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 Basic Fuchsin and Alkalinized Methylene Blue Rapid Stain for Epoxyembedded Tissue

Sections 1 μ thick of epoxy-embedded, OsO₄-fixed tissues were stained with 4% aqueous basic fuchsin at 70 C for 1 min, rinsed well and destained, also at 70 C, for 1 min. A 2% aqueous methylene blue solution, alkalinized to pH 12.5 by mixing 1 N NaOH with the dye on the slide in the proportion of about 2:1, was then allowed to act for 2 min at 23-27 C. The stain was rinsed off the slide, and the preparation air dried before applying a mounting medium and cover glass. The mounting medium consisted of immersion oil sealed with epoxy household cement. Stains had not faded after 1 yr. The method is simple, rapid (total time 4-5 min), and provides sharp contrast between cellular and connective tissue components.     

Luxol Fast Blue as a Stain for Mallory's Alcoholic Hyaline

Luxol fast blue MBS (du Pont), which has frequently been used as a stain for phospholipids, stains Mallory's “alcoholic” hyaline a deep purplish blue. The stain is stable and provides histological appearances far superior to other methods. It is used on paraffin sections of tissue fixed in formalin or formalin-sublimate as a 0.1% solution in 90% alcohol at 60°C for 8 hr. Differentiation is made with 0.05% Li₂CO₃ and a red counterstain applied.     

Methylene Blue as a Cerebral Metabolic and Hemodynamic Enhancer

By restoring mitochondrial function, methylene blue (MB) is an effective neuroprotectant in many neurological disorders (e.g., Parkinson’s and Alzheimer’s diseases). MB has also been proposed as a brain metabolic enhancer because of its action on mitochondrial cytochrome c oxidase. We used in vitro and in vivo approaches to determine how MB affects brain metabolism and hemodynamics. For in vitro, we evaluated the effect of MB on brain mitochondrial function, oxygen consumption, and glucose uptake. For in vivo, we applied neuroimaging and intravenous measurements to determine MB’s effect on glucose uptake, cerebral blood flow (CBF), and cerebral metabolic rate of oxygen (CMRO₂) under normoxic and hypoxic conditions in rats. MB significantly increases mitochondrial complex I–III activity in isolated mitochondria and enhances oxygen consumption and glucose uptake in HT-22 cells. Using positron emission tomography and magnetic resonance imaging (MRI), we observed significant increases in brain glucose uptake, CBF, and CMRO₂ under both normoxic and hypoxic conditions. Further, MRI revealed that MB dramatically increased CBF in the hippocampus and in the cingulate, motor, and frontoparietal cortices, areas of the brain affected by Alzheimer’s and Parkinson’s diseases. Our results suggest that MB can enhance brain metabolism and hemodynamics, and multimetric neuroimaging systems offer a noninvasive, nondestructive way to evaluate treatment efficacy.     

Brilliant Cresyl Blue as A Stain for Chromosome Smear Preparations

Brilliant cresyl blue is substituted for carmine in the acetocarmine technic. A mixture of one part of 1% toluidine blue and three parts 0.75% brilliant cresyl blue dissolved in 45% acetic acid gives good results. Propionic acid may be used instead of acetic acid for more rapid penetration.     

