Method of counterstaining preparations for immunofluorescent studies of the pituitary]

To elucidate nonfluorescent structural elements of the hypophyseal parenchyma for immunofluorescent investigations, properties of some dyes most commonly applied for hypophysis staining have been studied. Such dyes as paraldehide-fuchsin, light green, orange G, chromotrop 2R, hematoxylin, eosin, fuchsin, azocarmin possess their own intensive luminescence and block immunofluorescence completely. Some other dyes (trypan blue, bromthymol blue, aniline blue, malachite green, methyl green) though not blocking immunofluorescence, they do not reveal hypophyseal cellular elements distinctly enough. Good results have been obtained with 0.3% water solution of toluidine blue, 0.5% solution of methylene light blue, methylene blue, as well as with Gram--Weigert's staining and with gallocyanin after Einarson. For special staining of corticotropocytes, the authors recommend 0.1% solution of bromphenol blue in barate buffer, pH 8.2.     

Block staining of mammalian tissues with hematoxylin and eosin

Various mammalian tissues were stained en bloc with hematoxylin and eosin after fixation and prior to embedding in paraffin wax and sectioning. The choice of fixative is important and best results are obtained using Worcester's Fluid, a combination of saturated aqueous mercuric chloride, formaldehyde, and glacial acetic acid. After fixation, blocks of tissue up to 1.5 cm thick are stained for seven days in hematoxylin. Excess stain is removed by washing tissues in running water overnight. Tissue blocks then are dehydrated with graded concentrations of ethyl alcohols to 80% and counterstained, with further dehydration, in 0.5% spirit soluble eosin in 90% ethyl alcohol for five days. The tissue is subsequently transferred to 90% ethyl alcohol overnight to differentiate eosin staining; dehydration is completed in absolute ethyl alcohol. The blocks are cleared in in cedarwood oil and briefly in xylene prior to embedding, sectioning, and mounting. Following removal of wax by xylene, coverslips are applied. General morphological and histological features were particularly well differentiated and very selectively and reliably stained by this method.     

Block Staining of Mammalian Tissues with Hematoxylin and Eosin

Various mammalian tissues were stained en bloc with hematoxylin and eosin after fixation and prior to embedding in paraffin wax and sectioning. The choice of fixative is important and best results are obtained using Worcester's Fluid, a combination of saturated aqueous mercuric chloride, formaldehyde, and glacial acetic acid. After fixation, blocks of tissue up to 1.5 cm thick are stained for seven days in hematoxylin. Excess stain is removed by washing tissues in running water overnight. Tissue blocks then are dehydrated with graded concentrations of ethyl alcohols to 80% and counterstained, with further dehydration, in 0.5% spirit soluble eosin in 90% ethyl alcohol for five days. The tissue is subsequently transferred to 90% ethyl alcohol overnight to differentiate eosin staining; dehydration is completed in absolute ethyl alcohol. The blocks are cleared in cedarwood oil and briefly in xylene prior to embedding, sectioning, and mounting. Following removal of wax by xylene, coverslips are applied.

General morphological and histological features were particularly well differentiated and very selectively and reliably stained by this method.     

The Effect of pH on Staining by Eosins

The effect of pH on staining by 7 dyes of the eosin group was studied by means of specimens fixed 12-18 hr in Gilson's, in Petrunkewitsch's, or in Zenker's fluids, respectively. Sections were soaked in water or alcohol, depending upon the stain solvent, adjusted in 31 equal steps from pH 4.0 to 10.0 before being stained in similarly adjusted dye solutions. The stained sections were rinsed at H-ion concentrations identical to that at which staining took place, until no further color came away, and mounted. Variations in pH elicited different degrees of stain retention; different fixation altered staining affinity even though staining was effected at identical pH values.     

Nuclear stains with soluble metachrome metal mordant dye lakes. The effect of chemical endgroup blocking reactions and the artificial introduction of acid groups into tissues.

Following our study on the effect of deoxyribonucleic acid (DNA) extraction on nuclear staining with soluble metal mordant dye lakes covering 29 dye lakes we chose a series of lakes representing the three groups: (1) readily prevented by DNA removal, (2) weakened by DNA extraction but not prevented, (3) unaffected by DNA removal, for application of other endgroup blockade reactions. The lakes selected were alum and iron hematoxylins, iron alum and ferrous sulfate galleins, Fe2+ gallo blue E, iron alum celestin blue B, iron alum fluorone black and the phenocyanin TC-FeSO4 sequence. Azure A with and without an eosin B neutral stain, was used as a simple cationic (and anionic) dye control. Methylation was less effective than with simple cationic dyes, but did weaken celestin blue, gallo blue E and phenocyanin Fe2+ nuclear stains. These dyes also demonstrate other acid groups: acid mucins, cartilage matrix, mast cells, central nervous corpora amylacea and artificially introduced carboxyl, sulfuric and sulfonic acid groups. Alum hematoxylin stained cartilage weakly and demonstrated sulfation and sulfonation sites. The iron galleins, iron fluorone black and acid iron hematoxylin do not. A pH 4 iron alum hematoxylin gave no staining of these sites; an alum hematoxylin acidified with 1% 12 N HCl gave weaker results. Deamination prevented eosin and orange G counterstains but did not impair nuclear stains with any of the mordant dye lakes. The simple acetylations likewise did not alter mordant dye nuclear staining, the Skraup reagent gave its usual sulfation effect on other tissue elements, but did not alter nuclear stains by mordant dyes. The mordant dyes do not bind to periodic acid engendered aldehyde sites and p-toluidine/acetic acid and borohydride aldehyde blockades did not alter mordant dye lake nuclear staining. Nitration by tetranitromethane, which blocks azo coupling of tyrosine residues, did not alter nuclear staining by the mordant dye lakes. Benzil at pH 13, which prevents the beta-naphthoquinone-4-Na sulfonate (NQS) arginine reaction and the Fullmer reaction of basic nucleoprotein, did not affect iron gallein, iron or alum hematoxylin stains of nuclei or lingual keratohyalin.     

