Paraffin Sections of Nervous Tissue Supra Vitally Stained with Methylene Blue: A New, Reliable and Simple Fixation Technique

TWO steps are recommended for fixation of central nervous tissue after supravital staining with methylene blue: application of ammonium heptamolybdate followed by a paraformaldehyde-glutaraldehyde mixture. The two fixatives complement each other so that both dye and tissue are optimally fixed. Molybdate renders the dye water and alcohol insoluble, the aldehyde mixture conditions the tissue for embedding in paraffin. This technique is a suitable alternative to conventional whole mount and frozen sectioning methods.     

Electron microscopic demonstration of pulmonary surfactant proteins using procion brilliant blue H5GS

A new electron microscopy technique is described for detection of lung surfactant proteins with the copper-containing phthalocyanine dye, procion brilliant blue H5GS. The protein structures were stained concurrently with the fixation during perfusion through the pulmonary artery of a fixative-staining mixture containing glutaric aldehyde and a dye in the kakodilate buffer, pH 5.6-6, and in the course of a subsequent immersion of lung tissue pieces into the same mixture. Then the material was treated with thiosemicarbazide and post-fixed with OsO4. The dye did not penetrate intact cells. The electron-dense products of the histochemical reaction were located inside and on the surface of the surfactant membrane, in the hypophase of the surfactant complex, on the plasmalemma of air-blood barrier cells and in its micropinocytosis vesicles, as well as on the membranes of osmophilic plate-like bodies as their contents egressed into the alveolar lumen.     

A Microspectrophotometric Analysis of Staining with Carmine, Orcein and Carmine-Orcein

Microspectrophotometric measurements of carmine, orcein and carmine-orcein were made in solutions, in air-dried films and in stained adult and embryonic tissues of the domestic chicken. For individual stains only minor differences were found between dried dye and stained tissue. The absorption curve for carmine in solution showed a single peak at 490 mμ but was bimodal at about 530 and 570 mμ in dry films and stained tissue. Orcein showed a single broad peak at 510 mμ in solution; in dry films and stained tissue a broadening of the absorption curve in the red wavelengths was observed. The dye mixture carmine-orcein in solution showed a single peak at 500 mμ, but in tissue the spectral absorptions closely resembled carmine. With alum-like carmine, spectral changes due to the addition of iron were not detected. The results indicate that nuclear staining with carmine-orcein is due mainly to the carmine component of the mixture. Interpretation of spectral shifts indicates that acew-carmine is a metachromatic stain while aceto-orcein is mainly an ortho-chromatic stain, although some metachromasy is evident.     

Phytoremediation potential of Portulaca grandiflora Hook. (Moss-Rose) in degrading a sulfonated diazo reactive dye Navy Blue HE2R (Reactive Blue 172)

Wild and tissue cultured plants of Portulaca grandiflora Hook. have shown to be able to decolorize a sulfonated diazo dye Navy Blue HE2R (NBHE2R) up to 98% in 40 h. A significant induction in the activities of lignin peroxidase, tyrosinase and DCIP reductase was observed in the roots during dye decolorization. The wild plants and tissue cultures could independently decolorize and degrade NBHE2R into metabolites viz. N-benzylacetamide and 6-diazenyl-4-hydroxynaphthalene-2-sulfonic acid. A dye mixture and a textile effluent were also decolorized efficiently by P. grandiflora. The phytotoxicity study revealed reduction in the toxicity due to metabolites formed after dye degradation.     

An improved polychrome staining method for thick epoxy sections.

Improved polychrome staining of 1-1.5 mum epoxy sections is achieved with sequential applications of a single basic fuchsin-methylene blue mixture at two different pH values. The dye solution is applied for 2-3 min at 50-52 C first at pH 7.9, then at pH 6.7. In sections of mouse mammary tissue, epithelial cells are stained deep blue, connective tissue pink, and fat cells bright olive-green. This simple technique consistently yields uniform, vivid, contrasting colors that sharply delineate the elements of the complex glandular architecture of the mammary gland. Similar polychromatic effects are obtained in applications to other tissues, such as stomach, adrenal gland, mammary tumor and artery.     