Counterstaining Golgi-Cox Impregnations with Luxol Fast Blue as a Myelin Stain

Immerse pieces of brain tissue 4 wk in solutions A and B, mixed just before use: A. K₂Cr₂O₇, 1 gm; HgCl₂, 1 gm; boiling distilled water, 85 ml. Boil A for 15 min, cool to 2 C and add: B. K₂CrO₄, 0.8 gm; Na₂WO₄, 0.5 gm; distilled water, 20 ml. Rinse in water and immerse 24 hr in LiOH, 0.5 gm; KNO₃, 15 gm; distilled water, 100 ml. Wash 24 hr in several changes of 0.2% acetic acid and then for 2 hr in tap water. Dehydrate and embed in celloidin. Process a 60 μ section through 70 and 95% ethanol, a 3:1 mixture of absolute ethanol and chloroform, and toluene. Immerse it for 5 min in a solution containing methyl benzoate, 25 ml; benzyl alcohol, 100 ml; chloroform, 75 ml. Orient the section on a chemically clean slide and let air-dry 5-10 min. Process through toluene, 3:1 ethanol-chloroform and 95% ethanol. Place the section for 5-60 min at 60 C in a solution made up of: Luxol fast blue G (Matheson, Coleman and Bell), 1 gm; 95% ethanol, 1000 ml; 10% acetic acid, 5 ml. Hydrate to water and immerse in 0.05% Li₂CO₃ for 3-4 min. Differentiate in 70% ethanol and place in water. Immerse for 5-15 min in a mixture of two solutions: A. cresylechtviolet (Otto C. Watzka, Montreal), 2 gm; 1 M acetic acid, 185 ml; B. 1 M sodium acetate, 15 ml; distilled water, 400 ml; absolute ethanol, 200 ml. Dehydrate to 3:1 ethanol-chloroform. Clear in toluene and apply a coverslip. The technique produces fast Golgi-Cox impregnated neurons against a background of counterstained myelinated fibers. Patterns of the myelinated fibers can be used to localize impregnated neurons.     

Basic Blue 75: a New Stain for Erythroblasts

C.I. basic blue 75 in an aqueous alkaline solution stains the nuclei of mature anc immature erythroblasts bright red. Simultane ously, the stain colors the cytoplasm of erythro blasts blue in immature cells and purple in ma ture cells. Colors of the type described were noi found in other normal and abnormal hemato poietic cells.     

A Sudan Black B Myelin Stain for Peripheral Nerves

Blocks of fresh issue were fixed 2 or more days in: cobalt sulfate (or nitrate), 1 gm; distilled water, 80 ml; 10% calcium chloride, 10 ml; and formalin, 10 ml. The fixed tissue was washed thoroughly in tap water, embedded in gelatin, frozen sections cut, and mounted on slides with gelatin adhesive. The sections were stained 15-30 min in a saturated, filtered solution of Sudan black B in 70% alcohol, differentiated in 50% alcohol under microscopic observation, and a cover glass applied with glycerol-gelatin. In thick (50-100 μ) sections, myelin stained green to gray-green and this allowed easy differentiation between nerves and other tissue elements.     

Romanowsky-Malachowski Stains the So-Called Romanowsky Stain: Malachowski's 1891 Use of Alkali Polychromed Methylene Blue for Malaria Plasmodia

In the course of revising the chapter on neutral stains for the 9th edition of Conn's Biological Stains (1977) two papers of Kingsley (1935, 1937) were encountered. The first seemed to be a rather minor revision of MacNeal's tetrachrome stain, the second was concerned mainly with the inclusion of acetone in the solvent. Kingsley in this 1937 paper made an extensive review of the literature and made the only post-Nocht reference to Malachowski's 1891 publication that we had seen. It was not until much later when we were able to obtain a copy of Malachowski's 1891 paper and to study it in detail that we realized that not only had Malachowski published his results slightly before Romanowsky's 1891 paper, but that he had also anticipated Nocht's (1898) discovery of the use of alkali polychromed methylene blue.     

Methylene Blue Reduced Abnormal Tau Accumulation in P301L Tau Transgenic Mice

In neurodegenerative disorders, abnormally hyperphosphorylated and aggregated tau accumulates intracellularly, a mechanism which is thought to induce neuronal cell death. Methylene blue, a type of phenothiazine, has been reported to inhibit tau aggregation in vitro. However, the effect of methylene blue in vivo has remained unknown. Therefore, we examined whether methylene blue suppresses abnormal tau accumulation using P301L tau transgenic mice. At 8 to 11 months of age, these mice were orally administered methylene blue for 5 months. Subsequent results of Western blotting analysis revealed that this agent reduced detergent-insoluble phospho-tau. Methylene blue may have potential as a drug candidate for the treatment of tauopathy.     

Rhodanile Blue; a Rapid and Selective Stain for Heinz Bodies

Equal volumes of heparinized or EDTA-treated blood and a 0.5% solution of rhodanile blue (E. Gurr, Michrome No. 1156) in 1% NaCl were mixed and allowed to stand for 2 rain. Thin smears were then prepared, air dried and examined under oil. Heinz bodies stained deep purple and contrasted well with the yellow-orange to blue-green cytoplasm. Durable mounts could be made by applying a cover glass with a resinous mediiun to the dry smear (D. P. X. was used). The reticular material in reticulocytes did not stain in 2 min but could be stained by allowing the stain to act 5 min.     

