Reduced Methylene Blue as a Stain for Crustacean Nerves

Effective in situ staining of crustacean nerves was achieved with leuco methylene blue reduced with either ascorbic acid or sodium hydrosulfite (Na₂S₂O₄). A stock solution of methylene blue, 0.4% (ca. 0.001 M), and the reductants, ascorbic acid or sodium hydrosulfite (0.01 M), were prepared in van Harreveld's crayfish physiological solution. Methylene blue stock solution was mixed with either of the reductants in the approximate ratio of 1:10, v/v, and titrated to the end point. Ascorbic acid reduction is light catalyzed and requires intense illumination during titration. The cleared or leucomethylene blue stock solution is suitable for immediate use as a working nerve stain. With either reductant, the working solution oxidizes on standing in air, but can be titrated repeatedly without loss of staining properties. Dissected nerve trunks or tissue were immersed in the working stain for 20 min at room temperature and the staining process observed until suitable contrast developed. Excess dye was decanted and the tissues flooded with crayfish physiological solution. Contrast could sometimes be enhanced by flooding the stained area with 1% hydrogen peroxide in van Harreveld's solution. When permanent mounts were prepared, tissues were dehydrated with tertiary butyl alcohol in preference to ethyl alcohol series. For anatomical and neurophysiological studies of nerve distribution in crustaceans, the alternative use of either ascorbic acid or sodium hydrosulfite, as reductants for methylene blue, was preferable to the more complicated rongalit-technique and characterization of neural elements was fully as satisfactory.     

Reduced Methylene Blue as a Stain for Crustacean Nerves

Effective in situ staining of crustacean nerves was achieved with leuco methylene blue reduced with either ascorbic acid or sodium hydrosulfite (Na₂S₂O₄). A stock solution of methylene blue, 0.4% (ca. 0.001 M), and the reductants, ascorbic acid or sodium hydrosulfite (0.01 M), were prepared in van Harreveld's crayfish physiological solution. Methylene blue stock solution was mixed with either of the reductants in the approximate ratio of 1:10, v/v, and titrated to the end point. Ascorbic acid reduction is light catalyzed and requires intense illumination during titration. The cleared or leucomethylene blue stock solution is suitable for immediate use as a working nerve stain. With either reductant, the working solution oxidizes on standing in air, but can be titrated repeatedly without loss of staining properties. Dissected nerve trunks or tissue were immersed in the working stain for 20 min at room temperature and the staining process observed until suitable contrast developed. Excess dye was decanted and the tissues flooded with crayfish physiological solution. Contrast could sometimes be enhanced by flooding the stained area with 1% hydrogen peroxide in van Harreveld's solution. When permanent mounts were prepared, tissues were dehydrated with tertiary butyl alcohol in preference to ethyl alcohol series. For anatomical and neurophysiological studies of nerve distribution in crustaceans, the alternative use of either ascorbic acid or sodium hydrosulfite, as reductants for methylene blue, was preferable to the more complicated rongalit-technique and characterization of neural elements was fully as satisfactory.     

A Nissl Method Using Buffered Solutions of Thionin

Experiments were performed in an attempt to obtain a rapid method for staining the chromophilic substance of formalin-fixed nerve cells differentially without resorting to over-staining and subsequent acid-decolorizing. A satisfactory procedure using thionin in dilute buffered solutions was developed: Prepare a stock solution of the dye using 1 g. in 100 ml. of distilled water. Prepare veronal-acetate buffers (Michaelis, 1931) in the range of pH 5 to pH 3.S. To each 10 ml. of the buffer add 0.5 ml. of the stock dye solution. After rinsing in CO₂-free distilled water place mounted or unmounted sections in this solution. (Freshly fixed material, 10μ to 20μ thick, is completely stained in 10 to 20 minutes but over-staining does not occur when longer times are allowed.) Return sections to distilled water (2 changes) and wash until diffusion of excess dye is no longer visible. Wash in 70% ethyl alcohol (2 changes) until diffusion of excess dye is no longer visible. Dehydrate in 95% ethyl alcohol and normal butyl alcohol, clear and mount.

Optimum staining of chromophilic material occurs at pH 3.65. Glial processes are well stained at pH 4.6. Nissl bodies and glial cytoplasm are purplish blue, nuclear chromatin is blue, background is clear at pH 3.65 but pale blue at pH 4.9.     

