A New Method for Demonstrating Argyrophil Cells of the Pancreas and Intestines

A new method for demonstrating argyrophil cells of the pancreas and intestinal tract using a combined silver and reducing solution in sections of formaldehyde fixed tissue is described. Impregnating sections in a 60 C water bath, the procedure takes about 25 min. A microwave version that takes about 5 min is also given. Results are similar to those obtained with the Grimelius method for argyrophil cells.     

Effect of Temperature on Argyrophil Impregnation: Development of A High Temperature Rapid Argyrophil Procedure

Out studies on the effects of temperature on the demonstration of neurosecretory granules using argyrophil stains indicate an inverse relationship between the time needed for staining and temperature of the silver and reducing solutions. Careful monitoring of the temperature of silver solutions during the Grimelius procedure and its modifications show long incubation times serve in large part only to bring the solutions to reaction temperature. Tissue sections added when this temperature has been reached will stain with the same intensity as sections impregnated for the entire incubation period. We have modified the argyrophil procedure so that double-impregnation with solutions preheated to 60-70 C and development in Bodian's reducer prepared with preheated water rapidly demonstrates secretory granules. Our method does not require a microwave oven and much shorter incubation periods are required than with usual procedures. It is not necessary to incubate sections in hot solutions for extended periods of time, which can lead to detachment of sections, nonspecific staining and decomposition of the silver solution. Rinsing after impregnation and before development greatly increases contrast of argyrophil cells by reducing background staining. Our procedure results in more reliable staining of argyrophil and argentaffin cells and takes only ten minutes.     

Effect of temperature on argyrophil impregnation: development of a high temperature rapid argyrophil procedure

Our studies on the effects of temperature on the demonstration of neurosecretory granules using argyrophil stains indicate an inverse relationship between the time needed for staining and temperature of the silver and reducing solutions. Careful monitoring of the temperature of silver solutions during the Grimelius procedure and its modifications show long incubation times serve in large part only to bring the solutions to reaction temperature. Tissue sections added when this temperature has been reached will stain with the same intensity as sections impregnated for the entire incubation period. We have modified the argyrophil procedure so that double-impregnation with solutions preheated to 60-70 C and development in Bodian's reducer prepared with preheated water rapidly demonstrates secretory granules. Our method does not require a microwave oven and much shorter incubation periods are required than with usual procedures. It is not necessary to incubate sections in hot solutions for extended periods of time, which can lead to detachment of sections, nonspecific staining and decomposition of the silver solution. Rinsing after impregnation and before development greatly increases contrast of argyrophil cells by reducing background staining. Our procedure results in more reliable staining of argyrophil and argentaffin cells and takes only ten minutes.     

Metal-catalyzed oxidation renders silver intensification selective. Applications for the histochemistry of diaminobenzidine and neurofibrillary changes

Physical developers can increase the visibility of end products of certain histochemical reactions, such as oxidative polymerization of diaminobenzidine and selective binding of complex silver iodide ions to Alzheimer's neurofibrillary changes. Unfortunately, this intensification by silver coating is generally superimposed on a nonspecific staining originating from the argyrophil III reaction, which also takes place when tissue sections are treated with physical developers. The present study reveals that the argyrophil III reaction can be suppressed when tissue sections are treated with certain metal ions and hydrogen peroxide before they are transferred to the physical developer. The selective intensification of Alzheimer's neurofibrillary changes requires a pre-treatment with lanthanum nitrate (10 mM/liter) and 3% hydrogen peroxide for 1 hr. The diaminobenzidine reaction can be selectively intensified when physical development is preceded by consecutive treatments with copper sulfate (10 mM/liter, pH 5, 10 min) and hydrogen peroxide (3%, pH 7, 10 min). In peroxidase histochemistry, this high-grade intensification may help to increase specificity and reduce the threshold of detectability in tracing neurons with horseradish peroxidase or in immunohistochemistry when the peroxidase-antiperoxidase method is used.     