COUNTERACTION OF THE INHIBITING EFFECTS OF VARIOUS SUBSTANCES ON NITELLA

When living cells of Nitella are first exposed to (1) phosphate buffer mixture, or (2) phosphoric acid, or (3) hydrochloric acid, or (4) sodium chloride, or (5) sodium borate, and are then placed in a solution of brilliant cresyl blue made up with a borate buffer mixture at pH 7.85, the rate of penetration of the dye into the vacuole is decreased as compared with the rate in the case of cells transferred directly from tap water to the same dye solution. When cells exposed to any one of these solutions are placed in the dye solution made up with phosphate buffer solution at pH 7.85, the rate of penetration of dye into the vacuole is the same as the rate in the case of cells transferred from the tap water to the same dye solution. It is probable that this removal of the inhibiting effect is due primarily to the presence of certain concentration of sodium and potassium ions in the phosphate buffer solution. If a sufficient concentration of sodium ions is added to the dye made up with a borate buffer mixture the inhibiting effect is removed just as it is in the case of the dye made up with the phosphate buffer mixture. The inhibiting effect of some of these substances is found to be removed by the dye containing a sufficient concentration of bivalent cations, or by washing the cells with salts of bivalent cations. The inhibiting effect and its removal are discussed from a theoretical standpoint.     

A Mixture of Methyl Green and Pyronin for Cell Fractionation Studies

A staining mixture consisting of 0.57% methyl green and 0.1 1 % pyronin B (calculated from the actual dye content) dis- solved in glycerol, 20 ml.; 2% aqueous phenol, 100 ml.; and 95% ethanol, 25 ml., was found to be optimum for differentiating cell components containing desoxypentose and pentose nucleic acids. The stain can be used for either fresh suspensions or unfixed dried smears of tissue homogenates. Nuclei are stained bright blue, and nucleoli and cytoplasmic particles, bright pink.     

An Improved Polychrome Staining Method for Thick Epoxy Sections

Improved polychrome staining of 1-1.5 μm epoxy sections is achieved with sequential applications of a single basic fuchsin-methylene blue mixture at two different pH values. The dye solution is applied for 2-3 min at 50-52 C first at pH 7.9, then at pH 6.7. In sections of mouse mammary tissue, epithelial ells are stained deep blue, connective tissue pink, and fat ells bright olive-green. This simple technique consistently yields uniform, vivid, contrasting colors that sharply delineate the elements of the complex glandular architecture of the mammary gland. Similar polychromatic effects are obtained in applications to other tissues, such as stomach, adrenal gland, mammary tumor and artery.     

A Simplified Method for Staining Mast Cells with Astra Blue

The copper phthalocyanin dye astra blue has been used to stain differentially mast cells of the intestine; however, the procedure has not been used widely because of the difficulty in preparing and using the dye solution. Described here is a simple, reliable, and consistent method for selectively staining mast cells using a dye solution that may be prepared in any laboratory without the aid of sophisticated pH metering equipment. Astra blue is mixed with an alcoholic solution containing MgCl₂ · 6H₂O and the pH indicator pararosaniline hydrochloride. Concentrated hydrochloric acid is added dropwise, changing the dye mixture from purple to violet and then to blue. In this low range the weakly ionizing ethanol provides a more stable hydrogen ion concentration than the corresponding aqueous solutions used previously. Alcoholic acid fuchsin is a convenient counterstain, and this simple procedure then provides good contrast between the blue staining mast cell granules and the red tissue background.     

CERTAIN EFFECTS OF SALTS ON THE PENETRATION OF BRILLIANT CRESYL BLUE INTO NITELLA

The effect of various substances on living cells may be advantageously studied by exposing them to such substances and observing their subsequent behavior in solutions of a basic dye, brilliant cresyl blue. The rate of penetration of the basic dye, brilliant cresyl blue, is decreased when cells are exposed to salts with monovalent cations before they are placed in the dye solution (made up with borate buffer mixture). This inhibiting effect is assumed to be due to the effect of the salts on the protoplasm. This effect is not readily reversible when cells are transferred to distilled water, but it is removed by salts with bivalent or trivalent cations. In some cases it disappears in dye made up with phosphate buffer mixture, or with borate buffer mixture at the pH value in which the borax predominates, and in the case of NaCl it disappears in dye containing NaCl. No inhibiting effect is seen when cells are exposed to NaCl solution containing MgCl₂ before they are placed in the dye solution. The rate of penetration of dye is not decreased when cells are previously exposed to salts with bivalent and trivalent cations. The rate is slightly increased when cells are placed in the dye solution containing a salt with monovalent cation and probably with bivalent or trivalent cations. In the case of the bivalent and trivalent salts the increase is so slight that it may be negligible.     

An improved method for staining cells of the endocrine polypeptide (APUD) series by masked metachromasia: application of the principle of ''fixation by excluded volume''.

Synopsis Masked metachromasia is demonstrated by staining with a metachromatic basic dye, after acid hydrolysis of suitably fixed tissue. We report that the addition of 20% Carbowax 20M (an inert polymer, mol. wt. about 20000) to the hydrolysis mixture improved the reaction. The improved method gives increased metachromasia, greater tolerance to variations in hydrolysis conditions, and demonstrates a greater proportion of cells — presumably due to a lower threshold of sensitivity. Lower molecular weight polymers (Carbowax 1000, Carbowax 6000) are less effective.     

