The Preparation of Vital Neutral Red

Neutral red iodide suitable for vital staining was prepared by condensing nitrosodimethylanilin hydrochloride with m-toluylenediamine and the indamine, toluylene blue, was obtained. This was subjected to air oxidation and converted to the eurhodine, neutral red. The purification of this dye was brought about by converting it into its comparatively insoluble stannous chloride double salt, filtering, dissolving in water, and precipitating the neutral red iodide with potassium iodide solution. This was re-dissolved in water, reprecipitated with potassium iodide solution and crystallized from 95% ethanol. The uncrystallized dye was also found satisfactory for vital staining. Several other preparations of neutral red iodide were made, using a somewhat different procedure than that given above, and it was generally found that satisfactory stains were obtained only when the preparation was free from toluylene blue.

The chloride of the color base was prepared by continuing the air oxidation of the toluylene blue until a test sample indicated its complete conversion into neutral red. The color was salted out with sodium chloride and crystallized from 95% ethanol. Both the crystallized and uncrystallized products were found to be excellent stains.     

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.     

Selective staining methods for cartilage of rat fetal specimens previously treated with alizarin red S.

A convenient method for staining cartilage with several basic stains after alizarin red S staining of bone was investigated in rat fetuses. It was found that bromophenol blue was useful and effective for staining of the margin and center areas of cartilage, even in specimens stored in glycerin for over 10 years. The specimens were washed in running tap water for 1 hr, and subsequently were immersed in water or in 70% ethanol at pH 4 for 1 hr or longer. The specimens were then stained with 0.005% bromophenol blue in 40% ethanol adjusted to pH 4 for 2 hr, or with 0.001% bromophenol blue in 40% ethanol adjusted to pH 4 for 24 hr. Furthermore, the bromophenol blue stain color actually faded when the specimens were immersed in water or in 70% ethanol at pH 8. Descending order of the stain-effective action on fetal rat cartilage for the basic stains tested was bromophenol blue, aniline blue, Evans blue, methyl violet, trypan blue, and water blue.     

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.     

Application of Nile red, a fluorescent hydrophobic probe, for the detection of neutral lipid deposits in tissue sections: comparison with oil red O

Nile red is a phenoxazone dye that fluoresces intensely, and in varying color, in organic solvents and hydrophobic lipids. However, the fluorescence is fully quenched in water. The dye acts, therefore, as a fluorescent hydrophobic probe. We utilized this novel property of nile red to develop a sensitive fluorescent histochemical stain for tissue lipids. Nile red was prepared by boiling Nile blue A under reflux for 2 hr in 0.5% H2SO4, and extracting the product into xylene. For staining, the purified dye is dissolved in 75% glycerol (1-5 micrograms/ml) and applied to frozen tissue sections. Tissue lipids then fluoresce yellow-gold to red, depending on their relative hydrophobicity. Using sections of liver and aorta from a cholesterol-fed rabbit, we assessed the value of Nile red as a stain for neutral lipids by comparing the staining pattern obtained with that produced by oil red O, a commonly used dye for tissue cholesteryl esters and triacylglycerols. In the cholesterol fatty liver, Nile red staining was comparable to that of oil red O. In contrast, Nile red staining of rabbit aortic atheroma revealed ubiquitous lipid deposits not observed with oil red O staining. These latter results suggest that Nile red can detect neutral lipid deposits, presumably unesterified cholesterol, not usually seen with oil red O or other traditional fat stains.     

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.     

Metachromasia of basic dyes induced by mercuric chloride. I

Summary Interactions of the cationic dye methylene blue with mercuric chloride have been studied conductometrically, analytically and spectrophotometrically. Methylene blue produces red colored precipitate with mercuric chloride; in presence of large excess of mercuric chloride a strong metachromasia is induced in the dye. Metachromasia induced by mercuric chloride is more hypsochromic as well as hypochromic than that induced by chromotopes like heparin. The complexes formed between methylene blue and mercuric chloride have variable compositions, the complex responsible for the red metachromatic color of the dye has the composition 2 dye: 1 HgCl₂. A model has been proposed for the metachromatic complex consisting hexa-coordinated mercury, dye is coordinated to the mercury by donating the lone pair electrons of terminal nitrogen. The non-metachromatic dye capri blue also interacts with mercuric chloride but without any change in the visible spectrum. Potassium iodide also gives metachromatic reddish blue colored precipitate with methylene blue.University Research Scholar.     

