Zinc Chloride Methylene Blue. I. Biological Stain History, Physical Characteristics and Approximation of Azure B Content of Commercial Samples

Zinc chloride methylene blue appeared on the market almost contemporaneously with the zinc-free medicinal form. The former has rarely been reported as being used in blood stains. Recent suspension of manufacture of medicinal methylene blue by it. principal American producer has excited interest in the use of the zinc chloride form for the preparation of blood stains. According to Lillie (1944a,b) the azure B content of zinc chloride methylene blue may have varied from 5 to 30% in the samples studied. Taking the Merck Index (1968, 1976) figures for the spectroscopic absorption maximum (λmax) of 667.8 and 668 nm as standard, recent samples of zinc chloride methylene blue are calculated to contain 6-8% azure B. These figures are baaed on 1) the shift of λmax after exhaustive pH 9.5 chloroform extraction, 2) evaluation of the actual ratio of the observed TiCl₂ dye content to the theoretical for pure zinc chloride methylene blue, 3) comparison of spectroscopic and staining effects of graded hot dichromate oxidation products with those of highly purified azure B-methylene blue mixtures of known proportions.

As far as can be found, medicinal methylene blue is almost the exclusive source of cosin polychrome methylene blue blood stains. Lillie (1944c) included a short series comparing 5 zinc chloride methylene blues with a dozen medicinal methylene blue samples; all were oxidized with hot dichromate to produce successful Wright stains. No effort was made to remove the zinc Exhaustive pH 9.5 chloroform extraction of zinc chloride methylene blue (lot MCB 12-H-29) yielded a small amount of red dye which when extracted into 0.1 N HCI gave λmax = 650. The extraction moved the absorption peak of the zinc chloride methylene blue from 667 to 668 nm and the midpoint of the 90% maximum absorption band, 18 nm wide, from 666.5 to 667.5 nm.     

Spectrophotometric Characteristics and Assay of Biological Stains IV. the Phenyl Methane Dyes

This paper continues the investigation of the assay and spectral properties of biological stains. The phenyl methane dyes, auramine O, basic and acid fuchsins, methyl violet, crystal violet, methyl green, and anilin blue W. S., may all be assayed by the spectrophotometric method. Of these, methyl green has been found unstable both in solid form and in solution, hence color densities of this dye must be measured promptly after preparation.     

The Analysis of Neutral Red and of the Pyronins

Neutral red and the pyronins cannot be evaluated by means of reduction with titanous chloride, and market supplies of the stains contain nitrogenous dye intermediates which render other chemical methods of determining dye content unreliable.

Data are furnished in the present paper which will enable the analyst to obtain reliable dye-content values with samples of these dyes by means of a convenient spectrophotometric technic.     

Selected dyes for residence time distribution evaluation in bioreactors

Summary A selection of dyes for tracer studies in bioreactors, specially for wastewater treatment, is presented. Substances that showed no adsorption on air or biomass, stability in time, good solubility and no color change between pH 6.5 to 8.5, were: bromocresol green, bromophenol blue, dextran blue, eosin Y and mordant violet. Consequently they seem to be adequate for common biochemical engineering processes. In addition, dyes that showed some limitations, but may be employed in special cases, were: bromophenol red and phenol red (color change between pH 5.0 to 6.8 and 6.8 to 8.4 respectively) and methylene violet Bernsthen (low spectrophotometric response).     

Zinc Chloride Methylene Blue, Ii. Preparation of Giesma and Wright Type Low Azure B Blood Stains from Dichromate Oxidized Commercial Dye

TO determine the amount of K₂Cr₂O₇ required to produce optimal Giemsa type staining, six 1 g amounts (corrected for dye content) of zinc methylene blue were oxidized with graded quantities of K₂Cr₂O₇ to produce 4, 8, 12, 16, 20 and 24% conversion of methylene blue to azure B. These were heated with a blank control 15 minutes at 100 C in 60-65 ml 0.4 N HCI. cooled, and adjusted to 50 ml to give 20 mg original dye/ml. Aliquots were then diluted to 1% and stains were made by the “Wet Giemsa” technic (Lillie and Donaldson 1979) using 6 ml 1% polychrome methylene blue, 4 ml 1% cosin (corrected for dye content), 2 ml 0.1 M pH 6.3 phosphate buffer, 5 ml acetone, and 23 ml distilled water. The main is added last and methanol fixed blood films are stained immediately for 20-40 min.

