Impurities and staining characteristics of Alcian Blue samples

Synopsis The composition of various samples of Alcian Blue^* and related dyes was studied, using t.l.c. (with cellulose as adsorbent andn-butanol: acetic acid: water as developing solvent), solvent extraction and precipitation, i.r. spectroscopy and classical semimicro analysis. All the Alcian Blue samples appeared to contain the same coloured components. The Alcian Green samples were mixtures of these blue components and Alcian Yellow. All the Astra Blue samples examined were composed of the same blue constituents. Colourless components identified were boricacid, dextrin and sulphate and sometimes amounted to nearly three-quarters by weight of the crude dyes. Impurities had only a slight effect on staining with Alcian Blue in aqueous acetic acid but appreciably affected staining by the critical electrolyte concentration (C.E.C.) procedure. Dextrin as impurity raised C.E.C. limits while the inorganic salt impurities raised the C.E.C. values of some substrates and lowered those of others.     

Polyacrylamide-gel electrophoresis and Alcian Blue staining of sulphated glycosaminoglycan oligosaccharides.

Oligosaccharide fragments of glycosaminoglycans may be separated for rapid analysis by electrophoresis through a 10% polyacrylamide matrix. An extensive ladder-like set of bands is observed for partial testicular hyaluronidase digests of chondroitin 4- or 6-sulphate, and for dermatan sulphate. Co-electrophoresis of purified oligosaccharides has established that the major bands of these patterns represent fragments differing in chain length by one disaccharide unit, with the smallest fragments having the greatest mobility. Additional minor bands, representing heterogeneity in the repeating unit structure, are also observed. There are slight differences in the mobilities of oligosaccharides derived from the three major types of sulphated glycosaminoglycans. Alcian Blue is employed for visualization of the digest fragments. Sample loads of 5-10 micrograms per band appear optimum. The smallest oligosaccharide which may be stained by this method is the hexasaccharide. After consideration of this effect, a good correlation is found to exist between densitometric scans of the gel-electrophoretic patterns and gel-filtration chromatographic profiles based on uronic acid concentration.     

Alcian blue staining of proteoglycans in polyacrylamide gels using the "critical electrolyte concentration" approach

A method is described here for Alcian blue staining of proteoglycans in polyacrylamide gels; this is illustrated using extracts obtained from bovine corneal stroma. Other available methods for visualization of proteoglycans can produce nonspecific staining and frequently a high background in the gel; with a "critical electrolyte concentration" approach, specific staining against a clear background can be obtained.     

An alternative Alcian Blue dye variant for the evaluation of fetal cartilage

BACKGROUND: The most comprehensive evaluation of vertebrate skeletal development involves the use of Alizarin Red S dye to stain ossified bone and various other dyes to stain cartilage. The dye used most widely to stain fetal cartilage in rodents and rabbits is Alcian Blue 8GX. However, the global supply of this specific dye has been exhausted. Several forms of the dye marketed as Alcian Blue 8GX are now available, although they are not synthesized via the original 8GX manufacturing process. METHODS: One new Alcian Blue 8GX form and two Alcian Blue dye variants were evaluated in rats and rabbits using standard staining procedures. The staining quality of these dyes were evaluated relative to the original form of Alcian Blue 8GX based on cartilage uptake of the dye, clarity of the cartilaginous components, staining intensity of the dye, and overall readability of the specimens under stereomicroscopic evaluation. RESULTS: Staining with the newer form of Alcian Blue 8GX resulted in poor staining quality. The Alcian Blue-Pyridine variant performed well, although staining intensity was less than optimal. The Alcian Blue-Tetrakis variant provided staining characteristics that were most similar to the original form of Alcian Blue 8GX. CONCLUSIONS: Alcian Blue-Tetrakis was markedly better in its ability to stain fetal cartilage than the newer form of Alcian Blue 8GX.     

Bismuth staining for light and electron microscopy.

