Studies on Polychrome Methylene Blue I. Eosinates, their Spectra and Staining Capacity

The absorption spectra of eosinates of thiazin dyes in water exhibit absorption maxima at the same spectral locations as do the individual component dyes in aqueous solution.

Commercial samples of Wright's stain showing thiazin absorption maxima between 620 and 660 mμ generally give satisfactory blood stains. Nuclear staining is redder and cytoplasm grayer blue in 620-640 range, and consequently staining of malaria parasites is less satisfactory in that range. The best malaria stains show their thiazin absorption maxima usually between 650 and 660 mμ.

Successive batches of Wright's stain made by the same manufacturer, as well as experimental laboratory lots, may show wide variations in their thiazin absorption maxima and in their staining characteristics.     

Additional Schiff-Type Reagents for Use in Cytochemistry

Twenty-four new Schiff-type reagents were discovered in a survey of 140 different dyes. These dyes include acid fuchsin, acridine yellow, acriflavine hydrochloride, azure C., Bismarck brown R, Bismarck brown Y, celestine blue B, chrysoidine 3R, chrysoidine Y extra, cresyl violet, crystal violet, gentian violet, methylene blue, neutral violet, phenosafranin, phosphine GN, proflavine, toluidine blue O, and toluylene blue. Positive results obtained with crystal violet and a few samples of methylene blue are considered due to impurities. Various chemical extractions, aldehyde blocking reagents, and enzymatic treatments were used to verify the aldehyde specificity of the above dye-SO₂, reagents as well as azure A, brilliant cresyl blue, neutral red, safranin O, and thionin which have been mentioned by other workers. These reagents were tested in the Feulgen reaction for DNA and the PAS reaction for polysaccharides. Absorption curves were obtained from individual nuclei stained for DNA. The absorption peaks ranged from 450 mμ, to 630 mμ. depending on the dye studied. The Feulgen reaction could be followed by the PAS reaction or vice versa in mouse intestine using reactive dyes of complementary colors. The evidence indicates that a potential Schiff-type reagent must have at least one free NH₂ group on the dye molecule.     

An Evaluation of the Metachromasy of Anionic Dyes. II. Visual and Spectral Observations on Solutions

The reactions of 13 anionic dyes in solution with a basic protein (protamine), a cationic detergent, guanidine, histamine, procaine, quinine, and strychnine were examined visually and spectrophotometrically in order to distinguish metachromatic changes of the dyes. Disazo dyes (Congo red, benzopurpurin, but not trypan blue) were metachromatic; indigoid, triphenylmethane and xanthene dyes were not. The magnitude of metachromasy in this series of dyes was not great compared with cationic dyes, the shifts of absorbance maxima being only about 15 mμ against 90 mμ or more for some cationic metachromatic dyes. The most effective chromotropes were protamine and a cationic detergent. Agreement between visual observations on tissue sections, visual observations on solutions, and spectral observations on solutions was generally good.     

The Spectrophotometric Evaluation of Mixtures of Methylene Blue and Trimethyl Thionin

Spectrophotometric analysis affords the most convenient means for determining the proportion of methylene blue and trimethyl thionin (azure B) present in a mixture of these two dyes. The method proposed depends upon the determination of an “absorption ratio.” A suitable ratio for the purpose is that of the extinction coefficient at 640 mμ to that at 670 mμ. On account of the difference in absorption maxima of the two dyes, this ratio increases as the percentage of methylene blue decreases. The ratio value for eleven different mixtures is given and a graph is plotted from this data by means of which the proportions of the two dyes present in any mixture can be calculated from the absorption ratio determined as specified.     

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.     

Chromatography And Biological Stains V. Isolation And Spectral Analysis Of The Orange Fat-Staining Component Of Sudan Iii

A sample of the orange fat-staining compound present in commercial Sudan III was isolated and purified by chromatographic methods. This material showed the presence of no other contaminating colored compounds when analyzed by paper chromatographic methods. Spectrographic analysis in the visible and ultra-violet ranges shows a strong absorption maximum at 481 mμ, a shoulder at approximately 425 mμ, and a weak absorption maximum at 315 mμ.     

Spectrophotometry of Dyes: 1. Methyl Green. 2. Pyronin

Comparisons of absorption peaks of seven samples of methyl green showed that two different types of the dye were represented. One type (2 samples) had the visible peak near 617 mμ; the other (4 samples) near 630 mμ, while one sample was intermediate in spectral characteristics. Using these findings as a means of differentiating between heptamethyl and hexamethylethyl pararosanil-in is suggested. The Y and B forms of pyronin were found to be readily distinguishable by comparing their absorption maxima (Y, 546 mμ, B, 557-8 mμ). A check on the application of Beer's law of dilution showed that it held (1-3 mg./liter) for pyronin and that the relative effect of dilution was a slow increase with pyronin but a rapid decrease with methyl green.     

