视觉刺激对猴初级视皮层神经元眼球位置效应的影响

用细胞外记录的方法,研究了视觉刺激对清醒猴初级视皮层神经元眼球位置效应的影响,当猴注视电视屏幕上２５个不同位置的小光点时,屏蔽上分别给予两种不同形式的视觉刺激：注视点周围的闪光圆环和感受野内的移动光条。这两种刺激都能增强初级视皮层神经元的眼球位置相关活动,并相应地使受眼球位置调制的神经元的比例明显增加。     

初级视皮层神经元非经典感受野研究的新进展

感觉皮层神经元的非经典感受野(简称"外周")对经典感受野(简称"中心")的调节作用广泛存在于哺乳动物中,被认为是感觉皮层神经元的基本特性.以初级视皮层神经元为例,刺激其外周能有效地调节刺激其中心引起的反应,这种作用主要是抑制性的.理解初级视皮层神经元的外周对中心的调节机制能够深入揭示哺乳动物的感觉皮层神经元信息处理的基本原则.本文综述了引起初级视皮层神经元非经典感受野对经典感受野调节作用的神经环路机制和计算模型研究的进展.     

猫纹状皮层神经元整合野的形状和范围

用正弦调制的移动光栅测量了１２０个猫纹状皮层神经元在长度和宽度方向上的空间整合特性。结果表明：（１）大多数细胞的传统感受野具有长宽相近的结构,然而它们的整合野多数是宽而短或者窄而长的长条形。（２）整合野大小为传统感受野的２—７倍,平均为３．７倍。简单细胞与复杂细胞整合野的大小没有显著差别。（３）随着感受野的视网膜偏心度的增加,整合野大小有逐渐增大的趋势。（４）感受野靠近视网膜垂直中线的细胞,其整合野可以跨越中线进入同侧视野;在两半视野中整合野的范围没有显著差异,但是同侧视野整合野的作用强度明显弱于对侧视野。以上结果提示,初级视皮层神经元能够对大范围内的图形特征进行整合,这种整合作用来自两侧视野。     

猫视皮层星形胶质细胞的老年性变化

电生理研究结果显示,在衰老过程中猫的视皮层神经元对视觉刺激的反应性出现显著的功能衰退,是否这种功能性衰退伴随胶质细胞活动的改变尚无直接的实验证据。以前期电生理实验猫为材料,用免疫形态学方法比较青年猫和老年猫初级视皮层内星形胶质细胞的活动状况。利用Nissl染色显示猫初级视皮层组织结构,用免疫组织化学方法（SABC法）显示GFAP免疫阳性（GFAP-IR）星形胶质细胞。光镜下观察、拍照,对GFAP-IR细胞计数并换算成密度,测量GFAP-IR直径取平均值。老年猫初级视皮层灰质各层及白质内的GFAP-IR细胞密度比青年猫的显著升高（p〈0.001）。与青年猫相比,老年猫视皮层灰质和白质中GFAP-IR细胞的平均直径均比青年猫的显著增大（p〈0.0001）,且老年猫视皮层内GFAP阳性免疫反应较青年猫的明显增强。老年猫初级视皮层神经元功能衰退伴随着星形胶质细胞活动的增强,胶质细胞活动增强有助于神经元之间的信息交流,因而可能对衰老过程中神经元的功能衰退起补偿作用。     

S100蛋白在猫初级视皮层中分布及其年龄相关性变化

比较青年猫和老年猫初级视皮层(primary visual cortex)各层神经元密度,及S100蛋白在初级视皮层各层中的表达与分布,探讨其表达与分布的年龄相关性变化及意义.Nissl法显示初级视皮层各层神经元,免疫组织化学方法(SABC法)示S100蛋白免疫阳性(S100-IR)细胞.光镜下观察、拍照,计数初级视皮层各层中神经元密度和S100-IR细胞密度.S100-IR细胞在初级视皮层中分布呈现区域性特点,白质较灰质密集.与青年猫相比,老年猫初级视皮层神经元密度有下降,老年猫初级视皮层各层S100-IR细胞密度均有不同程度的显著增加(尤其是Ⅱ、Ⅲ、Ⅳ层),胞体较大,阳性较强.动物衰老过程中,初级视皮层存在着明显的星形胶质细胞反应性增生,这种增生可能对灰质层中神经元的丢失有补偿作用,并对维持老年个体初级视皮层形态结构和延缓老年动物初级视皮层功能衰退具有积极意义.     