Detailed Differentiation of Bacteria by Means of A Mixture of Acid and Basic Dyes at Different pH-Values

As previously reported by the author (1927), a mixture of methylene blue and eosin Y can be used for the differential staining of bacteria. It gives a fairly deep staining of bacteria at about pH 3 and above. Below pH 3 the eosin Y stains bacteria only a very pale pink; at such high H-ion concentration, the eosin is present as undissociated color acid, and for this reason not enough eosin is in solution to stain bacteria. To improve the staining at such reactions, the eosin was replaced by a stronger acid dye, namely acid fuchsin. The mixture of methylene blue medicinal Merck and acid fuchsin can be successfully used at a pH-value as low as 0.8. The method of staining by this new mixture is entirely the same as with the old mixture. It is sensitive enough to detect the difference in the isoelectric points: (1) of the single bacteria from the same pure culture, (2) of different strains of the colon and typhoid organisms. Some strains of the colon organism were found by this method with an isoelectric point at a pH-value as low as that of the Staphylococcus. Others, on the contrary, have their isoelectric point as high in the pH-scale as that of the typhoid organism. The new mixture can also be used for the study of the chemical composition of the different parts of bacterial body. Applying it at a definite pH-value, the author was able to stain differentially polar bodies of the typhoid group and of the diphtheria organism. This new mixture can be recommended in staining of B. diphtheriae as a substitute for Neisser's stain. It is interesting to note that polar bodies of the colon group consist of more alkaline protein than the body of the bacteria itself, i. e., they are stained by acid fuchsin. The polar bodies of the B. diphtheriae on the contrary are composed of more acid protein than the bacterial body; i. e., they are stained by methylene blue. The impossibility of detecting the above mentioned variations in the isoelectric points of bacteria using the Gram method is explained by the absence of pH variations in the latter technic. The differentiation of bacteria by the Gram stain depends chiefly on the varying stability of the compound formed (Gram-positive or Gram-negative bacteria plus gentian violet and iodine) in the presence of organic solvents, such as alcohol, acetone, etc.     

Efficient staining of actinomycetoma and eumycetoma grains using henna extract

The use of natural, nontoxic, convenient and eco-friendly dyes for histopathological diagnosis avoids some of the synthetic dyes’ hazards. I used an aqueous extract of henna at a concentration of 20 g/ml and acidified with acetic acid to stain mycetoma grains. Henna stained mycetoma grains orange-red to brown. The engulfed mycetoma grains within inflammatory cells stained well with henna extract compared to hematoxylin and eosin (H & E) and hexamine silver.     

Modified Elastic Tissue-Masson Trichrome Stain

A combined elastic tissue-Massou technique is presented which stains elastic fibers of all sizes, nuclei and connective tissue. The modified elastic tissue stain consists of hematoxylin, ferric chloride and Verhoeffs iodine; nuclei and elastic fibers are stained blue-black in six minutes without differentiation. By contrast, cytoplasmic elements are stained red, (Biebrich scarlet-acid fuchsin) and collagen is stained green (light green) or blue (aniline blue). The entire staining procedure takes approximately one hour.     

Modified elastic tissue-Masson trichrome stain

A combined elastic tissue-Masson technique is presented which stains elastic fibers of all sizes, nuclei and connective tissue. The modified elastic tissue stain consists of hematoxylin, ferric chloride and Verhoeff's iodine; nuclei and elastic fibers are stained blue-black in six minutes without differentiation. By contrast, cytoplasmic elements are stained red, (Biebrich scarlet-acid fuchsin) and collagen is stained green (light green) or blue (aniline blue). The entire staining procedure takes approximately one hour.     

Staining of Pathogenic Fungi with Gomori's Aldehyde-Fuchsin in Both Old and New Sections

Gomori's stain for elastic tissue can be applied directly to paraffin sections as a routine method for fungus capsules and membranes. Either freshly prepared, or old sections previously stained with hematoxylin-eosin, can be used. After applying the aldehydefuchsin stain, nuclei may be stained (or restained) with hematoxylin, and a general background stain obtained with either eosin or light green.     

