A Phloxine-Azure-Hematoxylin Sequence for Differential Staining of Cells in Pancreatic Islets

Sections of 6 μ from tissues fixed in Susa or in Bouin's fluid (without acetic acid) and embedded in paraffin were attached to slides with Mayer's albumen, dried at 37 C for 12 hr, deparaffinized and hydrated. The sections fixed in Susa were transferred to a I₂-K₁ solution (1:2:300 ml of water); rinsed in water, decolorized in 5% Na₂S₂O₃; washed in running water, and rinsed in distilled water. Those fixed in Bouin's were transferred to 80% alcohol until decolorized, then rinsed in distilled water. All sections were stained in 1% aqueous phloxine, 10 min; rinsed in distilled water and transferred to 3% aqueous phosphotungstic acid, 1 min; rinsed in distilled water; stained 0.5 min in 0.05 azure II (Merck), washed in water; and finally, nuclear staining in Weigert's hematoxylin for 1 min was followed by a rinse in distilled water, rapid dehydration through alcohols, clearing in xylene and covering in balsam or a synthetic resin. In the completed stain, islet cells appear as follows: A cells, purple; B cells, weakly violet-blue; D cells, light blue with evident granules; exocrine cells, grayish blue with red granules.     

Differentiation of Cells in the Hypophysis and in Pancreatic Islets

Deparaffinized, 3-5μ, sections are brought to water, oxidized 3.5 min in an equal-parts mixture of 0.3% H₂SO₄ and 0.3% KMnO₄, and decolorized with 4% K₂S₂O₅. Nuclei are stained with Gomori's (1939) chromium-hematoxylin, and cell granules with Cason's (1950) mixture. The eosinophilic cells of the hypophysis and the alpha cells of pancreatic islets (of Langerhans) stain carmine red; basophilic and beta cells stain dark blue. Heidenhain's _susa is the most suitable fixative for hypophysis, Bouin's fluid for pancreas; but a satisfactory result is obtainable after formalin-sublimate or plain formalin. Besides studying the ratio of the cell types in the hypophysis or in pancreatic islets, it is possible to estimate the granule content of the cells. The method works on human autopsy material provided fixation of hypophysis occurs within 24 hr, and. pancreas, 12 hr post mortem, and it is suitable also for quite fresh organs.     

Differentiation of Cells in the Hypophysis and in Pancreatic Islets

Deparaffinized, 3-5μ, sections are brought to water, oxidized 3.5 min in an equal-parts mixture of 0.3% H₂SO₄ and 0.3% KMnO₄, and decolorized with 4% K₂S₂O₅. Nuclei are stained with Gomori's (1939) chromium-hematoxylin, and cell granules with Cason's (1950) mixture. The eosinophilic cells of the hypophysis and the alpha cells of pancreatic islets (of Langerhans) stain carmine red; basophilic and beta cells stain dark blue. Heidenhain's _susa is the most suitable fixative for hypophysis, Bouin's fluid for pancreas; but a satisfactory result is obtainable after formalin-sublimate or plain formalin. Besides studying the ratio of the cell types in the hypophysis or in pancreatic islets, it is possible to estimate the granule content of the cells. The method works on human autopsy material provided fixation of hypophysis occurs within 24 hr, and. pancreas, 12 hr post mortem, and it is suitable also for quite fresh organs.     

The Demonstration of Beta Cells in Pancreatic Islets and Their Tumors

The stain is applied routinely to tissues fixed in 10% buffered formalin (pH near 7.0) or in Bouin's fluid. Bring paraffin section to water as usual and mordant 72 hr in 5% CrCl₃ dissolved in 5% acetic acid. Wash in water and in 70% alcohol and stain 6 hr. Formula of staining solution: new fuchsin, 1% in 70% alcohol, 100 ml; HCl, conc., 2 ml and paraldehyde, 2 ml, mixed together and added to the dye solution; let stand 24 hr before use. After staining, wash in running tap water 5-10 min, rinse in distilled water and counterstain if desired. Dehydration in alcohol, clearing and covering completes the process. When the paraldehyde is obtained from a freshly opened bottle, standardized staining times can be used and thus eliminate the necessity of differentiating individual slides. The granules of beta cells stained deep blue to purple and were demonstrated in the pancreatic islet of man, dog, mouse, frog, guinea pig and rabbit.     