猴和猫初级视皮层细胞方向选择性及其功能组织的比较研究

虽然许多视皮层区内的方向选择性细胞以柱状方式排列组构, 但猴初级视皮层(V1)区方向选择性功能组构仍然不甚明了. 定量地比较研究了猴和猫初级视皮层方向选择性细胞的比例、选择性强度和功能组织, 结果表明, 猴的方向选择性细胞的比例比猫少, 选择性强度和方向功能组织的程度均显著地比猫弱, 提示这些种属差别可能源于其神经通路的不同.     

猫初级视皮层内Glu／GABA表达比率的衰老性变化

最近的一些研究结果显示,视皮层内抑制性递质系统作用减弱可能是导致老年性视觉功能衰退的重要因素。是否皮层内兴含性递质系统办伴随衰老而发生改变并影响皮层内神经兴奋与抑制的平衡尚不清楚。为此,利用Nissl染色和免疫组织化学染色方法以及Image—Pro Express图像分析软件对青、老年猫初级视皮层（17区）内各层神经元密度、兴奋性递质谷氦酸免疫反应阳性（Glu—immunoreactive,Glu—IR）神经元密度以及抑制性递质γ-氨基丁酸免疫反应阳性（v．aminobutyric acid-immunoreactive,GABA—IR）神绎元密度进行了统计分析。结果显示,青、老年猫初级视皮层各层神经元密度均没有明显的年龄性差异（P〉0．05）;与青年猫相比,老年猫初级视皮层Glu—IR、GABA．IR神经元密度均显著减少（P〈0．01）,而Glu—IR／GABA-IR神经元密度比率却显著增大（P〈0．01）。结果提示,老年猫初级视皮层内兴奋性递质系统作用相对增强,而抑制性递质系统的作用相对减弱,导致皮层内兴奋-抑制平衡关系失调,这可能是引起老年个体视觉功能衰退的重要原因之一。     

屈光不正对儿童视觉皮层神经元活动影响的功能磁共振研究

目的：利用血氧水平依赖性功能性磁共振成像（BOLD-fMRI）技术及非金属MRI专用眼镜,分析探索屈光不正对儿童大脑皮层视觉功能区神经元活动的影响。方法：以1．5T磁共振成像系统采集8例屈光不正眼儿童屈光矫正前后枕叶视皮层兴趣区BOLD—fMRI数据,及8例正常眼凸透镜离焦前后枕叶视皮层兴趣区BOLD—fMRI数据,进行对比分析,比较屈光不正眼及其矫正后、正常眼及其离焦后皮层视觉功能区神经元活动的不同,分析其改变特点及原因。结果：屈光不正眼儿童矫正屈光后皮层视觉功能区神经元活动范围明显增加（P〈0．05）;正常眼离焦后皮层视觉功能区神经元活动范围明显减小（P〈0．05）。结论：屈光不正会明显降低儿童皮层视觉功能区的神经元活动。屈光不正患儿应尽早配镜矫正,以免影响视觉皮层功能发育。     

猫纹状皮层神经元整合野的形态和范围

用正弦调制的移动光栅测量了１２０个猫纹状皮层神经元在长度和宽度方向上的空间整合特性。结果表明：（１）大多数细胞的传统感受野具有长宽相近的结构,然而它整合野多数是宽而短或者窄而长的长条形。（２）整合野大小为传统感受野的２－７倍,平均为３．７倍。简单细胞与复杂细胞整合野的大小没有显著差别。（３）随着感受野的视网膜偏心度的增加,整合野大小有逐渐增大的趋势。（４）感受野靠近视网膜垂直中线的细胞,其整合野可     