Catecholamine-containing pancreatic islet cells of the domestic fowl

Summary In an attempt to identify pancreatic islet cells emitting formaldehyde-induced fluorescence (FIF), the pancreatic islets of the domestic fowl were studied by combined fluorescence, ultrastructural, silver-impregnation and immunohistochemical methods in the same section or in consecutive semi-thin and ultra-thin sections. The results indicate that islet cells emitting intense FIF exhibit a strongly argyrophil reaction with the Grimelius' silver method and also immunohistochemical reaction with anti-glucagon serum, but not with anti-5-HT serum. Therefore, the fowl islet A cell, a peptide hormone-producing cell, stores simultaneously catecholamine as biogenic amine. The islet B and D cells did not display any FIF, any argyrophil reaction with the Grimelius' silver method, or any immunoreactivity with anti-glucagon or anti-5-HT sera. The fluorescent but non-argyrophil cells dispersed in the exocrine acinus may well be PP cells.     

Silver stains for identification of neuroendocrine cells. A study of the chemical background

Summary The chemical background of silver stains used for visualization and characterization of peripheral neuroendocrine cells in the gastrointestinal tract and pancreas, and of their corresponding tumours, was studied in tissue sections and by a dot-blot technique. Sequential staining of pancreatic islets with an immunohistochemical procedure and silver staining of the same tissue section revealed that chromogranin A immunostained cells also displayed an argyrophil reaction with the Grimelius method, but no argentaffin reaction with the Masson technique. Accordingly, purified chromogranin A (15 g or less) treated in formalin and applied to nitrocellulose did not show any argentaffin reaction but displayed a dose-related argyrophil reaction. Equal quantities of other polypeptide components did not give rise to any silver reaction. Further dot-blot studies showed that the tryptophan and tyrosine metabolites, dopamine, norepinephrine, 5-hydroxytryptamine and 5-hydroxindole caused strongly argentaffin and argyrophil reactions while epinephrine, 5-hydroxyindole-3-acetic acid and 5-hydroxytryptophan gave only the former reaction. Among other chemical components studied, only guanine displayed weak silver staining. The results indicate that the reaction products between aldehydes and the granular content of biogenic amines synthesized from tryptophan and tryosine display an argentaffin reaction and that the granular chromogranin A caused an argyrophil but no argentaffin reaction.     

Electron microscopic classification of amine-producing endocrine cells by selective staining of ultra-thin sections

Summary The argyrophil, argentaffin and chromaffin reactions were performed directly on ultra-thin sections for examination in the electron microscope. Glutaraldehyde fixation was appropriate for the argentaffin and chromaffin reactions; additional fixation with osmium tetroxide, however, caused impairment of these reactions. Fixation with formaldehyde, but not with glutaraldehyde, was adequate for the argyrophil reaction; post-fixation with osmium tetroxide did not affect this staining. At the light microscopic level the staining reactions were correlated with fluorescence histochemistry according to the method of Falck and Hillarp. The techniques described were used to study certain amine-producing endocrine cell systems: adrenal medullary cells and thyroid parafollicular cells of the mouse, gastric endocrine cells from the oxyntic gland area of the mouse, rat and rabbit. All these cells stained argyrophil. The adrenal medullary cells and one cell type in the oxyntic gland area of the rabbit were strongly argentaffin and chromaffin. The remainder of the cells were non-argentaffin and non-chromaffin but could be induced to give an argentaffin (and chromaffin) reaction after injection of the animals with l-3,4-dihydroxyphenylalanine or l-5-hydroxytryptophan, a treatment which is known to result in the accumulation of the highly reducing dopamine and 5-hydroxytryptamine, respectively, in these endocrine cells. Without exception the precipitates formed in all the staining reactions accumulated selectively over the secretory granules of the cells.The techniques described permit differential staining of consecutive ultra-thin sections for electron microscopic characterization of one and the same cell. They will provide information necessary for correlative studies of the stainable cells at the light and electron microscopic levels.     