Luxol Fast Blue Mbs and Phloxine; a Stain for Mitochondria

The applicability of Luxol fast blue MBS as a 0.1% solution in 0.05% acetic acid to the staining of mitochondria, first recognized in rat kidney by Shanklin and Nassar (Stain Techn., 34: 257-60. 1959), was confirmed in various organs (formalin-Zenker and Regaud's fixations; paraffin embedding) of the mouse and bullfrog. In liver cells and in the epithelium of renal tubules, mitochondria were stained green, selectively and clearly. The dark cells of the renal tubules and the middle piece of sperms in both animals were conspicuously demonstrated by their dense assemblages of green granules. The periodic acid-Schiff procedure proposed by Shanklin and Nassar as a counterstain was replaced by staining in 0.5% aqueous phloxine, 2-3 min; differentiation in 5% phosphotungstic acid, 2 min; and washing in water, 5 min. This simplified and accelerated the techique, and gave a better color contrast. Advantages of Luxol fast blue MBS and phloxine staining over traditional methods for mitochondria in paraffin sections are: durability of the stain, high specificity, simplicity of procedure, and constant result.     

Physical Damage on Giant Vesicles Membrane as a Result of Methylene Blue Photoirradiation

In this study we pursue a closer analysis of the photodamage promoted on giant unilamellar vesicles membranes made of dioleoyl-sn-glycero-3-phosphocholine (DOPC) or 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC), by irradiating methylene blue present in the giant unilamellar vesicles solution. By means of optical microscopy and electro-deformation experiments, the physical damage on the vesicle membrane was followed and the phospholipids oxidation was evaluated in terms of changes in the membrane surface area and permeability. As expected, oxidation modifies structural characteristics of the phospholipids that lead to remarkable membrane alterations. By comparing DOPC- with POPC-made membranes, we observed that the rate of pore formation and vesicle degradation as a function of methylene blue concentration follows a diffusion law in the case of DOPC and a linear variation in the case of POPC. We attributed this scenario to the nucleation process of oxidized species following a diffusion-limited growth regime for DOPC and in the case of POPC a homogeneous nucleation process. On the basis of these premises, we constructed models based on reaction-diffusion equations that fit well with the experimental data. This information shows that the outcome of the photosensitization reactions is critically dependent on the type of lipid present in the membrane.     

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.     

Hot, Acidified Rhodamine B and Methylene Blue; A Differential Stain Dichromatic for Hair Follicular Keratins, Achromatic for Epidermal Keratin

Procedure:Cut paraffin sections and float on a 45-50 C water bath; spread silicone-rubber adhesive (Clear Seal-General Electric) thinly and evenly over 2/3 of the slide; pick up the sections from the floatation water with the coated slide; dry for 1.5 hr at 25 C and at 60 C for 0.5 hr; deparaffinize, and hydrate to water. Place 150 mg of rhodamine B and 150 mg of methylene blue each in separate 100 ml beakers and add 80 ml of 10% HCl to each beaker. Bring both solutions to a boil on a hot plate in a fume hood; immerse tissue sections in the boiling rhodamine B exactly 2 min; rinse in a beaker of 10% HCl 5 sec; immerse in the boiling methylene blue exactly 0.5 min; rinse in distilled water; blot dry; and mount in a silicone-rubber medium (Glass and Ceramic Adhesive—Dow Corning Corp.). Hair shaft keratin stains red; inner root sheath keratin and keratogenous zone of the hair shaft, blue green; epidermal keratin remains unstained. Pilomatrixornas show foci of both red and blue green keratin; epidermal and hair sheath (“sebaceous”) cysts remain unstained.     

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.     

An Improved Fixing Solution for Methylene Blue Preparations

A method is described which combines the writer's hot celloidin technic¹ with a form of the clearing-before-cutting procedure. The method requires only 16–17 days and yields a block which may be cut in any microtome, the sections being as thin as those afforded by paraffin with comparable material. The advantages of celloidin over paraffin, listed in the writer's earlier paper, are retained in the present method which, altho consuming more time than the hot process, requires less skill and gives superior results.