Bismuth salts on aldehyde fixed tissue give a highly selective pattern of staining suitable for light and electron microscopy. Structures stained include the nucleolus, ribosomes, inter- and perichromatin granules, the Golgi complex beads and the outer face of the tubule doublets of mouse sperm, certain neurosecretory vesicles believed to contain biogenic amines, some junctions (some central synapses, neuromuscular junctions, tight junctions), specialized membranes such as the post acrosomal dense lamina of mouse sperm and the inner alveolar membrane of Paramecium, and a variety of structures associated with the cytoplasmic face of membranes, such as plasma membrane plaques, cleavage furrows, the leading edge of the spreading acrosome and sperm annuli.Staining is not reduced by nucleases and spot tests show no reaction between nucleic acids and bismuth under conditions similar to those used to stain tissues. However, spot tests do show strong binding of bismuth by basic proteins and by some phosphorylated molecules.It is hypothesized that bismuth reacts with cell components in two ways, distinguishable by their glutaraldehyde sensitivity. For example, staining of the nucleolus and ribosomes is blocked by glutaraldehyde but the inter- and perichromatin granules and the GC beads are unaffected. Spot tests show that basic proteins (histones, protamines, polylysine and polyargenine) and other molecules with free amino groups (5HT, tryptamine, dopamine) bind bismuth strongly, a reaction that is blocked to varying degrees by glutaraldehyde. We presume that most bismuth staining of tissues is due to reaction with amine groups and is glutaraldehyde sensitive and some may be due to guanidine groups which are less sensitive to fixation by glutaraldehyde. Organic phosphates may be the cause of the glutaraldehyde insensitive staining since ATP and some other phosphates bind bismuth in a reaction that is not blocked by glutaraldehyde.     

Observations on the glycosaminoglycans of aging bronchial cartilage studied with Alcian Blue

Synopsis The changes in the distribution of acidic glycosaminoglycans in the extracellular matrix of aging human bronchial cartilage have been studied with Alcian Blue using the critical electrolyte technique described by Scott & Dorling (1965). Keratan sulphate was detected in the interterritorial matrix early in the first decade. The factors initiating the synthesis of keratan sulphate by chondrocytes are discussed and a hypothesis is proposed to explain the subsequent localization of this glycosaminoglycan in the extracellular matrix.     

Alcian Blue staining of glycosaminoglycans in embryonic material: Effect of different fixatives

Summary Glycosaminoglycans are important components of the extracellular matrix of developing embryos where they are found in the form of proteoglycans. Alcian Blue staining of tissue sections is the technique most commonly used for demonstrating their distribution. Glycosaminoglycans have a high solubility in water, and are easily lost from the tissue during processing, even if non-aqueous fixatives have been used. Formalin and Carnoy's fluid are the most frequently used fixatives, and the addition of cetyl pyridinium chloride has been recommended to reduce glycan solubility.Using sections of day-10 rat embryos containing developing head and heart (both known to be rich in glycosaminoglycans) the effects of ten fixatives have been investigated with and without cetyl pyridinium chloride on the preservation of Alcian Blue-stainable material (at pH 2.5) and tissue structure. The most useful fixatives were Karnovsky's and Sainte-Marie's. Both gave a strong and reproducible staining pattern of the extracellular polyanionic material. Sainte-Marie's gave better preservation of tissue structure, allowing the demonstration of cell-matrix inter-relationships; Karnovsky's gave a better contrast between extracellular and intracellular staining, which is particularly useful at lower magnifications.Cetyl pyridinium chloride is a detergent. Transmission electron microscope observations showed that it causes cell membrane disruption and vesicle formation, which at the light microscopic level, would cause cell membrane-associated glycosaminoglycans to appear as stained strands wholly within the extracellular domain. Therefore the use of cetyl pyridinium chloride is inadvisable where a distinction between surface-related and extracellular glycosaminoglycans is desirable. It has the further disadvantage of enhancing cytoplasmic and nuclear polyanionic material, thus decreasing the differential staining intensity of intracellular and extracellular domains.     