TrkB受体依赖的PV神经元调控小鼠视觉方位辨别能力的机制

神经营养因子-酪氨酸受体激酶B （tyrosine receptor kinase B,TrkB）信号通路在调控初级视皮层（primary visual cortex,V1）兴奋与抑制平衡上发挥着重要的作用,以往的研究揭示了其通过增加兴奋性传递效率来调控皮层兴奋性水平的机制,却并未阐明TrkB受体如何通过抑制系统来调控兴奋与抑制平衡,进而影响视觉皮层功能。为了探讨TrkB信号通路如何特异性地调控最主要的抑制性神经元——PV神经元进而对小鼠视觉皮层功能产生影响,本研究通过病毒特异性地降低V1区的PV神经元上TrkB受体的表达水平,并通过在体多通道电生理手段记录初级视皮层抑制性与兴奋性神经元功能变化,通过行为学实验测试小鼠的方位辨别能力改变。结果表明,初级视觉皮层中的PV抑制性神经元上的TrkB受体表达减少会显著增加兴奋性神经元的反应强度,减弱抑制性神经元与兴奋性神经元的方位辨别能力,增加二者的信噪比,但是小鼠个体水平的方位辨别能力出现下降。这些结果说明,TrkB信号通路并非单纯通过增加靶向PV神经元的兴奋性传递来调控PV神经元的功能,其对神经元信噪比的影响也并非由于抑制系统的增强所致。     

Parietal neurons encoding visual space in a head-frame of reference.

Neurons of the visual system are known to have receptive fields organized in retinotopic coordinates. We wanted to test whether visual neurons existed whose receptive fields were organized in spatial coordinates. Extracellular recordings from single cells were carried out in one area of the posterior parietal cortex (area V6) of a behaving macaque monkey. Among a great majority of retinotopically organized visual cells, neurons whose visual receptive field did not shift with gaze were also found. These cells responded to the visual stimulation of the same spatial position independently of the animal's direction of gaze, that is, their receptive field was anchored to an absolute spatial location. We suggest that these neurons directly encode visual space and are involved in programming visually-guided motor actions in space.     

Saccade reward signals in posterior cingulate cortex

Movement selection depends on the outcome of prior behavior. Posterior cingulate cortex (CGp) is strongly connected with both limbic and oculomotor circuitry, and CGp neurons respond following saccades, suggesting a role in signaling the motivational outcome of gaze shifts. To test this hypothesis, single CGp neurons were studied in monkeys while they shifted gaze to visual targets for liquid rewards that varied in size or were delivered probabilistically. CGp neurons responded following saccades as well as following reward delivery, and these responses were correlated with reward size. CGp neurons also responded following the omission of predicted rewards. The timing of CGp activation and its modulation by reward could provide signals useful for updating representations of expected saccade value.     

Somatosensory-motor neuronal activity in the superior colliculus of the primate

The superior colliculus (SC) in primates plays an important role in orienting gaze and arms toward novel stimuli. Here we ask whether neurons in the intermediate and deep layers of the SC are also involved in the interaction with objects. In two trained monkeys we found a large number of SC units that were specifically activated when the monkeys contacted and pushed a target that had been reached with either hand. These neurons, however, were silent when the monkeys simply looked at or reached for the target but did not touch it. The activity related to interacting with objects was spatially tuned and increased with push strength. Neurons in the SC with this type of activity may be involved in a somatosensory-motor feedback loop that monitors the force of the active muscles together with the spatial position of the limb required for proper interaction with an object.     

The role of the posterior parietal cortex in coordinate transformations for visual-motor integration

Lesion to the posterior parietal cortex in monkeys and humans produces spatial deficits in movement and perception. In recording experiments from area 7a, a cortical subdivision in the posterior parietal cortex in monkeys, we have found neurons whose responses are a function of both the retinal location of visual stimuli and the position of the eyes in the orbits. By combining these signals area 7 a neurons code the location of visual stimuli with respect to the head. However, these cells respond over only limited ranges of eye positions (eye-position-dependent coding). To code location in craniotopic space at all eye positions (eye-position-independent coding) an additional step in neural processing is required that uses information distributed across populations of area 7a neurons. We describe here a neural network model, based on back-propagation learning, that both demonstrates how spatial location could be derived from the population response of area 7a neurons and accurately accounts for the observed response properties of these neurons.     