Thiazin Dyes in Supravital Staining of nerve Fibers

Supravital staining by thiazins of segments of small intestine and mesentery of young dogs was studied with reference to specificity for nervous tissue. Attempts to secure a purer form of methylene blue by alumina adsorption and alcohol elution of the commercial, medicinal dye yielded a product which appeared to be structurally different from the original dye. The treated dye had absorption maxima from 620 to 655 mμ in contrast with 665 for the untreated. Small nerve bundles were stained by the treated dye after 2 to 4 hours of immersion, but staining was always incomplete. Staining by untreated methylene blue was compared with that by the leucobase, thionol, methylene green, toluidine blue, new methylene blue and the azures. It was concluded that the specificity for nerve fibers resides mainly in the =N(CH₃)₂Cl radical, although some specificity appears to be effected by the methyl groups on the trivalent nitrogen, since azure A (dimethyl) and azure C (mono-methyl) stained weakly, but thionin did not. Methylene green showed some specificity but stained weakly. The leucobase was less active than the reoxidized dye obtained from it.     

Methylene Violet (Bernthsen), by Zinc-Alkali-Chlorate Hydrolysis of Methylene Blue

Though Bernthsen's methylene violet (MV) is a common constituent of polychrome methylene blue, the hydrolytic oxydation of methylene blue to yield azure-free MV has been considered a difficult chemical reaction since the time of Bernthsen, who used Ag₂O in the hydrolysis. MV is qualitatively distinguished from azures by Bernthsen's criteria and the author's new tests: (1) light-excited isomeric change, (2) reactivity to acidity, (3) reaction with KCIO, and (4) reaction with Na₂SO₃ of azures in CHCI₃, while MV gives none. But MV shows (5) indicator properties at pH 4, while azures do not. For practical hydrolysis, treat methylene blue (10 parts by weight) and KCIO₃ (1 part) with 1-2 N NaOH to convert methylene blue to a mixture of MV and azures. Then dilute the solution, add a Zn salt and NaHCO₃ in excess of the amount needed to convert the NaOH to Na₂CO₃. Boil the solution gently for 1-2 hr. The end point of the reaction is found by pipetting a drop of reactant into 3% acetic acid in a test tube, adding CHC1₃ and extracting. The acetic layer should then be almost colorless while the CHC1₃ is colored intensely cherry red. After cooling, the precipitated dye is filtered and dried. This procedure gives good yields of a dye which meets the criteria given by Bernhsen. The peak of the absorption curve in solution, pH 4-11, is at 624 mμ (Bernthsen 625 mμ) and in acid solution, pH 0-4, 588 mμ (Biological Stains, 1953; 580 μ). The dye contains so little azures, that purification of the MV fraction obtained from the reaction mixture is unnecessary when it is used in the Wright-type Romanowsky stain. The remarkable staining effect of MV is its power to bring out red azurophil granules of monocytes and lymphocytes when used with eosinated thiazins in Wright's stain.     

Staining Reactions of some Anionic Disazo Dyes and Histochemical Properties of the Red Impurity in Trypan Blue

Some staining properties of 10 anionic disazo dyes are clarified by comparison with previous chromatographic analysis. Trypan blue contains both blue and red components and the purified blue fraction displays no color shifts in tissue sections. Evans blue, Niagara blue 2B, Niagara sky blue, Niagara sky blue 4B and Niagara sky blue 6B generally resemble trypan blue. Congo red is a metachromatic dye and the only known example among anionic dyes of established purity whose color shows shifts in tissue sections and also in solutions with certain basic compounds. Other red dyes (Congo corinth, trypan red and vital red) are not metachromatic. The red dye impurity of trypan blue selectively stains nuclei which are pycnotic, degenerating or undergoing no further division. This reaction is apparently related to basic protein content. Other reactions of the red fraction of trypan blue (mammalian erythrocytes, blood plasma) are not fully explained on this basis.     

An Update on Protein Stains: Amido Black, Coomassie Blue G, and Coomassie Blue R

Samples of amido black, Coomassie blue G, and Coomassie blue R obtained over a number of years were tested for dye content, impurities, and effectiveness for staining proteins after polyacrylamide gel electrophoresis and for protein dye-binding assays. Some impurities produced reactions resembling metachromasia with specific proteins, although instances of true metachromatic staining are also reported. Several simple assays are given for determining dye content and relative levels of impurities. Recommendations are made for selecting batches of commercial dyes which are most likely to perform satisfactorily.     

