A Combined Bodian-Nissl Stain for Improved Network Analysis in Neuronal Cell Culture

Bodian and Nissl procedures were combined to stain dissociated mouse spinal cord cells cultured on coverslips. The Bodian technique stains fine neuronal processes in great detail as well as an intracellular fibrillar network concentrated around the nucleus and in proximal neurites. The Nissl stain clearly delimits neuronal cytoplasm in somata and in large dendrites. A combination of these techniques allows the simultaneous depiction of neuronal perikarya and all afferent and efferent processes. Costaining with little background staining by either procedure suggests high specificity for neurons. This procedure could be exploited for routine network analysis of cultured neurons.     

GDAF对原代培养脊髓神经元的影响

The effect of GDNF on long-term cultured spinal cord neurons was studied. GDNF could promote spinal cord neurons survival after 7 d or 14 d culture by MTT assay. The effect of GDNF on growth cones, neuron soma magnitude, neurite length and spines formulation of spinal cord neurons in cell culture was observed by phase microscopy, Nissl stain and NSE immunocytochemistry stain. The results indicated that GDNF had significant trophic effects on long-term cultured spinal cord neurons.     

GDNF对原代培养脊髓神经元的影响

本文研究了GDNF对体外培养各个时期的脊髓神经元的作用。通过MTT法检测GDNF对脊髓神经元存活率的影响,发现GDNF能促进培养7天及14天的神经元存活。 通过活体观察、尼氏染色、NSE免疫细胞化学染色观察GDNF对脊髓神经元生长锥数目、胞体大小、突起长度及分枝、侧棘形成的影响,发现GDNF对体外培养1—3周的脊髓神经元有明显的营养作用。     

A Combination Staining Method for Fibers and Cell Bodies of the Urodele Central Nervous System

A simple method for staining nerve cells and fibers of the salamander central nervous system is described. The procedure employs Carnoy's fixation followed by Protargol impregnation and Nissl staining. This technique permits the simultaneous observation of intracellular neurofibrils, neuronal processes and basophilic components of the neuron. In addition, it eliminates the need to stain alternate sections with separate procedures to view the various components of the urodele central nervous system.     

A combination staining method for fibers and cell bodies of the urodele central nervous system

A simple method for staining nerve cells and fibers of the salamander central nervous system is described. The procedure employs Carnoy's fixation followed by Protargol inpregnation and Nissl staining. This technique permits the simultaneous observation of intracellular neurofibrils, neuronal processes and basophilic components of the neuron. In addition, it eliminates the need to stain alternate sections with separate procedures to view the various components of the urodele central nervous system.     

L-NAME对大鼠急性脊髓损伤的影响

实验采用雌性Wistar大鼠15只,分为正常对照组、生理盐水对照组L－NAME治疗组,后两组制成急性脊髓损伤模型,于术后每天一次腹腔注射L－NAME（20kg/kg）或等量生理盐水,连续七天,然后处死动物,行脊髓NOS和Nissl染色。结果显示,L－NAME治疗组脊髓NOS阳性神经元染色较生理盐水对照组浅,组间光密度比较P＜0.05。此外,生理盐水对照组脊髓神经元还出现尼氏体位、减少,甚至消失等现象;这些改变在L－NAME治疗组较轻,因此我们认为,大鼠急性脊髓损伤可诱导神经元NOS表达,L－NAME可对其损伤修复起促进作用。     

Understanding the physiology of glutamate receptors by use of a protocol for neuronal staining

Teaching students about the physiology of neurotransmitter receptors usually requires practical lessons with the use of sophisticated equipment and complex analysis of data. Here, we report our experience in teaching medical students with a simple, practical protocol that transforms the physiology of glutamate receptors into neuronal staining, observable under bright-field microscopy. Essentially, the students were challenged to selectively stain a subpopulation of cultured neurons expressing Ca(2+)-permeable alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA) receptors (a subgroup of ionotropic glutamate receptors). Neurons expressing this type of receptors were loaded with Co(2+) (in substitution for Ca(2+)) after nondesensitizing activation of AMPA receptors. After precipitation, the Co(2+) was revealed after treatment with silver. At the end of the procedure, the neurons expressing Ca(2+)-permeable AMPA receptors were visually identified under bright-field microscopy. The procedure allowed the visualization of the complete dendritic network of the stained neurons and allowed the students to learn very efficiently about the physiology of glutamate receptors.     