An Automated Double Staining Procedure for Bone and Cartilage

Differential skeletal staining is an important part of developmental toxicologic studies. Traditionally these studies have required time-consuming differentiation of one or both stains used and careful attention to the maceration step to prevent specimen destruction. We present a fully automated protocol which does not require differentiation of either dye and incorporates a controlled maceration step which is highly reproducible. This has resulted in high quality staining that is reproducible, stable, and can be done in volume with minimal personnel time. The process involves the staining of skinned, eviscerated specimens fixed in 95% ethanol. Using an automated tissue processor, the specimen is stained in alcian blue for 24 hr, macerated in 3% potassium hydroxide for 24 hr and stained with murexide for 24 hr. The specimens are cleared and preserved in glycerol. Within three days specimens have red stained bone and blue stained cartilage. The procedure was developed using 20-day-old Sprague-Dawley rat fetuses to evaluate the feasibility of using the procedure for teratology studies involving the fetal skeleton. Evenly stained specimens can be examined within three days and stored for years without loss of staining.     

Histological, Chromatographic and Spectrophotometric Studies of Toluidine Blue

Chromatographic analysis of commercial batches of toluidine blue shows these to be dye mixtures. Histologically, some samples were found to be poor metachromatic dyes. These unsatisfactory stains contained blue dyes with little or no metachromatic properties as well as a metachromatic fraction. On the other hand, contaminating dyes in histologically satisfactory samples had poor staining qualities and hence did not interfere with the color produced by the metachromatic fraction.

Chromatographic fractionation of different commercial batches of toluidine blue yielded identical, homogeneous metachromatic dyes. These purified dyes had a peak absorption at 615 mμ in contrast to that of purified azure A whose peak absorption was at 622.5 mμ.     

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.     

Spectrofluorometric studies of the lipid probe, nile red

We found that the dye nile red, 9-diethylamino-5H-benzo[alpha]phenoxazine-5-one, can be applied as a fluorescent vital stain for the detection of intracellular lipid droplets by fluorescence microscopy and flow cytofluorometry (J. Cell. Biol. 1985. 100: 965-973). To understand the selectivity of the staining, we examined the fluorescence properties of nile red in the presence of organic solvents and model lipid systems. Nile red was found to be both very soluble and strongly fluorescent in organic solvents. The excitation and emission spectra of nile red shifted to shorter wavelengths with decreasing solvent polarity. However, the fluorescence of nile red was quenched in aqueous medium. Nile red was observed to fluoresce intensely in the presence of aqueous suspensions of phosphatidylcholine vesicles (excitation maximum: 549 nm; emission maximum: 628 nm). When neutral lipids such as triacylglycerols or cholesteryl esters were incorporated with phosphatidylcholine to form microemulsions, nile red fluorescence emission maxima shifted to shorter wavelengths. Serum lipoproteins also induced nile red fluorescence and produced spectral blue shifts. Nile red fluorescence was not observed in the presence of either immunoglobulin G or gelatin. These results demonstrate that nile red fluorescence accompanied by a spectral blue shift reflects the presence of nile red in a hydrophobic lipid environment and account for the selective detection of neutral lipid by the dye. Nile red thus serves as an excellent fluorescent lipid probe.     

Studies on Textile Dyes for Biological Staining II. A Trichrome Stain for General Use

This trichrome staining procedure differentially stains elastic fibers, collagen fibers and mucin. Gomori's aldehyde-fuchsin is used for elastic fibers; fast yellow TN is the component used for collagen and cytoplasm; pontacyl blue black SX is the nuclear stain. Procedure: Paraffin sections to water; aldehyde-fuchsin, 30 min; 70% ethanol; distilled water; 0.75% pontacyl blue black SX in 1.5% K.₂Cr₂O₇, 15 min; tap water; 70% ethanol to wash off all free dye; 2% fast yellow TN in 95% ethanol, 5 min; dehydrate, clear and cover.     