An Update on Protein Stains: Amido Black,Coomassie Blue G,and Coomassie Blue R

Samples of amido black, Coomassie blue G, and Coomassie blue R obtained over a number of years were tested for dye content, impurities, and effectiveness for staining proteins after polyacrylamide gel electrophoresis and for protein dye-binding assays. Some impurities produced reactions resembling metachromasia with specific proteins, although instances of true metachromatic staining are also reported. Several simple assays are given for determining dye content and relative levels of impurities. Recommendations are made for selecting batches of commercial dyes which are most likely to perform satisfactorily.     

Histochemistry of Alcian blue

Summary Alcian blue and related copper phthalocyanin dyes carrying cationic charges on substituent aliphatic groups are metachromatic. The unperturbed orthochromatic molecules are easily observed in non-protic solvents of moderately high dielectric constant e. g. dimethyl sulphoxide. Metachromasia is the result of mutual interactions between chromophores. The Alcian blues are aggregated and metachromatic in water at molar concentrations one hundredth those at which toluidine blue is mainly orthochromatic. The relevance of Alcian blue aggregation to the speed of staining, its use in critical electrolyte concentration techniques, and in microspectrophotometry, is considered.     

Metal contaminants in commercial thiazine dyes.

The iron, potassium, sodium and zinc content of commercial samples of the thiazine dyes azure A (C.I. 52005), azure B (C.I. 52010), azure C (C.I. 52002), methylene blue (C.I. 52015), new methylene blue (C.I. 52030), polychrome methylene blue, thionine (C.I. 52000) and toluidine blue (C.I. 52040) have been determined by atomic absorption spectrophotometry. The metal concentration varied widely in the 38 samples examined--iron, potassium, sodium and zinc together comprised between 0.02% and 25.35% of individual samples.     

Effect of temperature on the induced cotton effects of acid polysaccharide-basic dye complexes

The induced Cotton effect of some acid polysaccharide–thiazine dye complexes were studied at various temperatures. When the equivalent ratio of the anionic site of the polymer to the cationic dye was near unity, all the complexes examined showed remarkable Cotton effects corresponding to their absorption bands in the visible and ultraviolet regions, at neutral pH and room temperature. Although the structure of the hyaluronate complex resembles the carbohydrate backbone, the sign of the Cotton effects was opposite that of chondroitin sulfate complexes. When the temperature was raised, the hyaluronate–toluidine blue complex decreased the metachromatic shift in the absorption spectrum gradually; the amplitude of the Cotton effects of this complex decreased also. With a polysaccharide which has a carboxylate group as its only anionic site (such as carboxymethylcellulose or pectic acid), a similar effect of temperature was observed on its induced Cotton effects. With the chondroitin 4-sulfate–toluidine blue complex, some reverse of the metachromatic shift was observed at higher temperature. However, the amplitude of its Cotton effects decreased up to 70 °C, then the sign of the effects reversed and the amplitude subsequently increased. A similar inversion of the sign of the Cotton effects was found with the chondroitin 6-sulfate–toluidine blue complex, but at a lower temperature (about 40 °C). Charonin sulfate, a highly sulfated cellulose-like glucan from a marine mollusca, showed a marked metachromatic effect on methylene blue even at the elevated temperature. The induced Cotton effects of this complex were also affected by temperature and the inversion of the sign was observed. When the pH was lowered, the amplitude of the Cotton effects of the hyaluronate-toluidine blue complex decreased and diminished at pH 3, at room temperature. With chondroitin 4-sulfate, the induced Cotton effects were remarkable at such a low pH; however, the amplitude of the effects decreased with elevated temperature and no inversion was observed. The optical rotatory dispersion of the chondroitin 6-sulfate–toluidine blue complex was reversed by acidifying to pH 3, and the amplitude of the Cotton effects decreased by elevating the temperature.     

Properties and function of the respiratory chain of freshwater mussel spermatozoa in relation to motility

1. The spermatozoa of the freshwater mussel (Hyriopsis schlegelii) contain cytochromes aa₃, b and c, flavoproteins and nicotinamide nucleotides in molar ratios of 1.0:0.9:1.8:1.8:8.7. Cytochrome c₁ is not detectable even at liquid-N₂ temperature, but a c₁-like cytochrome with an -band at 550 mμ is found at liquid-N₂ temperature in a cell preparation from which cytochrome c is completely removed.

2. The near-ultraviolet difference spectrum of whole cells reveals an absorption peak at 315 mμ with a shoulder around 350 mμ.