The islets of Langerhans in ducks and chickens with special reference to the argyrophil reaction

Summary The pancreas of birds is a suitable object for studying the A and B cells separately, since the two cell systems are topografically almost entirely segregated in the form of light (= B cells) and dark (= A cells) islets of Langerhans.On the whole in the chicken and duck the actual distribution of the light islets into different size classes followed the same regular pattern previously found in the rat and man. In the body of the pancreas, containing the great majority of islets, the volume distribution curves thus appeared symmetrical.With the silver impregnation method used a distinct argyrophil reaction in both types of islets was obtained on paraffin sections of the pancreas. According to the presence or absence of blackening, the cells of the dark islets could be divided into two distinct fractions. Especially in the duck the silver-positive cells were grouped in a characteristic way along the walls of the capillaries. Ducks and chickens are not the only animals in which it is possible to identify an argyrophil fraction in what the usual granule stains had shown to be A cells. Parallel studies of various mammals are in complete agreement with these observations. It is, however, still uncertain whether we are here dealing with differences in function, age etc. in one and the same type of cell or with two completely different kinds. No correlation between the argyrophil reaction in the dark islet cells and their content of SH and SS groups or tryptophane could be established.This work was aided by grants from the Swedish Medical Research Council.     

Identification of enterochromaffin cells in adjacent Epon-embedded sections at light and electron microscopic levels

Summary Methods for light and electron microscopic comparison of individual argentaffin and argyrophil enterochromaffin cells (EC) in the sheep duodenal mucosa are described. These silver procedures were applied for light microscopy to Epon-embedded sections. The adjacent sections were examined with the electron microscope. The most specific characteristics of the argentaffin and argyrophil EC in electron microscopy are highly osmiophilic cytoplasmic granules. In one cell type these granules are smaller and more roundish than in the another type. These two cell types are stainable both by the argentaffin and argyrophil reactions. No essential difference can be observed in the localization of these elements. It is suggested that both cell types belong to the enterochromaffin system. Both silver methods are also suitable for the light microscopic identification of other intestinal structures in sections adjacent to that sectioned for electron microscopy.This work was supported by a grant from the Yrjö Jahnsson Foundation, Helsinki, Finland.The electron microscopic observations were carried out in the Electron Microscope Laboratory, University of Helsinki.     

A new method for easy demonstration of argyrophil cells.

A new method for silver impregnation of endocrine cells of the gastrointestinal mucosa is described. It offers great reliability, eveness of impregnation, and, since it can be used on batches of slides, is also suitable for histology class and investigation material. The procedure for paraffin sections of formalin-fixed material is as follows: dewax and transfer to distilled water, leave in 0.5% silver nitrate solution for 2 hours at 60 C. Rinse in distilled water, then treat in Bodian developer (hydroquinone, 1 g; sodium sulphite, 5 g; distilled water, 100 ml) previously heated to 60 C. Rinse in running tap water, distilled water, and then re-impregnate for 10 minutes at 60 C in the same silver solution and reduce in Bodian's solution. Since the background is not impregnated by this method, sections may be counterstained by any basic anilin dye to bring out nuclei. A 0.1% kernechtrot solution was found very satisfactory in this respect. The granulations of argyrophil cells stand out sharply black against a red background.     

A New Method for Easy Demonstration of Argyrophil Cells

A new method for silver impregnation of endocrine cells of the gastrointestinal mucosa is described. It offers great reliability, eveness of impregnation, and, since it can be used on batches of slides, is also suitable for histology class and investigation material. The procedure for paraffin sections of formalin-fixed material is as follows: dewax and transfer to distilled water, leave in 0.5% silver nitrate solution for 2 hours at 60 C. Rinse in distilled water, then treat in Bodian developer (hydroquinone, 1 g; sodium sulphite, 5 g; distilled water, 100 ml) previously heated to 60 C. Rinse in running tap water, distilled water, and then re-impregnate for 10 minutes at 60 C in the same silver solution and reduoc in Bodian's solution. Sma the background is not impregnated by this method, sections may be counterstained by any basic anilin dye to bring out nuclei. A 0.1% kernechtrot solution was found very satisfactory in this respect. The granulations of argyrophil cells stand out sharply black against a red background.     