The Alcian Blue and combined Alcian Blue-Safranin O staining of glycosaminoglycans studied in a model system and in mast cells

Synopsis Polyacrylamide films containing different glycosaminoglycans have been applied to the study of the Alcian Blue and combined Alcian Blue-Safranin O staining procedures. It was found that the polyacrylamide matrix can be interpreted as some kind of barrier around the substrate molecules, a situation which can be compared to a certain extent with what occursin situ, where complex protein molecules can likewise form a barrier.The Alcian Blue staining of the model films was found to follow the Lambert-Beer law. The time to reach optimal dye binding depended on the concentration of the glycosaminoglycan enclosed in the model films and on the concentration of Alcian Blue in the dye solution. Lowering the pH of the dye solution appeared to increase the rate of staining. Optimal staining of model films in the presence of salt or urea was not possible, because under these conditions the pores of the polyacrylamide matrix became blocked. Alcian Blue was found to bind irreversibly to the glycosaminoglycan molecules enclosed in the polyacrylamide films.The results of the combined Alcian Blue-Safranin O staining applied to model films appeared to be highly dependent on the amount of Alcian Blue bound to the glycosaminoglycan in the first step of the double staining procedure. No specific differences were noticed between the behaviour of the different glycosaminoglycan-Alcian Blue complexes towards the Safranin O binding in the mext step. As the theoretical basis for the application of the combined Alcian Blue-Safranin O staining was also found not to be completely valid, the conclusion was reached that this double staining cannot be used for the histochemical identification of glycosaminoglycans. The colour retained by a certain glycosaminoglycan-containing part of the specimen only delivers information about the accesibility of that part for Alcian Blue.     

An optimized device for staining electron microscopy grids

Proper staining of grids is critical for transmission electron microscopy (TEM). Staining must be done as quickly as possible using minimal reagents and with consideration for the environment. We developed a new device for efficient staining of multiple TEM grids. We studied reagent evaporation, rinsing volume, flow rate and re-use of uranyl acetate, and provide here a procedure for efficient staining using the new device. Our device permits TEM grids to be stained with less reagent than alternative staining apparatuses; staining requires a total volume of 260 μl for five grids. Reagent evaporation is less than 6% even if used at 37° C. Moreover, our staining apparatus reduces chemical waste and shortens experiment time by staining several grids simultaneously. Our staining device is a compromise between time-consuming single grid processing and expensive commercial devices that consume large amounts of reagents.     

The effect of pH on Alcian Blue staining of epithelial acid glycoproteins. II. Human bronchial submucosal gland

Synopsis The effect of pH on Alcian Blue staining of sialomucins and sulphomucins in human bronchial submucosal glands has been analysed. Using Alcian Blue combined with periodic acid-Schiff, lowering the pH was associated with a decrease in the area staining with Alcian Blue and an increase in that staining with periodic acid-Schiff, save in one bronchus with a large sulphomucin content, in which an increase in the area staining with Alcian Blue was found at pH1.0. In all bronchi, an increase in the intensity of Alcian Blue staining was found at this pH. Sialomucin sensitive to sialidase was found to lose Alcian Blue staining at a higher pH than sialomucin resistant to the enzyme. Some sulphomucins stained with Alcian Blue throughout the pH range studied and some only at the more acid pH levels. At pH1.0 Alcian Blue stained only sulphomucins, thus distinguishing them from sialomucins. Alcian Blue staining combined with the high iron diamine technique has enabled three sulphate groups to be identified: one stained with high iron diamine, the other two did not, and, of the latter, one stained with Alcian Blue at pH 2.6 and1.0, and the other only at pH1.0.     

Early developments in the negative staining technique for electron microscopy

It is approximately 34 years since the first high resolution images of T₂ bacteriophages were recorded in the electron microscope using a method which was to be known as ‘negative staining’. Details of the historical background and the original experiments which led up to the negative staining method are described.