金黄仓鼠视觉中枢的甘氨酸免疫阳性神经元

用免疫细胞化学方法研究了甘氨酸在金黄仓鼠视觉中枢的分布特征, 并应用统计学方法进行了定量分析.结果表明：在视皮层中, 除了Ⅰ层以外, 甘氨酸免疫阳性神经元分布在其他各层内, 其平均密度为1 046/mm²,占视皮层细胞总数的23.9％.上丘浅灰层及视觉层甘氨酸免疫阳性神经元平均密度为750/mm²,占该层细胞总数的19.5％.外膝体中甘氨酸免疫阳性神经元密度较低.甘氨酸免疫阳性神经元包括不同类型的细胞.     

单眼剥夺对金黄地鼠视觉中枢GABA神经元分布的影响

用免疫细胞化学技术观察了单眼剥夺后金黄地鼠视觉中枢GABA神经元分布的变化。结果表明:单眼剥夺后,金黄地鼠视皮层和上丘的GABA阳性神经元暂时性增多,但剥夺后六个月,其数目显著减少。在单眼剥夺前和剥夺后侧膝体中GABA阳性神经元数目没有明显差异。剥夺眼对侧视皮层GABA阳性神经元数比剥夺眼同侧视皮层GABA神经元数目少。单眼剥夺后视觉中枢GABA神经元类型及形态与剥夺前没有差别。晚期单眼剥夺也能引起视觉中枢GABA神经元数量和分布的变化。以上结果表明,单眼剥夺后视觉中枢抑制神经元的结构发生了变化。     

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.     

金黄地鼠视觉中枢发育过程中P物质神经元数量及分布的变化

本实验用免疫细胞化学技术观察了不同年龄金黄地鼠视皮层和上丘中P物质(SP)阳性神经元数量和分布的变化,同时观察了不同年龄金黄地鼠视皮层SP阳性神经元的形态和类型。结果表明,出生后10天小鼠视皮层SP阳性神经元为36％,Ⅱ—Ⅳ层密度最大,约占40％。上丘中SP阳性神经元约为37％。出生后20天,视皮层及上丘中SP阳性神经元分别减少到23％和16％。视皮层Ⅱ—Ⅳ层减少最明显,Ⅴ层和Ⅵ层变化不大。成年鼠视皮层及上丘中偶见SP神经元,但出现一些SP阳性纤维。出生10天及20天鼠视皮层中SP阳性神经元的形态及类型没有差别。     

金黄地鼠视皮层中乙酰胆碱(Ach)阳性神经元及纤维

本文通过色疫组织化学方法-PAP法,使用乙酰胆碱(Ach)抗体对金黄地鼠视皮层中的Ach进行定位Ach阳性神经元分布于视皮层的第Ⅱ—Ⅵ层,主要集中在Ⅱ、Ⅲ层.其细胞形态除大部分为非锥体神经元外,还发现有极少数锥体型神经元.这些神经元的数量和树突形态在视皮层17区和18区存在某些区域性差异.17区细胞比较密集,18区比较稀疏.17区第IA层细胞排列整齐,顶树突特别粗大,18区这种现象不太明显.皮层白质中也有少量的Ach阳性神经元.视皮层Ach阳性神经元的相对含量约为10%.视皮层中遍布外源性和内源性Ach阳性神经纤维,它们主要分布在第Ⅳ层.在视皮层微血管周围有大量Ach阳性神经元,说明对血管有舒张作用的Ach可能来源于血管内壁.     

猫上丘浅层GABA能神经元的年龄相关性变化

目的比较青年猫和老年猫上丘浅层（superricial Superior Colliculus,sSC）GABA能神经元及其表达的年龄相关性变化,探讨老年个体视觉功能衰退的相关神经机理。方法Nissl染色显示上丘浅层结构及神经元、免疫组织化学ABC法标记GABA免疫阳性神经元。光镜下观察,采集图像,并利用图像分析软件对带状层、浅灰质层和视层神经元及GABA免疫阳性神经元及其灰度值进行分析统计。结果GABA免疫阳性神经元、阳性纤维及其终末在青年猫及老年猫上丘浅层均有分布。与青年猫相比,老年猫上丘浅灰质层、视层神经元和GABA免疫阳性神经元密度及其GABA免疫阳性反应强度均显著下降（P〈0．01）（免疫反应强度与平均灰度值成反比）;带状层神经元密度也显著下降（P〈0．01）,但其GABA免疫阳性神经元密度无显著变化（P〉0．05）。结论衰老过程中猫上丘浅层GABA能神经元的丢失和GABA表达的下降,可能是在上丘水平上导致老年个体视觉功能衰退的重要因素之一。     

猫初级视皮层内GIu/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.是否皮层内兴奋性递质系统亦伴随衰老而发牛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、兴奋性递质谷氨酸免疫反应阳性(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(γ-aminobutyric acid.immunoreactive,GABA-IR)神经元密度进行了统汁分析.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神经元密度比率去却显著增大(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.     