A Historical Perspective on the Identification of Cell Types in Pancreatic Islets of Langerhans by Staining and Histochemical Techniques

Before the middle of the previous century, cell types of the pancreatic islets of Langerhans were identified primarily on the basis of their color reactions with histological dyes. At that time, the chemical basis for the staining properties of islet cells in relation to the identity, chemistry and structure of their hormones was not fully understood. Nevertheless, the definitive islet cell types that secrete glucagon, insulin, and somatostatin (A, B, and D cells, respectively) could reliably be differentiated from each other with staining protocols that involved variations of one or more tinctorial techniques, such as the Mallory-Heidenhain azan trichrome, chromium hematoxylin and phloxine, aldehyde fuchsin, and silver impregnation methods, which were popularly used until supplanted by immunohistochemical techniques. Before antibody-based staining methods, the most bona fide histochemical techniques for the identification of islet B cells were based on the detection of sulfhydryl and disulfide groups of insulin. The application of the classical islet tinctorial staining methods for pathophysiological studies and physiological experiments was fundamental to our understanding of islet architecture and the physiological roles of A and B cells in glucose regulation and diabetes.     

Metachromatic Reaction of Pancreatic B Cells to Toluidine Blue; Influence of pH on Staining

The granules of islet B cells show an intense β metachromasia when paraffin sections of pancreas fixed in Bouin's fluid or formalin are dipped for 1 min in a 0.1% aqueous solution of toluidine blue O₂ buffered to pH 6.0 with acetate or phosphate. This reaction provides a quick method for surveying the condition of B cells in experimental work. A weak staining is observable at pH 4.5 and becomes distinct at pH 5.5-6.0. Oxidation of sections (0.25% KMnO₄ in 0.5% H₂SO₄, for 1 min, recommended) prior to staining intensifies the metachomatic reaction conspicuously. The metachromatic substance could not be demonstrated after fixation in either ethanol or acetone. It corresponds to the aldehyde fuchsin-positive and pseudoisocyanin-metachromatic substance in its occurrence and distribution in the B cells, as shown by different physiological states of various animals, including fasted and glucose-administered guinea pigs. It is thought to be topographically coincident but not necessarily identical to insulin.     

Optimizing Conditions for Rat Pancreatic Islets Isolation

Many procedures have been described for rat pancreatic islet isolation. Several factors contribute to the pancreatic islet isolation outcome. One of the main problems in islet isolation procedure is the formation of a viscouse, gellike structure during collagenase digestion which entraps the free islets and decrease islet yield after density gradient purification. This issue has not been addressed in most techniques described for rat islet isolation. We examined effect of various factors to eliminate formation of gellike material and improve the islets yields. Islet isolation was performed on 26 adult male Wistar Albino rats weighing between 280 and 350 g. We have observed that several factors affect pancreatic islet isolation. Optimum Collagenase enzyme concentration, maintaining pH range between 7.7 and 7.9 in digestion solution, incubation temperature at 38±1 °C and addition of Calcium ion decreased the formation of gellike materials and increased islet yield. Addition of Glycerol as a gelatin solvent has also been helpful in the reduction or complete elimination of gellike material. Precise optimization of rat islet isolation procedure is useful to improve the islet yield in islet transplantation studies.     