For methylene blue supplied by MCB 12-H-29, optimal stains were obtained with preparations containing 20 and 24% conversion of methylene blue to azure B. With methylene blue supplied by Aldrich (080787), 16% conversion of methylene blue to azure B was optimal. Eosinates prepared from a low azure B/methylene blue preparation selected in this way give good stains when used as a Wright stain in 0.3% methanol solution. However, when the 600 mg eosinate solution in glycerol methanol is supplemented with 160 mg of the same azure B/methylene blue chloride the mixture fails to perform well. The HCI precipitation of the chloride apparently produces the zinc methylene blue chloride salt which is poorly soluble in alcohol. It appears necessary to have a zinc-free azure B/methylene blue chloride to supplement the probably zinc-free eosinate used in the Giemsa mixture.     

The Germicidal Effect of Staining Solutions

Gentian violet, crystal violet and carbol fuchsin applied to cover slip preparations for one minute will destroy the majority of non-spore-forming bacteria and yeasts, tho they can not be relied upon to do this consistently and in all cases.

The Gram staining procedure is more effective and non-spore-formers were never found to survive this process.

Methylene blue stains exert very little if any germicidal power and most organisms survived them readily. India ink was totally ineffective.

Several species of yeasts and yeast-like molds were killed in every instance by the Gram stain, gentian violet, crystal violet and carbol fuchsin, but survived both Loeffler's methylene blue and a plain aqueous solution of methylene blue.     

The Germicidal Effect of Staining Solutions

Gentian violet, crystal violet and carbol fuchsin applied to cover slip preparations for one minute will destroy the majority of non-spore-forming bacteria and yeasts, tho they can not be relied upon to do this consistently and in all cases.

The Gram staining procedure is more effective and non-spore-formers were never found to survive this process.

Methylene blue stains exert very little if any germicidal power and most organisms survived them readily. India ink was totally ineffective.

Several species of yeasts and yeast-like molds were killed in every instance by the Gram stain, gentian violet, crystal violet and carbol fuchsin, but survived both Loeffler's methylene blue and a plain aqueous solution of methylene blue.     

A Technique for Distinguishing Between Methylene Violet and Methylene Violet Bernthsen

Thin layer chromatography by a previously described method for Romanowsky stains permits the ready separation of methylene violet and methylene violet Bernthsen, which have been confused because of the similarity in their names.     

Zirconyl Hematoxylin: a New Stain for Acidic Mucins

Most stains for acidic mucins are time-consuming to prepare and have poor stability. Zirconyl hematoxylin is easily prepared and works for a year or more. It is made by adding 5 ml freshly-made 0.1% aqueous sodium iodate, 400 mg zirconyl chloride oc-tahydrate, and 40 ml 25% aqueous glycerol, in that order, to 100 mg of hematoxylin in 5 ml of absolute ethanol and stirring for 5 min. Stain 10 min and do not “blue” the stain. Chlorazole black or kernechtrot and fast green are good counterstains. Zirconyl hematoxylin stains acidic mucins violet or red violet, regardless of how they are fixed. It stains the same mucins as alcian blue in mouse and sheep salivary glands. It shows goblet cells in mouse rectum as well as alcian blue. It stains the same stomach regions in a lizard as alcian blue. Like alcian blue and colloidal iron, zirconyl hematoxylin stains the mucin of cancerous prostate, but not normal prostate.     

Evaluation of different staining procedures for the quantification of fibroblasts cultured in 96-well plates.

Comparison of published methods for the quantification of adherent cell numbers by the measurement of absorbance of bound stain indicates a wide variation in their sensitivity. This study aimed at comparing the sensitivities of five different staining procedures (Coomassie brilliant blue G in perchloric acid, Coomassie brilliant blue G in phosphoric acid, methylene blue, crystal violet, and toluidine blue) applied to three separate types of cultured fibroblasts (3T3 cells, Vero cells, and human gingival fibroblasts) at concentrations from 0.125 x 10(4) to 10 x 10(4) per well in 96-well microplates. Absorbance values of Coomassie blue-stained cells were measured in situ. Those of the remaining cells were measured after solubilization of the dye with 1% sodium dodecyl sulfate. All absorbance values were measured using an Elisa reader at 620 or 570 nm for crystal violet. The relationship between cell number and absorbance over the entire cell concentration range was best fitted with quadratic regression analysis, in contrast with the linear relationship described elsewhere. The order of sensitivity of the staining procedures was the same for each cell type: Coomassie blue in perchloric acid less than Coomassie blue in phosphoric acid less than methylene blue less than crystal violet less than toluidine blue. With the latter two stains absorbance values began to plateau at approximately 8 x 10(4) cells per well. However, staining with Coomassie blue in perchloric acid and methylene blue resulted in an almost linear relationship between cell number and absorbance over the entire concentration range tested.(ABSTRACT TRUNCATED AT 250 WORDS)     