金黄仓鼠视皮层、上丘和外侧膝状体中的血管活性肠肽(VIP)神经元及其纤维

用程序稍有不同的两种ＰＡＰ法对视觉通路中的三个重要区域视皮层、上６和外侧膝状体中的 血管活性肠肽（ＶＩＰ）进行了定位,．视皮层Ⅱ至Ⅵ层都有ＶＩＰ阳性神经元分布,内域性的阳性神经 纤维遍布整个视皮层。上丘中的ＶＩＰ阳性神经无数量较少,主要分布于上丘的咀部表层,视皮层和 上丘中的ＶＩＰ神经元均为非锥体型的多极和双极神经元。外侧膝状体中未发现有ＶＩＰ阳性神经元 胞体．只有弥散的阳性神经纤维。     

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。     

金黄地鼠视皮层17、18区乙酰胆碱阳性神经元

利用乙酰胆碱( acetylcholine,Ach)自身抗体对金黄地鼠视皮层17、18区乙酰胆碱阳性神经元及其分布进行免疫学显示并进行量化分析.实验发现,Ach阳性细胞大部分为非锥体神经元,也有少量锥体神经元.Ach阳性神经元在视皮层的Ⅱ～Ⅵ层,主要分布在Ⅱ～Ⅳ层.在不同层次中其阳性神经元类型存在某些差异,Ⅱ～Ⅳ中双极细胞居多,其他层次中多极细胞占优势.17区的这类神经元数量较多且集中成垂直于皮层表面的细胞带,18区的神经元数量相对较少且多呈分散状态.     

猫小脑皮质GABA能神经元年龄相关性变化

为探讨青年猫和老年猫小脑皮质GABA能神经元及其表达的年龄相关性变化,利用Nissl染色显示小脑皮质结构及神经元,免疫组织化学ABC法标记GABA免疫阳性神经元。光镜下观察,采集图像,并利用图像分析软件对分子层、蒲肯野细胞层和颗粒层神经元及GABA免疫阳性神经元及其灰度值进行分析统计。结果显示,GABA免疫阳性神经元、阳性纤维及终末在青年猫和老年猫小脑皮质各层均有分布。与青年猫相比,老年猫分子层、蒲肯野细胞层神经元和GABA免疫阳性神经元密度及其GABA免疫阳性反应强度均显著下降(P<0.01),颗粒层神经元密度和GABA免疫阳性强度也显著下降(P<0.01),但其GABA免疫阳性神经元密度无显著变化(P>0.05);蒲肯野细胞的胞体萎缩,阳性树突分枝减少。因此认为,衰老过程中猫小脑皮质GABA能神经元的丢失和GABA表达的下降,可能是老年个体运动协调、精确调速和运动学习等能力下降的重要原因之一。     

Antisera to gamma-aminobutyric acid. II. Immunocytochemical application to the central nervous system

An antiserum to gamma-aminobutyric acid (GABA) was tested for the localization of GABAergic neurons in the central nervous system using the unlabeled antibody enzyme method under pre- and postembedding conditions. GABA immunostaining was compared with glutamate decarboxylase (GAD) immunoreactivity in the cerebellar cortex and in normal and colchicine-injected neocortex and hippocampus of cat. The types, distribution, and proportion of neurons and nerve terminals stained with either sera showed good agreement in all areas. Colchicine treatment had little effect on the density of GABA-immunoreactive cells but increased the number of GAD-positive cells to the level of GABA-positive neurons in normal tissue. GABA immunoreactivity was abolished by solid phase adsorption to GABA and it was attenuated by adsorption to beta-alanine or gamma-amino-beta-hydroxybutyric acid, but without selective loss of immunostaining. Reactivity was not affected by adsorption to glutamate, aspartate, taurine, glycine, cholecystokinin, or bovine serum albumin. The concentration (0.05-2.5%) of glutaraldehyde in the fixative was not critical. The antiserum allows the demonstration of immunoreactive GABA in neurons containing other neuroactive substances; cholecystokinin and GABA immunoreactivities have been shown in the same neurons of the hippocampus. In conclusion, antisera to GABA are good markers for the localization of GABAergic neuronal circuits.     