大鼠胰岛分离条件的优化

目的:优化大鼠胰岛分离纯化的条件,为胰岛移植实验奠定基础。方法:通过胆总管灌注胶原酶P来消化大鼠胰腺,分离胰岛,采用不连续密度梯度Ficoll离心法纯化胰岛,观察胶原酶浓度、消化时间以及大鼠体重对胰岛分离结果的影响。双硫腙染色鉴定胰岛,丫啶橙/碘丙啶染色鉴定胰岛细胞活率,糖刺激胰岛素释放试验评价胰岛功能。结果:胶原酶浓度、消化时间以及大鼠体重对胰岛分离结果有重要影响。1mg/ml胶原酶P在37℃静止消化45分钟条件下,胰岛分离效果最佳,效果较其他酶浓度和消化时间条件下好(P＜0．05)。体重350g的大鼠的胰岛收获量778．33±80．21IEQ/胰腺,而体重250g的大鼠的胰岛收获量655．00±56．56 IEQ/胰腺(P＜0．05)。优化条件下分离的胰岛其纯度＞90%,胰岛细胞活率＞90%,低糖(2．8mmol/L)、高糖(16．7mmol/L)刺激胰岛素释放分别为(5．40±1．75)mIU/L/30IEQ,(12．27±2．55)mIU/L/30IEQ(P＜0．05),刺激指数为2．33±0．29。结论:胶原酶浓度、消化时间以及大鼠体重影响胰岛分离结果,优化分离条件可改善大鼠胰岛分离结果。     

Modeling K,ATP-Dependent Excitability in Pancreatic Islets

In pancreatic β-cells, K,ATP channels respond to changes in glucose to regulate cell excitability and insulin release. Confirming a high sensitivity of electrical activity to K,ATP activity, mutations that cause gain of K,ATP function cause neonatal diabetes. Our aim was to quantitatively assess the contribution of K,ATP current to the regulation of glucose-dependent bursting by reproducing experimentally observed changes in excitability when K,ATP conductance is altered by genetic manipulation. A recent detailed computational model of single cell pancreatic β-cell excitability reproduces the β-cell response to varying glucose concentrations. However, initial simulations showed that the model underrepresents the significance of K,ATP activity and was unable to reproduce K,ATP conductance-dependent changes in excitability. By altering the ATP and glucose dependence of the L-type Ca²⁺ channel and the Na-K ATPase to better fit experiment, appropriate dependence of excitability on K,ATP conductance was reproduced. Because experiments were conducted in islets, which contain cell-to-cell variability, we extended the model from a single cell to a three-dimensional model (10×10×10 cell) islet with 1000 cells. For each cell, the conductance of the major currents was allowed to vary as was the gap junction conductance between cells. This showed that single cell glucose-dependent behavior was then highly variable, but was uniform in coupled islets. The study highlights the importance of parameterization of detailed models of β-cell excitability and suggests future experiments that will lead to improved characterization of β-cell excitability and the control of insulin secretion.     

Modeling K,ATP-Dependent Excitability in Pancreatic Islets

In pancreatic β-cells, K,ATP channels respond to changes in glucose to regulate cell excitability and insulin release. Confirming a high sensitivity of electrical activity to K,ATP activity, mutations that cause gain of K,ATP function cause neonatal diabetes. Our aim was to quantitatively assess the contribution of K,ATP current to the regulation of glucose-dependent bursting by reproducing experimentally observed changes in excitability when K,ATP conductance is altered by genetic manipulation. A recent detailed computational model of single cell pancreatic β-cell excitability reproduces the β-cell response to varying glucose concentrations. However, initial simulations showed that the model underrepresents the significance of K,ATP activity and was unable to reproduce K,ATP conductance-dependent changes in excitability. By altering the ATP and glucose dependence of the L-type Ca²⁺ channel and the Na-K ATPase to better fit experiment, appropriate dependence of excitability on K,ATP conductance was reproduced. Because experiments were conducted in islets, which contain cell-to-cell variability, we extended the model from a single cell to a three-dimensional model (10×10×10 cell) islet with 1000 cells. For each cell, the conductance of the major currents was allowed to vary as was the gap junction conductance between cells. This showed that single cell glucose-dependent behavior was then highly variable, but was uniform in coupled islets. The study highlights the importance of parameterization of detailed models of β-cell excitability and suggests future experiments that will lead to improved characterization of β-cell excitability and the control of insulin secretion.     