Staining Methods For Studying Ingredient Distribution In Baked Cakes

A method is described for preparing cake crumb for sectioning and staining. Previous to embedding, the fat was stained and fixed by exposing small blocks of cake to the fumes from a 5%, freshly-prepared, aqueous solution of osmic acid (OsO₄). This was followed by dehydration in ethyl alcohol and tertiary butyl alcohol, removal of air under vacuum and infiltration with paraffin.

Sections were cut 20 and 9Op thick and mounted with water.

Wax was removed by immersion in xylene. The sections were rehydrated in a series of ethyl alcohol dilutions, from concentrated to dilute, then transferred to distilled water.

Protein was then stained pink by immersion of the slides in an acidified 0.04% water solution of eosin Y, or starch was stained blue with a dilute aqueous solution of iodine. Ten grams iodine and 10 g. KI were dissolved in 25 ml. distilled water. This stock solution was diluted for use one to two hundred times.

The relationship between protein and starch was demonstrated by staining the sections with eosin, differentiating in 50% alcohol and staining with iodine.

When slides of cake crumb were prepared in this way, the fat was stained black, the protein bright pink and the starch granules a dark blue.     

An Arginine Histochemical Method Using Sakaguchi's New Reagent

A mounted paraffin section of material fixed in Bouin's, Carnoy's or 10% formalin is allowed to stand 15 minutes at room temperature in a 0.3% solution of 8-hydroxyquinoline in 30% ethanol. The slide, with adhering solution, is placed in 0.15 N hypochlorite (with enough KOH added to make the solution 0.015 N KOH) for 60 seconds, then (without draining) into a solution containing: 10 ml. of 0.15 N KOH; 15 g. of urea; 70 ml. of tertiary butyl alcohol, and water to make 100 ml. Here it is gently agitated for 10 sec. and then kept in a second change of the same solution for 2 min. Two changes of pure tertiary butyl alcohol, 10 sec. and 4 min.; one in aniline, 3 min.; and one of 10 sec. in xylene, complete the procedure. Permount containing 0.02% aniline is used as a mounting medium.     

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.     

Differential Cytophysiological Diagnosis of Cancerous and Normal Tissues

A method is offered for he differential diagnosis of cancer cells. It depends on the use of methylene blue decolorized with sodium thiosulfate (denoted here HLM, i.e. “hyposulfite methylene blue”); this is prepared by dissolving 800 mg. sodium thiosulfate in 10 ml. of 0.1% aqueous methylene blue and adding 3-5 drops of dilute (1:3) HCl. Frozen sections are treated with this reagent for 2-3 minutes, rinsed with a large amount of distilled water, then stained 2-3 minutes with 0.05% aqueous acid fuchsin. Staining should be performed in a darkened room. If all due precautions are observed, normal tissue appears blue, malignant tissue red.     

Suggested Counterstains for Davenport Reduced Silver Preparations of Peripheral Nerves

—Peripheral nerves which have been fixed in a mixture of formaldehyde and acetic acid and stained according to the method of Davenport can be successfully counterstained for demonstration of myelin sheaths and stroma. After mounted sections have been silvered, reduced and toned, the coating of nitrocellulose is removed by passing thru two changes of acetone. Following brief washes in 100,95,85 and 75% alcohols they are stained in an acidified aqueous solution of azo carmine for 30 to 60 minutes. Excess azo carmine is extracted with anilin alcohol followed by acetic alcohol after which the sections are mordanted for 15 to 60 minutes in a 5% aqueous solution of phosphotungstic acid. Without washing they are transferred to a stain mixture of either anilin blue and orange G (acidified) or light green and orange G (acidified) where they remain from 1 to 5 hours. After destaining in 95% alcohol and dehydration in absolute alcohol the sections are mounted in dammar. Result: axons stain black; sheath and fibroblast nuclei, red; myelin sheaths, orange; and connective tissue, blue or green. When the counterstains are applied to ganglia, cytological details of individual cells are demonstrated.     

A Comparative Study of some Dehydration and Clearing Agents

An experiment to determine the advantages of diozan, iso-butyl alcohol, tertiary butyl alcohol, and ethyl alcohol as dehydrants and chloroform, toluol, xylene, benzol, methyl benzoate, methyl salicylate, and acetone as clearers is described. Materials fixed in Bouin's fluid, Zenker formol, and 10% neutral formalin were dehydrated, embedded, sectioned, and stained. Bouin's fluid produces less hardening, shrinkage and distortion than the other fixatives employed. Slow dioxan is the best method of dehydration. All the picric acid need not be removed from tissues to be embedded in paraffin. Tissue blocks not more than 4 mm. thick may be dehydrated and impregnated with paraffin by slow dioxan in 13 hours, fast dioxan in 10 hours, iso-butyl alcohol and tertiary butyl alcohol in 14 hours, and ethyl alcohol-chloroform in 17 hours without incurring any distortion due to rapidity of dehydration and infiltration.     