Enteroglucagon and substance P-like immunoreactivity in argentaffin and argyrophil rectal carcinoids.

A specific immunofluorescence for enteroglucagon or substance P or for both hormones was demonstrated in nine out of 12 examined rectal carcinoids. One tumor was argentaffin, contained ultrastructurally pleomorphic granules of the entero-chromaffin cell type, and showed immunofluorescence for substance P. The rest were non-argentaffin but were argyrophil with the Grimelius technique and contained round granules. The argyrophil carcinoids were immunoreactive to one or both hormones in eight cases and not fluorescent in three cases. In two of the non-argentaffin carcinoids a small number of argyrophil cells was found with the method of Sevier-Munger.     

Neuron-specific enolase in mucosal endocrine cells and carcinoid tumours of the small intestine: A comparative study with neuron-specific enolase immunocytochemistry and silver stains

Summary Endocrine cells of human small intestinal mucosa, small intestinal carcinoids and carcinoid liver metastases were stained with an immunocytochemical technique using an antiserum against neuron-specific enolase (NSE), with the argyrophil technique of Grimelius and with the argentaffin technique of Masson. In the normal mucosa, scattered NSE-immunoreactive cells were seen mainly in the deeper parts of the crypts. These cells, as shown in the same sections, corresponded to the argentaffin and/or argyrophil cells indicating that they were of endocrine type.All intestinal carcinoids (16 cases) displayed NSE immunoreactivity. However, this reaction did not correlate on the cellular level with the silver techniques employed. Thus, many tumour cells were NSE immunoreactive but lacked an argentaffin or argyrophil reaction and vice versa. On the light microscopical level the silver techniques reveal the presence of neurohormonal granules in the tumour cells, while the NSE immunoreactivity appears to disclose neuroendocrine differentiation of the tumour cells irrespective of their hormone and granular content.Out of 13 carcinoid liver metastases, eight displayed strong NSE immunoreactivity, three were weakly stained and two were unreactive. Consecutive or the same tumour sections showed an argentaffin and argyrophil reaction in all carcinoid metastases. Since silver staining provides one type of information and NSE immunocytochemistry another, they provide in combination a good discriminator for neuroendocrine tumours.     

Endocrine cells of the human gastric mucosa

Summary By light and electron microscopy investigation of the human gastric mucosa five types of ultrastructurally different endocrine cells have been detected: 5-hydroxytryptamine storing enterochromaffin (EC) cells, gastrin storing G cells, and functionally undefined ECL, D and D₁ cells. By direct application of Masson's argentaffin reaction as well as of Sevier-Munger's and Grimelius' argyrophil method to electron microscopy specimens, selective deposition of silver grains upon the endocrine granules of such cells was obtained. In particular, only EC cell granules reacted to the argentaffin method, granules of both EC and ECL cells heavily reacted to Sevier-Munger's technique, granules of EC, ECL, G and D₁ cells reacted to Grimelius' technique, while D cell granules failed to react either to argentaffin or argyrophil methods. By the application of the same silver methods to paraffin sections as well as by other selective staining methods for endocrine granules (5-hydroxytryptamine techniques, lead-haematoxylin, HCl-basic dye method), at least four of the above cell types were also identified under light microscope. This opens the way for extensive studies of such cells in conventional histologie specimens.This investigation was supported in part by grant N.70.01022.04 from the Italian Consiglio Nazionale delle Ricerche.     