The Pancreatic Islets of Bony Fishes

The biology of the fish endocrine pancreas is discussed fromviewpoints of cytology, peripheral physiology, and control ofislet secretion. The clear cell often described in Brockmannbodies is probably not a real entity, but the islets of manyfish species probably contain a fourth granular cell type inaddition to the usual population of A-, B-, and D-cells. Numerousstudies employing islet cytotoxins and exogenous hormone treatmentshave been reported, but a unified concept of islet functionin any fish species still does not exist. Recent data indicatethat metabolic parameters other than blood sugar must be measuredin order to obtain a more accurate assessment of islet function.The direct relationship of the nervous system to islet endocrinecells also raises questions regarding the control of islet secretionand necessitates consideration of laboratory conditions andseasonal or diurnal variation as probable influencing factorsof islet activity.     

Comparative Histophysiology of the Pancreatic Islets

The embryological origin of the islet tissue from a common entodermalanlage with the exocrine pancreas has been questioned recently.The islet tissue may be of. neural crest origin, and the ancestralislet cells may have been "taste cells in the gut." Whether the separation of exocrine and endocrine tissue in thecyclostomes is an original one or not remains an open phylogenetickey question. One or more islet hormones affect the exocrine pancreas tissue.However, the islet topography in various groups shows that intrapancreaticislet dissemination is not a general prerequisite for the normalfunction of the exocrine tissue. The D-cell is now generally recognized as the source of a thirdislet hormone. A fourth granular cell type (X-cell) may wellsecrete a fourth islet hormone. The significance of the amphiphilislet cells, found in various species, and of the "light" cellsof the cyclostomes requires further studies. The islet function in lower vertebrates is largely unknown.So far, neither the islet cytology nor the known effects ofpancreatectomy allow far-reaching conclusions. The evolutionof the islet functions may be only understood when their interactionswith the pituitary functions become clear.     

Basic Fuchsin-Crystal Violet; A Rapid Staining Sequence for Juxtaglomerular Granular Cells Embedded in Epoxy Resin

A basic fuchsin-crystal violet staining sequence for demonstration of juxtaglomerular granular cells in epoxy-embedded tissues is rapid and results in slides with excellent contrast and intensity. Procedure: Cut sections 0.3-0.6 μ thick. Hydrate through xylene and alcohol to water. Stain in modified Goodpasture's stain (basic fuchsin, 1; aniline, 1; phenol, 1; 30% alcohol, 100) for 20-30 sec; rinse in tap water; stain in modified Stirling's (crystal violet, 5; alcohol, 10; aniline, 2; water, 88) for 20-30 sec; rinse in tap water and dry on a hotplate; mount in a synthetic resin. Granular cells of the juxtaglomerular apparatus are stained an intense dark blue by the crystal violet. Arterial elastic membranes and collagen are pale blue. Other structures are shades of red.     

Co-Transplantation of Endothelial Progenitor Cells and Pancreatic Islets to Induce Long-Lasting Normoglycemia in Streptozotocin-Treated Diabetic Rats

Graft vascularization is a crucial step to obtain stable normoglycemia in pancreatic islet transplantation. Endothelial progenitor cells (EPCs) contribute to neoangiogenesis and to the revascularization process during ischaemic events and play a key role in the response to pancreatic islet injury. In this work we co-transplanted EPCs and islets in the portal vein of chemically-induced diabetic rats to restore islet vascularization and to improve graft survival. Syngenic islets were transplanted, either alone or with EPCs derived from green fluorescent protein (GFP) transgenic rats, into the portal vein of streptozotocin-induced diabetic rats. Blood glucose levels were monitored and intraperitoneal glucose tolerance tests were performed. Real time-PCR was carried out to evaluate the gene expression of angiogenic factors. Diabetic-induced rats showed long-lasting (6 months) normoglycemia upon co-transplantation of syngenic islets and EPCs. After 3–5 days from transplantation, hyperglycaemic levels dropped to normal values and lasted unmodified as long as they were checked. Further, glucose tolerance tests revealed the animals'' ability to produce insulin on-demand as indexed by a prompt response in blood glucose clearance. Graft neovascularization was evaluated by immunohistochemistry: for the first time the measure of endothelial thickness revealed a donor-EPC-related neovascularization supporting viable islets up to six months after transplant. Our results highlight the importance of a newly formed viable vascular network together with pancreatic islets to provide de novo adequate supply in order to obtain enduring normoglycemia and prevent diabetes-related long-term health hazards.     

