event, points to a medullary premotor/motor property.