小鼠胃肠道嗜银细胞的分布及形态学观察

用Grimelius嗜银法对10只小鼠胃肠道嗜银细胞的分布及形态学作了观察研究,结果显示：（l）小鼠嗜银细胞的分布密度,在胃体部最高,从十二脂肠、空肠、回肠、盲肠直到结肠依次减少。（2）嗜银细胞的形态也是多种多样,有梭形、锥体形、椭圆形等。     

Electron-microscopical evidence for heterogeneity of micronodular argyrophil cell growth in man

Hypergastrinaemia-associated changes of non-antral argyrophil cells in man are of increasing interest, because of the development of potent inhibitors of gastric acid secretion. Using an antibody against chromogranin A, we identified micronodular endocrine cell hyperplasia of the oxyntic mucosa in gastric biopsy specimens of patients with hypergastrinaemia of different backgrounds. Consecutive ultrathin sections were examined at the electron-microscopical level. Endocrine cell types within the (extraepithelial) micronodules closely resembled those in the adjacent mucosa. Micronodules were classified into two groups. The first group was composed of endocrine cells only and predominated in patients with drug-induced hypergastrinaemia and/or chronic gastritis, and in a gastrinoma/MEN I patient. The second group represented “neuroendocrine complexes”, showing a close intermingling of non-myelinated nerve fibres with endocrine cells, and was found predominantly in pernicious anaemia. Micronodular argyrophil cell growth in man is therefore heterogeneous and depends on the background of the hypergastrinaemia.     

On the occurrence of argyrophil cells in salivary glands

Summary Salivary glands (parotid, submandibular and sublingual glands) of nine mammalian species were investigated with respect to presence and localization of argyrophil and argentaffin cells. With the exception of the parotid gland of the rat, no positive staining was observed within the examined glands. In the rat parotid distinctly argyrophil cells could be demonstrated in the intercalated ducts. Histochemical studies of the cells, ultrastructural analysis of their cytoplasmic granules as well as their reactions to certain drugs indicate that these cells are of exocrine rather than of endocrine nature. After a subcutaneous injection of pilocarpine, the intensity of the argyrophil staining was markedly reduced. No specific catecholamine fluorescence could be detected within the cells, not even after pretreatment of the animals with high doses of L-DOPA. The membrane-bounded cytoplasmic granules of the intercalated duct cells furthermore displayed a strong positive staining reaction after treatment of ultrathin Vestopal sections with the periodic acid-chromic acid-silver technique of Rambourg et al. (1969).Supported by grants from the Swedish Medical Research Council (Project No. 12X-718), and the Medical Faculty of the University of Umeå. The skilful technical assistance of Miss Siw Domeij is gratefully acknowledged     

刺猬消化道嗜银细胞形态与分布

通过用龙桂开浸银法对刺猬消化道各段进行组织切片观察,结果表明嗜银细胞分布于胃贲门及以下所有消化管,其中胃、十二指肠与小肠末段嗜银细胞分布密度较高,小肠中段及直肠末段密度较低。嗜银细胞分布于消化管壁粘膜层腺体与绒毛,其中在腺体密度较高,在绒毛较低,并且胃、小肠壁固有膜腺体的中、底部密度最高,另外在胃幽门有狭小的高密度分布区。嗜银细胞有锥体形、瓜子形、椭圆形、长梭形、圆形等。锥体形、瓜子形、长梭形多有明显的长突起。嗜银颗粒或充满整个细胞,或集中于突起端或基底部。细胞外常可见到刚释放的嗜银颗粒,特别是锥体形、瓜子形细胞的尖端处常可见到向腺管腔或肠腔释放的嗜银颗粒。     

白条草蜥消化道嗜银细胞的分布和形态学观察

应用Grimelius银染法对白条草蜥消化道嗜银细胞进行了染色和切片观察.结果 表明:在白条草蜥的消化道中嗜银细胞分布广泛,见于其全长.其嗜银细胞形态多样,主要有锥体形、椭圆形等;其嗜银细胞分布密度于胃幽门最高,胃体次之,十二指肠最低.其消化道嗜银细胞分布型的形成与生活环境和取食方式等有关;根据其形态,嗜银细胞具有内、外分泌两种功能.