Distribution and anatomy of GABA-like immunoreactive neurons in the central and peripheral nervous system of the snail Helix pomatia

Gamma-aminobutyric acid (GABA)-like immunoreactive neurons were studied in the central and peripheral nervous system of Helix pomatia by applying immunocytochemistry on whole-mount preparations and serial paraffin sections. GABA-immunoreactive cell bodies were found in the buccal, cerebral and pedal ganglia, but only GABA-immunoreactive fibers were found in the viscero-parietal-pleural ganglion complex. The majority of GABA-immunoreactive cell bodies were located in the pedal ganglia but a few could be found in the buccal ganglia. Varicose GABA-ir fibers could be seen in the neuropil areas and in distinct areas of the cell body layer of the ganglia. The majority of GABA-ir axonal processes run into the connectives and commissures of the ganglia, indicating an important central integrative role of GABA-immunoreactive neurons. GABA may also have a peripheral role, since GABA-immunoreactive fibers could be demonstrated in peripheral nerves and the lips. Glutamate injection did not change the number or distribution of GABA-immunoreactive neurons, but induced GABA immunoreactivity in elements of the connective tissue ensheathing the muscle cells and fibers of the buccal musculature. This shows that GABA may be present in different non-neural tissues as a product of general metabolic pathways.     

Intrinsic processing in the mammalian superior colliculus

The mammalian superior colliculus receives visual inputs from the retina and primary visual cortex in its superficial layers and sends descending motor commands from its deeper layers. It is now becoming clear that a connection exists between these layers, but the signal transmission through it is not robust. The induction of burst discharges in the deeper layer neurons by direct visual inputs from the superficial layers may lead to 'express' saccadic eye movements with extremely short reaction times in behaving animals.     

Orientational and directional selectivities of visual neurons in the superior colliculus of the cat

Based on quantitative analyses of the response characteristics of visual neurons in the superior colliculus to moving optical bar stimuli, it is demonstrated for the first time that the visual neurons in superior colliculus of the cat have, to some extent, orientational selectivity. The significance of this selectivity is discussed in reference to its morphological substrate and physiological functions. In addition, both the directional and orientational selectivities in the superior colliculus are relatively weak when compared with those in the primary visual cortex, and the majority of the neurons prefer upward or downward motion in the visual field.     

大鼠上丘到外膝体P－物质投射的机能

已知大鼠外膝体内有中脑上丘来的含Ｐ－物质的神经末梢,其机能不明。在离休的大鼠外膝体脑片上用单电极电压箝位的方法研究了Ｐ－物质对外膝体神经元电压依赖性离子通道的作用。结果表明,Ｐ－物质可以使静息膜去极化,并降低膜电导。这提示Ｐ－物质抑制了线性钾漏电流。此外,Ｐ－物质还抑制去极化激活的慢失活的钾电流、低阈值钙电流和超极化激活的内向整流（Ｈ或Ｑ）电流。Ｐ－物质还可能抑制早钾（Ａ）电流。因此,Ｐ－物质在外膝体视觉信号传递中的作用是使外膝体神经元从爆发反应方式或振荡状态转化为中继反应方式,易化突触传递,使视网膜的视觉信号忠实地传递到大脑皮层。     

大鼠脑内代谢型谷氨酸受体5亚型(mGluR5)定位分布的免疫细胞化学研究

本研究用免疫细胞化学技术观察了大鼠脑内参与兴奋性突触传递的代谢型谷氨酸受体5亚型(mGluR5)的精确定位分布.mGluR5阳性浓染的神经元胞体和纤维密集地分布于大脑皮质浅层、嗅球、伏核、尾壳核、前脑基底部、隔区、苍白球、腹侧苍白球、海马CA1和CA2区、下丘中央核、被盖背侧核和三叉神经脊束核尾侧亚核浅层;淡染而稀疏的mGluR5阳性神经元胞体和纤维见于屏状核、终纹床核、杏仁中央核、丘脑部分核团、上丘浅灰质层、外侧丘系背侧核和延髓中央灰质.     

Cellular dispersion patterns and phenotypes in the developing mouse superior colliculus.

The mammalian superior colliculus is structurally and functionally divided into two entities: superficial visual and deep multimodal motor. To discover the role, if any, of developmental processes in establishing separate tectal compartments, we have used highly unbalanced mouse chimaeras to mark cell dispersion pathways and trace cell lineages. Two forms of cell dispersion were detected: radial and tangential. Neither radial nor tangential forms of cell dispersion were found to exist on their own in any group of labeled cells. Radial cell dispersion was the predominant form of cell movement from the germinal zones and primarily associated with the differentiation of glutamatergic neurons. In contrast, tangential cell dispersion involved a minority of tectal cells, concentrated chiefly in the superficial layers and often associated with the upper aspects of radial columns. More scattered cells expressed gamma-aminobutyric acid (GABA) compared to columnar cells. Taken together, these results indicate separate developmental constraints for the development of glutamatergic and GABAergic neurons in the superior colliculus.