Staining Angiosperm Shoot Apices with Heidenhain's Iron Hematoxylin and Aniline Blue

Good differential staining of nuclei, cytoplasm and cell walls of angiosperm shoot apices is obtained by a hematoxylin-aniline blue sequence. First, follow a typical Heidenhain's iron-hematoxylin scheme so that the nuclei and cytoplasm are well stained, then bring the slides up through an ethyl alcohol series to absolute alcohol. Transfer to a saturated solution of aniline blue in methyl cellosolve for 10 minutes. Remove the excess aniline blue with absolute alcohol, and follow this with a mixture of 42 parts absolute alcohol, 25 parts methyl salicylate, and 33 parts xylene; next, a similar mixture but in the proportions of 1:2:1; then a xylene-alcohol mixture, 9:1, followed by pure xylene, 2 changes, and covering in balsam. Panchromatic plates or film are suitable for photomicrographic reproduction (Ilford Special Rapid Panchromatic plates were used).     

A New Methylene Blue Technic for Permanent Preparations

1. Tissues stained intra vitam with methylene blue are fixed in a 10% ammonium molybdate solution in physiological saline (or sea water if the tissue is from a marine animal). Fixation time is kept to a minimum. Washing also is reduced to a minimum.

2. Excess fluids are removed from tissues by blotting with a paper or cloth towel before they are put into the succeeding solution. Tissues are taken from the wash water, blotted and placed in a mixture of equal parts of absolute ethyl alcohol and n-butyl alcohol for 30 minutes. They are then blotted and transferred to n-butyl alcohol for 30 minutes. After blotting they are placed in a mixture of one part methyl salicylate and four parts xylene until cleared. Tissues may be mounted whole or prepared for sectioning by embedding in paraffin in the usual way.

3. Tissues fixed, washed, dehydrated and cleared as described retain nearly all of the stain; the time required is greatly reduced; there is no need to chill the dehydrating solutions; cell distortion is much reduced.     

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.     

A Staining Procedure for Use in the Brucella Opsonocytophagic Test

The following staining procedure is recommended for use in the Brucella opsonocytophagic test in order to avoid confusing results obtained with stains of the Hasting or Wright type: Fix spreads for 5 minutes or longer in absolute methyl alcohol. Stain for 10 to 30 minutes in a solution of the following: 0.5 g. NaCl, 0.5 g. phenol, 0.5 g. methylene blue, 0.02 g. Na₂HPO₄+12H₂O, 50 cc. distilled water, 50 cc. methyl alcohol. Wash slides gently in water. Air dry. By this procedure, the bacteria and the nuclei of the leucocytes appear deep blue. The cytoplasm of the leucocytes appears faintly green with the cell outline distinctly visible. Cytoplasmic granules do not stain.     

An Assessment of Routine Chromosomal Staining Procedures in Radioautography

Unlabeled human chromosome preparations were treated with commonly employed chromosome stains as follows: (I) they were stained, destained, coated with liquid emulsion, developed, fixed, and restained; (II) stained and coated directly; or (III) coated and then stained. Of the stains tested, the methylene blue-eosin type (Giemsa, MacNeal's, Wright's) was useful for application after coating, although a similar stain (eosin-Stevenel's blue) caused formation of a heavy precipitate in the emulsion when so used. None of these stains could be employed before coating, however, even though they were removed with acid alcohol prior to dipping, because they caused chemographic grain formation in the emulsion. Aceto-orcein and Feulgen could not be employed after coating because the procedures removed the emulsion from the slides. Safranin was also found to be ineffective for staining coated preparations due to chemical changes caused by the photographic processing. The only stain which did not cause chemography, and hence can be used before coating slides, is aceto-orcein. Since this stain fades during radioautographic processing and cannot be employed after coating, we recommend secondary use of one of the methylene blue-eosin type stains for revisualization of the chromosome spread.     