A Formalin-Wright Staining Technique for Avian Blood Cells

A rather concentrated alcoholic staining solution, an aqueous formalin-containing diluent, and a mixture of ethyl ether and absolute methyl alcohol are required. Formulas: A. Wright's stain (Harleco, Cert. No. LWr-52 was used), 3.3 gm; methyl alcohol, 500 ml. B. Formaldehyde solution 40% USP (Fisher's used), 0.25 ml; distilled water, 500 ml with its pH adjusted to 6.8 by addition of either 0.25% Na₂CO₂ or 0.25% HCl, as needed. C. A I:I mixture of ethyl ether and absolute methyl alcohol. Procedure: Prepare thin smears of normal or pathological avian blood, air dry, place the slides on a drying rack, cover with solution A, and let stand for about 8 min. Dilute the stain by dropping on a volume of B estimated to be equal to the volume of the partially evaporated stain, and let stand for 2-5 min, or until the surface is well covered by a metallic sheen. Wash with distilled water adjusted to pH 6.8 with the 0.25% Na₂CO₂ solution or 0.25% HCl. Dry the preparations quickly by blotting with filter paper. Differentiate and adjust the color intensities by dipping 6-10 times into C. Check the results microscopically and differentiate further if the colors are not properly balanced. Dry, uncovered preparations may be examined under oil; or, a cover glass can be applied with balsam or a synthetic resin for permanent mount. Results are similar to those described in textbooks, but have been more consistent than those obtained with other techniques for blood cells of chicken, pheasants, American and Indian partridge, quail, pigeon, turkey, goose, canary, and the Himalayan snow partridge.     

A Double Mechanism for the Mesenchymal Stem Cells' Positive Effect on Pancreatic Islets

The clinical usability of pancreatic islet transplantation for the treatment of type I diabetes, despite some encouraging results, is currently hampered by the short lifespan of the transplanted tissue. In vivo studies have demonstrated that co-transplantation of Mesenchymal Stem Cells (MSCs) with transplanted pancreatic islets is more effective with respect to pancreatic islets alone in ensuring glycemia control in diabetic rats, but the molecular mechanisms of this action are still unclear.The aim of this study was to elucidate the molecular mechanisms of the positive effect of MSCs on pancreatic islet functionality by setting up direct, indirect and mixed co-cultures.MSCs were both able to prolong the survival of pancreatic islets, and to directly differentiate into an “insulin-releasing” phenotype. Two distinct mechanisms mediated these effects: i) the survival increase was observed in pancreatic islets indirectly co-cultured with MSCs, probably mediated by the trophic factors released by MSCs; ii) MSCs in direct contact with pancreatic islets started to express Pdx1, a pivotal gene of insulin production, and then differentiated into insulin releasing cells. These results demonstrate that MSCs may be useful for potentiating pancreatic islets'' functionality and feasibility.     

一种改良的肌细胞骨架染色方法

为了观察肌细胞骨架,对传统考马斯亮蓝染色法进行改良,并与免疫荧光染色法进行了比较。培养的血管平滑肌细胞先用多聚甲醛预固定后再进行考马斯亮蓝染色,可使细胞骨架非常清晰的显色,解决了传统考马斯亮蓝染色易使肌细胞变形、脱片的问题,其效果与免疫荧光染色相近。因此,多聚甲醛预固定．考马斯亮蓝染色法是一种适于肌细胞骨架染色的简便方法。