Measurement of Cutaneous Microvascular Exudates Using Evans Blue

As an approach to the study of inflammation, strategies were evaluated for quantitative assessment of plasma exudate from thecutaneous microvasculature. Measurements were based on recovery of Evans blue dye (EB) from rat skin. After preliminary studies to evaluate extraction methods, almost complete EB recovery was accomplished by homogenizing tissue in a mixture of acetone, water and sodium sulfate. When sources of potential variation were identified, expression of results as agonist-induced plasma accumulation provided precise results based on EB measurements. Also. the feasibility of parallel biochemical studies was demonstrated.     

Measurement of Cutaneous Microvascular Exudates Using Evans Blue

As an approach to the study of inflammation, strategies were evaluated for quantitative assessment of plasma exudate from thecutaneous microvasculature. Measurements were based on recovery of Evans blue dye (EB) from rat skin. After preliminary studies to evaluate extraction methods, almost complete EB recovery was accomplished by homogenizing tissue in a mixture of acetone, water and sodium sulfate. When sources of potential variation were identified, expression of results as agonist-induced plasma accumulation provided precise results based on EB measurements. Also. the feasibility of parallel biochemical studies was demonstrated.     

Quantitative histochemistry of myelin using Luxol Fast Blue MBS

Synopsis The amount of Luxol Fast Blue MBS in the band of Genarri was measured with two types of scanning microdensitometer and the optical density determined. The amount of stain measured was proportional to the section thickness employed, thus demonstrating that the dye has stoichiometric properties in tissue sections. Blocks of tissue treated with phospholipid solvents showed an increased uptake of stain, suggesting that phospholipids are not a primary substrate for the dye in myelin staining.The dye may, therefore, be used to quantify myelin in tissue sections.     

THE EFFECT OF ACETATE BUFFER MIXTURES,ACETIC ACID,AND SODIUM ACETATE,ON THE PROTOPLASM,AS INFLUENCING THE RATE OF PENETRATION OF CRESYL BLUE INTO THE VACUOLE OF NITELLA

When living cells of Nitella are exposed to a solution of sodium acetate and are then placed in a solution of brilliant cresyl blue made up with a borate buffer mixture at pH 7.85, a decrease in the rate of penetration of dye is found, without any change in the pH value of the sap. It is assumed that this inhibiting effect is caused by the action of sodium on the protoplasm. This effect is not manifest if the dye solution is made up with phosphate buffer mixture at pH 7.85. It is assumed that this is due to the presence of a greater concentration of base cations in the phosphate buffer mixture. In the case of cells previously exposed to solutions of acetic acid the rate of penetration of dye decreases with the lowering of the pH value of the sap. This inhibiting effect is assumed to be due chiefly to the action of acetic acid on the protoplasm, provided the pH value of the external acetic acid is not so low as to involve an inhibiting effect on the protoplasm by hydrogen ions as well. It is assumed that the acetic acid either has a specific effect on the protoplasm or enters as undissociated molecules and by subsequent dissociation lowers the pH value of the protoplasm. With acetate buffer mixture the inhibiting effect is due to the action of sodium and acetic acid on the protoplasm. The inhibiting effect of acetic acid and acetate buffer mixture is manifested whether the dye solution is made up with borate or phosphate buffer mixture at pH 7.85. It is assumed that acetic acid in the vacuole serves as a reservoir so that during the experiment the inhibiting effect still persists.     

Protein dye affinity chromatography using immobilized tetraiodofluorescein

The chromatographic behavior of a heterogeneous protein mixture and of a series of homogeneous proteins on the immobilized dye tetraiodofluorescein has been observed and analyzed. Less than 6%, of the millimolar concentration of dye immobilized to a porous agarose matrix is accessible to protein. The affinity of a protein for immobilized dye is dramatically increased by insertion of apolar spacer atoms between the dye and the matrix. Dye columns constructed with a 9-atom spacer can be used to advantage for the retention and competitive elution of proteins not found previously amenable to dye chromatography.     