Zirconyl Hematoxylin: a New Stain for Acidic Mucins

Most stains for acidic mucins are time-consuming to prepare and have poor stability. Zirconyl hematoxylin is easily prepared and works for a year or more. It is made by adding 5 ml freshly-made 0.1% aqueous sodium iodate, 400 mg zirconyl chloride oc-tahydrate, and 40 ml 25% aqueous glycerol, in that order, to 100 mg of hematoxylin in 5 ml of absolute ethanol and stirring for 5 min. Stain 10 min and do not “blue” the stain. Chlorazole black or kernechtrot and fast green are good counterstains. Zirconyl hematoxylin stains acidic mucins violet or red violet, regardless of how they are fixed. It stains the same mucins as alcian blue in mouse and sheep salivary glands. It shows goblet cells in mouse rectum as well as alcian blue. It stains the same stomach regions in a lizard as alcian blue. Like alcian blue and colloidal iron, zirconyl hematoxylin stains the mucin of cancerous prostate, but not normal prostate.     

Stains for the Primary Wall of the Cotton Fiber

Several methods are described for distinguishing between the primary wall of the cotton fiber and other fiber components, such as the lumen and the secondary wall. The primary wall, a membrane less than 0.5 μ thick covering the entire fiber, has been stained while still attached to the fiber as well as after it has been mechanically stripped from the fiber. The stains include aqueous or alcoholic solutions of ruthenium red, methylene blue chloride, Nile blue sulfate, oil red, Sudan black B, iodine, and Simons' stain. Various concentrations of sodium hydroxide, cupri-ethylenediamine hydroxide, or sulfuric acid have been used to enhance color changes and to cause cellulosic swelling. Fibers that have been stained with Simons' stain and then swelled with dilute cupri-ethylenediamine hydroxide have shown the greatest color differences between the primary wall and the lumen.     

History of Staining the Staining of Blood and Parasitic Protozoa

By the term “blood stain” one ordinarily means a compound dye formed from the chemical union of an acid and a basic dye, and usually a compound of the eosin-methylene-blue group. It is well known today that the sodium salt of a color acid (e. g. eosin) and the chloride of a dye base (e. g. methylene blue) may be converted by simple metathesis into sodium chloride plus the compound dye (e. g. methylene blue eosinate), the latter being insoluble in water unless an excess is present of either the acid or the basic dye. In modern blood stains a compound dye of this type is dissolved in methyl alcohol and mixed with water on the slide at the moment of staining.     

Stain Solubilities Part 1. Data in the Literature

The rather meager data found in the literature concerning the solubilities of the dyes used as biological stains is reviewed. Solubility data have been found concerning the following dyes: picric acid, martius yellow, crystal ponceau, methyl orange, tropaeolin O, orange II, Bismarck brown, Congo red, auramine, malachite green, fuchsin, methyl violet, gentian violet, crystal violet, methyl green, diphenylamine blue, aurin, corallin, phenolphthalein, flluorescein, eosin Y, iodo-eosin, methylene blue, alizarin, indigo carmine, and carmine. Much of this information is of questionable reliability. The writer is investigating the matter and his original data are to appear in subsequent papers.     

Stain Solubilities Part 1. Data in the Literature

The rather meager data found in the literature concerning the solubilities of the dyes used as biological stains is reviewed. Solubility data have been found concerning the following dyes: picric acid, martius yellow, crystal ponceau, methyl orange, tropaeolin O, orange II, Bismarck brown, Congo red, auramine, malachite green, fuchsin, methyl violet, gentian violet, crystal violet, methyl green, diphenylamine blue, aurin, corallin, phenolphthalein, flluorescein, eosin Y, iodo-eosin, methylene blue, alizarin, indigo carmine, and carmine. Much of this information is of questionable reliability. The writer is investigating the matter and his original data are to appear in subsequent papers.     

Subsidiary Dyes in Methylene Blue

Suitable tests have been devised for the detection of azure B (trimethyl thonin) and methylene violet in methylene blue. All samples of methylene blue examined have been found to contain appreciable proportions of azure B.     

Subsidiary Dyes in Methylene Blue

Suitable tests have been devised for the detection of azure B (trimethyl thonin) and methylene violet in methylene blue. All samples of methylene blue examined have been found to contain appreciable proportions of azure B.     

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.     

Acid-labile sulfide and zero-valence sulfur in plant extracts containing chlorophyll and ionic detergents

Two methods for analysis of acid-labile sulfide and zero-valence sulfur in plant extracts containing chlorophyll as well as ionic and/or nonionic detergents are presented. Both methods are based on the conversion of sulfide into methylene blue. In the first method an ethyl acetate extraction step is used to remove chlorophyll and its degradation products which otherwise prevent spectrophotometric quantitation of methylene blue. The second assay method employs 35S-labeled plant extracts. This method, which involves thin-layer chromatography and autoradiography, is potentially more sensitive than the spectrophotometric assay in detecting acid-labile sulfide and zero-valence sulfur.     

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.