THE FINE STRUCTURE OF THE LATERAL VESTIBULAR NUCLEUS IN THE RAT : I. Neurons and Neuroglial Cells

The lateral vestibular nucleus consists of multipolar isodendritic neurons of various sizes The distal segments of some dendrites display broad expansions packed with slender mitochondria and glycogen particles. These distinctive formations are interpreted as being growing tips of dendrites, and the suggestion is advanced that they are manifestations of architectonic plasticity in the mature central nervous system. Unlike large neurons elsewhere, the giant cells (Deiters) contain small Nissl bodies interconnected in a dense mesh-work. The Nissl substance is characterized by randomly arranged cisterns of the endoplasmic reticulum and by a high proportion of free ribosomes. Whether attached or free, ribosomes usually cluster in groups of four to six, and larger polysomal arrays are rare. Free ribosomal clusters also occur in the axon hillock and the initial segment. The neuronal perikarya contain distinctive inclusions consisting of a ball of neurofilaments enveloped by a complex honeycombed membrane. The failure of these fibrillary inclusions to stain with silver suggests that the putative argyrophilia of neurofilaments may reside in an inconstant matrix surrounding them. Giant cells of Deiters are in intimate contact with two kinds of cellular elements—astroglial processes and synaptic terminals. Oligodendroglial cells are only rarely satellites of giant cells; in contrast, they are frequently satellites of small and medium-sized cells.     

Trypan blue in vivo stains nigral dopaminergic neurons killed by 6-hydroxydopamine

Dopaminergic neurons in the substantia nigra killed by 6-hydroxydopamine were stained in vivo by intracerebral injections of trypan blue. Such staining appeared specific for dead neurons, although a proportion of these retained the ability to stain with Nissl dyes for at least 2 days. Neurons retained trypan blue in vivo for periods of up to 9 days. Trypan blue staining of some neurons outside the substantia nigra demonstrated the use of this dye in determining the degree of non-specific toxicity of 6-hydroxydopamine. Twenty-four hours after infusion of trypan blue almost no background staining was present and individually stained neurons were clearly visible. Thus the use of trypan blue may have a general application as a sensitive method for estimating discrete areas of toxin-induced neuronal death, and for estimating the degree of specificity of a toxin.     

Discriminative Staining Methods for the Nervous System: Luxol Fast Blue-Periodic Acid-Schiff- Hematoxylin Triple Stain and Subsidiary Staining Methods

This paper describes a new series of staining methods which can discrimina-tively demonstrate every structure of the nervous system, including axons and capillaries, in animal and human materials. Methods described in this paper consist of one primary stain, luxol fast blue-periodic acid Schiff-hematoxylin (LPH) and six different subsidiary staining methods. The LPH triple stain can precisely differentiate the following structures: neurons (Nissl bodies, cytoplasm, nuclear membrane and nucleolus), various kinds of nuclei (glia, ependyma, endothelium, leucocyte, connective tissue, etc.), myelin sheaths, neuronal processes (axons and dendrites), reacted glial cell bodies (protoplasmic astrocytes, foamy cells, etc), blood vessels (arteries, veins and capillaries), meninges, intervening connective tissue, erythrocytes, lipofuscin granules, amyloid bodies, and others. Subsidiary staining methods are also described briefly. Applications are discussed in the context of staining technology and neuromorphological research.     

Discriminative staining methods for the nervous system: luxol fast blue--periodic acid-Schiff--hematoxylin triple stain and subsidiary staining methods

This paper describes a new series of staining methods which can discriminatively demonstrate every structure of the nervous system, including axons and capillaries, in animal and human materials. Methods described in this paper consist of one primary stain, luxol fast blue-periodic acid Schiff-hematoxylin (LPH) and six different subsidiary staining methods. The LPH triple stain can precisely differentiate the following structures: neurons (Nissl bodies, cytoplasm, nuclear membrane and nucleolus), various kinds of nuclei (glia, ependyma, endothelium, leucocyte, connective tissue, etc.), myelin sheaths, neuronal processes (axons and dendrites), reacted glial cell bodies (protoplasmic astrocytes, foamy cells, etc.), blood vessels (arteries, veins and capillaries), meninges, intervening connective tissue, erythrocytes, lipofuscin granules, amyloid bodies, and others. Subsidiary staining methods are also described briefly. Applications are discussed in the context of staining technology and neuromorphological research.     