Distribution of Methylene Blue after Injection into the Epidural Space of Anaesthetized Pregnant and Non-Pregnant Sheep

The aim of the study was to determine the distribution of different volumes of methylene blue solution injected into the epidural space in anaesthetized pregnant and non-pregnant sheep, to evaluate its cranial distribution and to compare between them. Fifteen pregnant and fifteen non-pregnant sheep were included in the study. Sheep were anaesthetized and received 0.05, 0.1, or 0.2 mL/kg of a lumbosacral epidural solution containing 0.12% methylene blue in 0.9% saline. Thirty minutes after the epidural injection, the ewes were euthanized. The extension of the dye within the epidural space was measured, and the correlation between the volume of the dye injected and the number of stained vertebrae was evaluated. The cranial migration of the dye between pregnant and non-pregnant sheep was also compared. The results show that the volume of methylene blue injected epidurally into pregnant and non-pregnant sheep correlated directly with its cephalic distribution into the epidural space; and a volume of 0.1 mL/kg or 0.2 mL/kg stained up to the first lumbar segment in pregnant and non-pregnant sheep, respectively. Also, the results suggest that the volume of drugs administered into the epidural space of pregnant sheep should be half the volume that would be used in non-pregnant sheep.     

The Staining of Brunner's Gland and Other Neutral Mucins by Carmine, Hematoxylin and Orcein in Alkaline Solutions

Brunner's glands and other neutral mucins may be stained red, brownish red, and violet, respectively, by carmine, hematoxylin, and orcein from appropriate alkaline solutions. Carmine and hematoxylin in concentrations of 0.2-1% are dissolved in 60-70% alcohol containing 1% potassium carbonate; orein is used in a 0.2% alcoholic solution of sodium hydroxide. Staining times are 15 to 30 minutes. The stained sections are rinsed in 95% or absolute alcohol prior to xylene and mounting. The staining of these mucins is blocked by mild bromine oxidation. By using alcian blue 0.1% in 3% acetic acid for 5 minutes prior to the above stains, mucins may be characterized in the same preparation as acid, neutral or mixed.     

The Staining of Brunner's Gland and Other Neutral Mucins by Carmine,Hematoxylin and Orcein in Alkaline Solutions

Brunner's glands and other neutral mucins may be stained red, brownish red, and violet, respectively, by carmine, hematoxylin, and orcein from appropriate alkaline solutions. Carmine and hematoxylin in concentrations of 0.2-1% are dissolved in 60-70% alcohol containing 1% potassium carbonate; orein is used in a 0.2% alcoholic solution of sodium hydroxide. Staining times are 15 to 30 minutes. The stained sections are rinsed in 95% or absolute alcohol prior to xylene and mounting. The staining of these mucins is blocked by mild bromine oxidation. By using alcian blue 0.1% in 3% acetic acid for 5 minutes prior to the above stains, mucins may be characterized in the same preparation as acid, neutral or mixed.     

The staining of Brunner's gland and other neutral mucins by carmine, hematoxylin and orcein in alkaline solutions.

Brunner's glands and other neutral mucins may be stained red, brownish red, and violet, respectively, by carmine, hematoxylin, and orcein from appropriate alkaline solutions. Carmine and hematoxylin in concentrations of 0.2-1% are dissolved in 60-70% alcohol containing 1% potassium carbonate; orcein is used in a 0.2% alcoholic solution of sodium hydroxide. Staining times are 15 to 30 minutes. The stained sections are rinsed in 95% or absolute alcohol prior to xylene and mounting. The staining of these mucins is blocked by mild bromine oxidation. By using alcian blue 0.1% in 3% acetic acid for 5 minutes prior to the above stains, mucins may be characterized in the same preparation as acid, neutral or mixed.     

A simple, rapid staining procedure for methacrylate embedded tissue sections using chromotrope 2R and methylene blue

Sections of tissue embedded in glycol methacrylate can be stained in rapid sequence with solutions of 1% aqueous chromotrope 2R adjusted to pH 3 and 0.1% methylene blue to produce sufficient contrast and cellular detail to permit quick visual inspection and/or photomicrography. Solutions of these stains are simple to prepare and are stable over long periods. Staining of sections may be accomplished within six minutes.     

A Simple, Rapid Staining Procedure for Methacrylate Embedded Tissue Sections Using Chromotrope 2R and Methylene Blue

Sections of tissue embedded in glycol methacrylate can be stained in rapid sequence with solutions of 1% aqueous chromotrope 2R adjusted to pH 3 and 0.1% methylene blue to produce sufficient contrast and cellular detail to permit quick visual inspection and/or photomicrography. Solutions of these stains are simple to prepare and are stable over long periods. Staining of sections may be accomplished within six minutes.