3. Both the endogenous respiration and motility of spermatozoa are completely blocked by 0.2 mM CN⁻ and by 0.2 μM antimycin A. 2,4-Dinitrophenol and pentachlorophenol completely inhibit motility at the maximal stimulation of respiration. Rotenone strongly inhibits NADH oxidase of spermatozoa, although it has no effect on the respiration of whole cells.

4. It is concluded that the motility of mussel spermatozoa is tightly coupled to respiration, and the respiratory chain phosphorylating process is the only energy-supplying system for motility.     

X-ray microanalysis of toluidine blue stained chromosomes: a quantitative study of the metachromatic reaction of chromatin

The stoichiometry of metachromatic staining of chromatin by toluidine blue was investigated in isolated metaphase chromosomes from L929 cells using X-ray microanalysis. Microspectrophotometric measurements revealed that a hypsochromic shift (from 595 to 570 nm) occurs in toluidine blue stained chromosomes in relation to the staining solution. Under the electron microscope, stained chromosomes. After toluidine blue staining, X-ray microanalysis of chromosomes revealed a large increase for sulphur counts and a considerable increase for Fe and Cu counts, while the signal of Mg, Ca, Cl, K and Zn was reduced. After subtraction of the intrinsic sulphur signal, S/P ratios of 0.82--for euchromatic arms--and 0.85--for centromeric heterochromatin--were obtained. They are considered representative of dye/DNA phosphate ratios. These results indicate the occurrence of a nearly stoichiometric binding of toluidine blue to chromatin DNA and suggest that an external dye stacking is responsible for the metachromatic staining of metaphase chromosomes.     

Effects of differently hydrophobic solvents on the aggregation of cationic dyes as measured by quenching of fluorescence and/or metachromasia of the dyes

Aggregation of some cationic dyes leads to the appearance of their metachromatic spectra and/or quenching of their fluorescence. Ethanol and urea destroy metachromasia and enhance the fluorescence of such dyes by disaggregating them, suggesting hydrophobic bonds to be involved in their aggregation as in the formation of soap micelles or globular proteins. The ability of alcohols to disaggregate cationic dyes has been shown to be increased in the series methanol, ethanol, iospropanol and tertiary-butanol which is the order of increasing hydrophobic character of the alcohols themselves. Dimethyl urea is shown to be more effective than urea in destroying the metachromasia of toluidine blue, thus supporting the idea of hydrophobic bond to be involved in dye aggregation. Rhodamine 6 G undergoes quenching of its fluorescence in presence of a suitable polyanion but it is not metachromatic like acridine orange. Since only some specific cationic dyes undergo spectral changes with aggregation such changes seem to be the secondary effects of aggregation.Pool Officer, Scientists' Pool, Council of Scientific & Industrial Research (India), attached to the Bose Institute.     

The Toluidine Blue-Membrane Filter Method: Absorption Spectra of Toluidine Blue Stained Bacterial Cells and the Relationship Between Absorbance and Dry Mass of Bacteria

Propan-2-ol did not leach dye from toluidine blue stained bacteria on membrane filters but ethanol did. The absorption spectra of toluidine blue stained cells of two Gram-positive and two Gram-negative organisms differed with the latter organisms exhibiting metachromasia. The results suggest that toluidine blue stains the cell envelope. Linear regression equations were derived for each of four organisms, Streptococcus cremoris, Lactobacillus bulgaricus, Pseudomonas fluorescens and Escherichia coli, relating absorbance at the peak of the absorption spectra and the mass of cells on the filters. With these equations it should be possible to determine mass of cells with an error between 3% and 7.5% depending on the organism. Since the regression equations are similar, the amount of toluidine blue retained per milligram of cells may be constant under standard conditions, irrespective of species.     

Subependymal glycosaminoglycan networks in adult and developing rat brain

Histochemical studies of normal adult rat brain indicate two types of glycosaminoglycans in the subependymal region of the lateral ventricle. One network is characterized by an affinity for the cationic dyes alcian blue, aldehyde fuchsin and colloidal iron. These reactions occur at pH 1.0 and at 0.5-0.3 M concentration of MgCl2, which suggests that this material is chondroitin sulfate. The other system is identified by metachromasia with toluidine blue and a loss of PAS staining following sulfation. These findings are consistent with non-sulfated and non-anionic acid mucopolysaccharides. In developing rat brain the differential development of these networks enhances their separate identity. The metachromatic network is present at least by the 10th postnatal day but the polyanionic electrolytes cannot be identified until the 16th to the 22nd days. The possible functional importance of these systems is discussed.