Fix your eyes in the space you could reach: neurons in the macaque medial parietal cortex prefer gaze positions in peripersonal space

Interacting in the peripersonal space requires coordinated arm and eye movements to visual targets in depth. In primates, the medial posterior parietal cortex (PPC) represents a crucial node in the process of visual-to-motor signal transformations. The medial PPC area V6A is a key region engaged in the control of these processes because it jointly processes visual information, eye position and arm movement related signals. However, to date, there is no evidence in the medial PPC of spatial encoding in three dimensions. Here, using single neuron recordings in behaving macaques, we studied the neural signals related to binocular eye position in a task that required the monkeys to perform saccades and fixate targets at different locations in peripersonal and extrapersonal space. A significant proportion of neurons were modulated by both gaze direction and depth, i.e., by the location of the foveated target in 3D space. The population activity of these neurons displayed a strong preference for peripersonal space in a time interval around the saccade that preceded fixation and during fixation as well. This preference for targets within reaching distance during both target capturing and fixation suggests that binocular eye position signals are implemented functionally in V6A to support its role in reaching and grasping.     

Spatial Representations in Local Field Potential Activity of Primate Anterior Intraparietal Cortex (AIP)

The execution of reach-to-grasp movements in order to interact with our environment is an important subset of the human movement repertoire. To coordinate such goal-directed movements, information about the relative spatial position of target and effector (in this case the hand) has to be continuously integrated and processed. Recently, we reported the existence of spatial representations in spiking-activity of the cortical fronto-parietal grasp network (Lehmann & Scherberger 2013), and in particular in the anterior intraparietal cortex (AIP). To further investigate the nature of these spatial representations, we explored in two rhesus monkeys (Macaca mulatta) how different frequency bands of the local field potential (LFP) in AIP are modulated by grip type, target position, and gaze position, during the planning and execution of reach-to-grasp movements. We systematically varied grasp type, spatial target, and gaze position and found that both spatial and grasp information were encoded in a variety of frequency bands (1–13Hz, 13–30Hz, 30–60Hz, and 60–100Hz, respectively). Whereas the representation of grasp type strongly increased towards and during movement execution, spatial information was represented throughout the task. Both spatial and grasp type representations could be readily decoded from all frequency bands. The fact that grasp type and spatial (reach) information was found not only in spiking activity, but also in various LFP frequency bands of AIP, might significantly contribute to the development of LFP-based neural interfaces for the control of upper limb prostheses.     

Where the eye looks, the hand follows; limb-dependent magnetic misreaching in optic ataxia

The posterior parietal cortex (PPC) is thought to play an important role in the sensorimotor transformations associated with reaching movements. In humans, damage to the PPC, particularly bilateral lesions, leads to impairments of visually guided reaching movements (optic ataxia). Recent accounts of optic ataxia based upon electrophysiological recordings in monkeys have proposed that this disorder arises because of a breakdown in the tuning fields of parietal neurons responsible for integrating spatially congruent retinal, eye, and hand position signals to produce coordinated eye and hand movements . We present neurological evidence that forces a reconceptualization of this view. We report a detailed case study of a patient with a limb-dependent form of optic ataxia who can accurately reach with either hand to objects that he can foveate (thereby demonstrating coordinated eye-hand movements) but who cannot effectively decouple reach direction from gaze direction for movements executed using his right arm. The demonstration that our patient's misreaching is confined to movements executed using his right limb, and only for movements that are directed to nonfoveal targets, rules out explanations based upon simple perceptual or motor deficits but indicates an impairment in the ability to dissociate the eye and limb visuomotor systems when appropriate.     

Dorsal premotor neurons encode the relative position of the hand, eye, and goal during reach planning

When reaching to grasp an object, we often move our arm and orient our gaze together. How are these movements coordinated? To investigate this question, we studied neuronal activity in the dorsal premotor area (PMd) and the medial intraparietal area (area MIP) of two monkeys while systematically varying the starting position of the hand and eye during reaching. PMd neurons encoded the relative position of the target, hand, and eye. MIP neurons encoded target location with respect to the eye only. These results indicate that whereas MIP encodes target locations in an eye-centered reference frame, PMd uses a relative position code that specifies the differences in locations between all three variables. Such a relative position code may play an important role in coordinating hand and eye movements by computing their relative position.