Staining of macromolecules: possible mechanisms and examples

This review is based on a presentation given at the Biological Stain Commission meeting in June 2008. I discuss staining as an interaction between dye, solvent, and biological macromolecules. Most staining takes place in water, where the physico-chemical properties of the macromolecules are particularly important. Staining from aqueous solution is summarized. The first step is diffusion–ion exchange, which builds up the dye ion concentration close to the appropriately charged tissue constituents. While charge interactions are important for selectivity and build-up of dye ions around specific tissue and cell constituents, they have in most cases little to do with actual dye binding. The next step, actual binding, is predominantly between aromatic and other non-polar parts of the dye and corresponding groups in the tissue constituent. This results in a reduction of the total hydrophobic area exposed to water, hence the term hydrophobic interaction. Because dye binding is predominantly by dispersive forces, the larger the aromatic dye system and the fewer the number of charges on the dye, the greater the substantivity or affinity. Some relatively straightforward anionic or cationic one-step staining systems are discussed also. These include amyloid staining with Congo red, elastin staining with orceins, collagen staining with picrofuchsin, DNA–RNA staining with methyl green-pyronin Y, acid heteroglycan staining with Alcian blue, and metachromatic staining.     

Development of a low-cost, phyto-tunnel system using Portulaca grandiflora and its application for the treatment of dye-containing wastewaters

A phyto-tunnel was developed using a drilled PVC pipe. It was planted with Portulaca grandiflora and used for the treatment of a textile effluent and a dye mixture. COD, BOD, TOC, conductivity, turbidity, total suspended solids and total dissolved solids of the textile effluent, and dye mixture were decreased by 57, 45, 43, 52, 76, 77 and 24 % within 96 h, and 49, 62, 41, 63, 58, 71 and 33 %, within 60 h, respectively, after treatment. The effluent and dye mixture were decolorized up to 87 and 90 % within 96 and 60 h, respectively. Significant induction in activities of lignin peroxidase, tyrosinase and DCIP reductase was observed in root tissues of the plants. FTIR, HPLC and HPTLC of untreated and treated samples showed the formation of new metabolites and preferential dye removal. Phytotoxicity studies revealed the non-toxic nature of the metabolites.     

STUDIES ON PENETRATION OF DYES WITH GLASS ELECTRODE : V. WHY DOES AZURE B PENETRATE MORE READILY THAN METHYLENE BLUE OR CRYSTAL VIOLET?

Glass electrode measurements of the pH value of the sap of cells of Nitella show that azure B in the form of free base penetrates the vacuoles and raises the pH value of the sap to about the same degree as the free base of the dye added to the sap in vitro, but the dye salt dissolved in the sap does not alter the pH value of the sap. It is concluded that the dye penetrates the vacuoles chiefly in the form of free base and not as salt. The dye from methylene blue solution containing azure B free base as impurity penetrates and accumulates in the vacuole. This dye must be azure B in the form of free base, since it raises the pH value of the sap to about the same extent as the free base of azure B dissolved in the sap in vitro. The dye absorbed by the chloroform from methylene blue solution behaves like the dye penetrating the vacuole. These results confirm those of spectrophotometric analysis previously published. Crystal violet exists only in one form between pH 5 and pH 9.2, and does not alter the pH value of the sap at the concentrations used. It does not penetrate readily unless cells are injured. A theory of "multiple partition coefficients" is described which explains the mechanism of the behavior of living cells to these dyes. When the protoplasm is squeezed into the sap, the pH value of the mixture is higher than that of the pure sap. The behavior of such a mixture to the dye is very much like that of the sap except that with azure B and methylene blue the rise in the pH value of such a mixture is not so pronounced as with sap when the dye penetrates into the vacuoles. Spectrophotometric measurements show that the dye which penetrates from methylene blue solution has a primary absorption maximum at 653 to 655 mµ (i.e., is a mixture of azure B and methylene blue, with preponderance of azure B) whether we take the sap alone or the sap plus protoplasm. These results confirm those previously obtained with spectrophotometric measurements.     

Separation and identification of pteroylpolyglutamates by polyacrylamide gel chromatography.

A simplified procedure for the determination of the glutamate chain lengths of labeled and endogenous tissue folate is described. Pteroylpoly-γ-glutamates in tissue extracts were reductively cleaved at the C,9N,10 bond to p-aminobenzoylpolyglutamates, which were converted to azo dyes by coupling their diazonium salts with naphthylethylene diamine. The azo dyes were well resolved, according to glutamate chain length, by gel chromatography on Bio-Gel P4. Unlabeled tissue folates were detected by the absorbance of their azo dye derivatives. The major endogenous pteroylpolyglutamate in rat liver, identified colorimetrically using 0,5 g tissue, was the pentaglutamate. The major labeled folates in Lactobacillus casei and Streptococcus faecalis, after incubating these bacteria with labeled folic acid, were identified as the octa- and tetraglutamates, respectively. Reductive cleavage of 10-formylfolate and 5.10-methenyltetrahydrofolate resulted in a mixture of N-substituted and unsubstituted p-amino-benzoylpolyglutamates. Methods are described for the complete cleavage of these formyl derivatives to unsubstituted p-aminobenzoylpolyglutamates.