Intensifier for Bodian staining of tissue sections and cell cultures

Intensification of the standard Bodian silver stain with a poststaining photographic enhancer produces high resolution of fine cell processes such as axonal growth cones. This technique can be used on tissue sections and is especially useful for visualizing individual cells fixed in tissue cultures.     

Intensifier for Bodian Staining of Tissue Sections and Cell Cultures

Intensification of the standard Bodian silver stain with a poststaining photographic enhancer produces high resolution of fine cell processes such as axonal growth cones. This technique can be used on tissue sections and is especially useful for visualizing individual cells fixed in tissue cultures.     

Cytochemical studies demonstrating the effect of monosodium glutamate on RNA concentration in neurons in mice

The effect of monosodium glutamate (MSG) on the concentration of ribonucleic acid (RNA) in the neurons of mice was studied, using the specific cytochemical stain, azure B bromide. The RNA-rich sites such as the nucleolus and the Nissl substances of large neurons showed a marked decrease in the concentration of RNA in the MSG-treated as compared to the control animals. Since RNA is believed to be the principal macromolecule involved in the learning and behavioral processes, previous reports have attributed learning and behavioral dysfunctions in MSG-treated animals to a significant decrease of the RNA concentration in these animals.     

The superior olivary complex in C57BL/6 mice.

The cellular and cytoarchitectural features of the lateral superior olive, the medial superior olive, the superior paraolivary nucleus and the medial, lateral and ventral nuclei of the trapezoid body are described in C57BL/6 mice using Nissl, Bodian and Golgi techniques. Principal, spindle and marginal cells are present in a well-defined lateral superior olive. The dendrites of these cells run primarily within rostrocaudal sheets as in the cat. The principal cells of the medial nucleus of the trapezoid body are similar to the principal cells in the cat. Large multipolar cells characterize the lateral nucleus of the trapezoid body and bipolar cells with a medial-lateral orientation are found in the medial superior olive. The largest neurons are found in the superior paraolivary nucleus and the lateral superior olive, and the medial and ventral nuclei of the trapezoid body. While brain weight and neuronal packing density change with development, the characteristic location of cell groups and the shape and Nissl-staining pattern of neurons in the youngest brains examined were essentially unchanged in the adult mice, although dendritic maturation had occurred. The homologies of the C57BL/6 superior olivary complex nuclei with the same areas described in other mouse strains, rat and cat are discussed. This study expands our understanding of the organization of the superior olivary complex in an inbred strain of Mus musculus and relates it to other species. The data about changes occurring during postnatal maturation may aid in the interpretation of behavioral and physiological studies of neonatal plasticity of the auditory system.     

新生SD大鼠皮质神经元的体外培养和鉴定

目的：建立高纯度的新生SD大鼠皮质神经元原代培养方法。方法：取24h内的新生SD大鼠皮质,用木瓜酶和DNaseⅠ共同消化,5％胎牛血清终止消化,吹打分离组织获得单细胞悬液,进行细胞计数,用无血清DMEM／F12种植培养,4h后换成用无血清Neurobasal配制的维持培养液继续培养,尼氏小体染色和免疫荧光法鉴定神经元的纯度。结果：培养第10d,神经元胞体饱满,结构清晰完整,光晕明显,折光性强,可见粗长的树突和轴突,相邻细胞形成紧密网状联系,神经元纯度达到96％以上。结论：经改良和优化,无须添加阿糖胞苷抑制胶质细胞的生长即能够获得生长状态良好、高纯度的神经元。     

Primary neuronal cultures from the brains of late stage Drosophila pupae

In this video, we demonstrate the preparation of primary neuronal cultures from the brains of late stage Drosophila pupae. The procedure begins with the removal of brains from animals at 70-78 hrs after puparium formation. The isolated brains are shown after brief incubation in papain followed by several washes in serum-free growth medium. The process of mechanical dissociation of each brain in a 5 ul drop of media on a coverslip is illustrated. The axons and dendrites of the post-mitotic neurons are sheered off near the soma during dissociation but the neurons begin to regenerate processes within a few hours of plating. Images show live cultures at 2 days. Neurons continue to elaborate processes during the first week in culture. Specific neuronal populations can be identified in culture using GAL4 lines to drive tissue specific expression of fluorescent markers such as GFP or RFP. Whole cell recordings have demonstrated the cultured neurons form functional, spontaneously active cholinergic and GABAergic synapses. A short video segment illustrates calcium dynamics in the cultured neurons using Fura-2 as a calcium indicator dye to monitor spontaneous calcium transients and nicotine evoked calcium responses in a dish of cultured neurons. These pupal brain cultures are a useful model system in which genetic and pharmacological tools can be used to identify intrinsic and extrinsic factors that influence formation and function of central synapses.     