4种碘化钾-过氧化氢法髓过氧化物酶染色结果比较

目的为了探讨较理想的髓过氧化物酶（MPO）染色方法。方法采用我室新建立的碘化钾-吡啰红B法（KI-PyB法）及碘化钾-吡啰红G法（KI-PyG法）,以及碘化钾-煌焦油蓝法（KI-BCB法）、碘化钾-wright-Giemsa法（KI-WG法）四种MPO染色法,同时对80例骨髓涂片标本进行了MPO染色。结果KI-PyB法MPO阳性产物呈鲜红色颗粒状,细胞核为蓝绿色;KI—PyG法MPO阳性产物呈棕黑色颗粒状,细胞核为浅红色;KI-BCB法阳性产物为蓝黑色颗粒状,细胞核为紫红色;KI-WG法阳性产物为深红色至棕黑色颗粒状,细胞核为浅蓝色或浅紫红色。4种碘化钾法MPO染色平均阳性率分别为60．9％、62．1％、56．3％及61．3％,差异无统计学意义（P〉0．05）。结论4种碘化钾法MPO染色中KI-PyG法的阳性率相对较高、且阳性反应易于判断,是较理想的MPO染色方法。     

Improved demonstration of mast cells using alcian blue tetrakis (methylpyridium) chloride

Many batches of alcian blue dye are incompletely soluble at the low pH used for demonstrating mast cells. An improved technique using alcian blue tetrakis (methylpyridium) chloride (alcian blue pyridine variant) is described here. It produces stronger mast cell staining than other alcian blue stains tested.     

Improved demonstration of mast cells using alcian blue tetrakis (methylpyridium) chloride

Many batches of alcian blue dye are incompletely soluble at the low pH used for demonstrating mast cells. An improved technique using alcian blue tetrakis (methylpyridium) chloride (alcian blue pyridine variant) is described here. It produces stronger mast cell staining than other alcian blue stains tested.     

Isolation of a component from commercial coomassie brilliant blue R-250 that stains rubrophilin and other proteins red on polyacrylamide gels

Commercially available Coomassie Brilliant Blue R-250 (C.I. 42660) is a popular and useful dye that stains most proteins blue on polyacrylamide gels. Some proteins from brain (rubrophilin), collagens, histones and parotid gland proteins are distinctly red when stained with Coomassie Blue. Commonly used Coomassie Brilliant Blue R-250 preparations may contain more than 30 distinct colored and fluorescent components that can be separated on silica gel chromatographic columns. A specific component has been isolated on silica gel columns that stains rubrophilin and other proline-rich proteins a reddish color. Fast atom bombardment mass spectrometry of the isolated rubrophilin staining principle indicates a molecular weight of 634 as compared to 826 for the major dye in the original Coomassie Brilliant Blue R-250. Infrared spectrometry is consistent with a difference between the rubrophilin staining principle and Coomassie Brilliant Blue R-250 of a toluene sulfonic acid residue.     

Selective vital staining of companion cells of potato tuber and parsnip root with neutral red.

When staining the internal phloem region of a potato tuber with the vital stain neutral red, it was observed that files of elongated cells of narrow diameter were heavily stained and were easily distinguishable from the more isodiametric parenchyma cells, many of which did not stain with neutral red. The elongated cells were identified as companion cells by locating the adjacent sieve-tube members through counterstaining with aniline blue and reviewing under violet light. Of a number of other plants surveyed, only parsnip roots possessed companion cells exhibiting a similar slective staining. In other plants both the companion cells and the surrounding parenchyma cells usually stained. Sieve-tube members never accumulated neutral red. It was concluded that the vacuoles of the companion cells of the potato tuber were stained by the ion trap mechanism because of the color of the accumulated stain, the lack of staining when neutral red was applied in an acidic solution, and the complete destaining after soaking in dilute ammonium hydroxide.     

Selective Vital Staining of Companion Cells of Potato Tuber and Parsnip Root with Neutral Red

When staining the internal phloem region of a potato tuber with the vital stain neutral red, it was observed that files of elongated cells of narrow diameter were heavily stained nod were easily distinguishable from the more isodiametric parenchyma cells, many of which did not stain with neutral red. The elongated cells were identified as companion cells by locating the adjacent sieve-tube members through counterstaining with aniline blue and viewing under violet light. Of a numb of other plants surveyed, only parsnip roots possessed companion cells exhibiting a similar selective staining. In other plants both the companion cells and the surrounding parenchyma cells usually stained. Sieve-tube members never accumulated neutral red. It was concluded that the vacuoles of the companion cells of the potato tuber were stained by the ion trap mechanism because of the color of the accumulated stain, the lack of staining when neutral red was applied in an acidic solution, and the complete destaining after waking in dilute ammonium hydroxide.