Development of an artificial neuronal network with post-mitotic rat fetal hippocampal cells by polyethylenimine

The selection of appropriate surface materials that promote cellular adhesion and growth is an important consideration when designing a simplified neuronal network in vitro. In the past, extracellular matrix proteins such as laminin (LN) or positively charged substances such as poly-l-lysine (PLL) have been used. In this study, we examined the ability of another positively charged polymer, polyethyleneimine (PEI), to promote neuronal adhesion, growth and the formation of a functional neuronal network in vitro. PEI, PLL and LN were used to produce grid-shape patterns on glass coverslips by micro-contact printing. Post-mitotic neurons from the rat fetal hippocampus were cultured on the different polymers and the viability and morphology of these neurons under serum-free culture conditions were observed using fluorescent microscopy and atomic force microscopy (AFM). We show that neurons cultured on the PEI- and PLL-coated surfaces adhered to and extended neurites along the grid-shape patterns, whereas neurons cultured on the LN-coated coverslips clustered into clumps of cells. In addition, we found that the neurons on the PEI and PLL-coated grids survived for more than 2 weeks in serum-free conditions, whereas most neurons cultured on the LN-coated grids died after 1 week. Using AFM, we observed some neurosynapse-like structures near the neuronal soma on PEI-coated coverslips. These findings indicate that PEI is a suitable surface for establishing a functional neuronal network in vitro.     

Some fluorescent counterstains for neuroanatomical studies

Methods for counterstaining neural tissue that contains fluorescent markers have been developed. Acridine orange is useful for localizing cells that are retrogradely labelled with the fluorescent tracers true blue, bisbenzimide, and nuclear yellow because at low concentrations it yields a green Nissl stain when excited with blue, but not with ultraviolet, light; since the tracers fluoresce only when exposed to ultraviolet light, they are not masked by the counterstain. In addition, counterstaining at pH 2 increases bisbenzimide fluorescence considerably. Ethidium bromide is useful for immunohistochemistry (IHC) because it yields a bright red Nissl counterstain when excited by green light, and is only faintly visible when the fluorescein marker is excited with blue light, or when ultraviolet excitation is used. Ethidium bromide is therefore a good counterstain for fluorescent retrograde tracer and for combined IHC-retrograde tracer studies as well. Certain dyes are also useful for studies of the normal morphology of neural tissue. For example, bisbenzimide and nuclear yellow at low concentrations produce a brilliant Nissl stain at pH 2, and stain only nuclei at pH 7.2. The latter procedure may be particularly useful for cell counts. Finally, neutral red, astrazone red, and safranin-O differentially stain cells amd myelinated fibers, producing fluorescence analogs of the Klüver-Barrera stain.     

A rapid method combining Golgi and Nissl staining to study neuronal morphology and cytoarchitecture.

The Golgi silver impregnation technique gives detailed information on neuronal morphology of the few neurons it labels, whereas the majority remain unstained. In contrast, the Nissl staining technique allows for consistent labeling of the whole neuronal population but gives very limited information on neuronal morphology. Most studies characterizing neuronal cell types in the context of their distribution within the tissue slice tend to use the Golgi silver impregnation technique for neuronal morphology followed by deimpregnation as a prerequisite for showing that neuron's histological location by subsequent Nissl staining. Here, we describe a rapid method combining Golgi silver impregnation with cresyl violet staining that provides a useful and simple approach to combining cellular morphology with cytoarchitecture without the need for deimpregnating the tissue. Our method allowed us to identify neurons of the facial nucleus and the supratrigeminal nucleus, as well as assessing cellular distribution within layers of the dorsal cochlear nucleus. With this method, we also have been able to directly compare morphological characteristics of neuronal somata at the dorsal cochlear nucleus when labeled with cresyl violet with those obtained with the Golgi method, and we found that cresyl violet-labeled cell bodies appear smaller at high cellular densities. Our observation suggests that cresyl violet staining is inadequate to quantify differences in soma sizes.