Phosphotungstic Acid-Eosin Combined with Hematoxylin as A Stain for Negri Bodies in Paraffin Sections

Experimentation with the Papanicolaou stain in this laboratory led to the discovery that the eosin, combined with phosphotungstic acid, was responsible for differential staining of Negri bodies. Eosin prepared as in EA 36 was used, but without the light green and Bismarck brown. Paraffin sections of hippocampus from brains of animal affected with rabies were fixed in 10% formol or in a mixture of 2 volumes of saturated aqueous HgCl₂ and 1 volume of absolute alcohol. They were stained first with hematoxylin and then with eosin. This procedure gave better results than staining with other types of eosin or by the original EA 36 mixture. The Negri bodies were well stained and their structure easily visible. The best results were obtained from material fixed with the HgCl₂ solution.     

Nuclear stains with soluble metachrome metal mordant dye lakes

Summary Following our study on the effect of deoxyribonucleic acid (DNA) extraction on nuclear staining with soluble metal mordant dye lakes covering 29 dye lakes we chose a series of lakes representing the three groups: (1) readily prevented by DNA removal, (2) weakened by DNA extraction but not prevented, (3) unaffected by DNA removal, for application of other endgroup blockade reactions. The lakes selected were alum and iron hematoxylins, iron alum and ferrous sulfate galleins, Fe²⁺ gallo blue E, iron alum celestin blue B, iron alum fluorone black and the phenocyanin TC-FeSO₄ sequence. Azure A with and without an eosin B neutral stain, was used as a simple cationic (and anionic) dye control.Methylation was less effective than with simple cationic dyes, but did weaken celestin blue, gallo blue E and phenocyanin Fe²⁺ nuclear stains. These dyes also demonstrate other acid groups: acid mucins, cartilage matrix, mast cells, central nervous corpora amylacea and artificially introduced carboxyl, sulfuric and sulfonic acid groups. Alum hematoxylin stained cartilage weakly and demonstrated sulfation and sulfonation sites. The iron galleins, iron fluorone black and acid iron hematoxylin do not. A pH 4 iron alum hematoxylin gave no staining of these sites; an alum hematoxylin acidified with 1% 12 N HCl gave weaker results.Deamination prevented eosin and orange G counterstains but did not impair nuclear stains with any of the mordant dye lakes. The simple acetylations likewise did not alter mordant dye nuclear staining, the Skraup reagent gave its usual sulfation effect on other tissue elements, but did not alter nuclear stains by mordant dyes.The mordant dyes do not bind to periodic acid engendered aldehyde sites and p-toluidine/acetic acid and borohydride aldehyde blockades did not alter mordant dye lake nuclear staining. Nitration by tetranitromethane, which blocks azo coupling of tyrosine residues, did not alter nuclear staining by the mordant dye lakes¹. Benzil at pH 13, which prevents the -naphthoquinone-4-Na sulfonate (NQS) arginine reaction and the Fullmer reaction of basic nucleoprotein, did not affect iron gallein, iron or alum hematoxylin stains of nuclei or lingual keratohyalin.Assisted by Contract Nol-CB-43912 National Cancer Institute     

Standardized Thionin-Eosin Y: A Quick Stain for Cytology

Two stains long used in exfoliative cytology, the hematoxylin-eosin Y and Papanicolaou stains, have not been standardized even today. Some dozens of hematoxylin and eosin and Papanicolaou staining recipes have been recommended in the literature. Consequently, the staining pattern of hematoxylin and eosin, and Papanicolaou stained cytological material varies from laboratory to laboratory. To a certain degree this is due to batch-to-batch variations of commercial samples of the natural dye hematoxylin (C.I. 75290). The present paper describes a simple, standardized and reproducible procedure using thionin bromide to replace hematoxylin in the hematoxylin and eosin stain.     

细菌脱色酶TpmD对三苯基甲烷类染料脱色的酶学特性研究

从嗜水气单胞菌DN322中分离纯化出能够对三苯基甲烷类染料结晶紫、碱性品红、灿烂绿及孔雀绿进行有效脱色的脱色酶,命名为TpmD。该酶的亚基分子量为29.4kDa,等电点为5.6。该酶催化上述4种三苯基甲烷类染料脱色反应的适合温度为40~60℃,适合pH范围为5.5~9.0。动力学参数测定结果显示TpmD对结晶紫、碱性品红、灿烂绿及孔雀绿的Km值分别为24.3、40.65、4.2、68.5μmol-1.L-1,Vmax值分别为19.6、74.1、82.8、115.6μmol.L-1.s-1。结晶紫为该酶的最适反应底物。TpmD催化的脱色反应依懒于NADH/NADPH及分子氧的存在,显示该酶属于NADH/NADPH依赖型的氧化酶类。这是国内外首次关于细菌中三苯基甲烷类染料脱色酶酶学性质的描述。     

New Fuchsin-Hematoxylin-Eosin; A Stain for Acid-Fast Bacilli and Surrounding Tissue

This is a staining technique for histopathologic evaluation of tissue reaction in the environs of acid-fast tubercle bacilli (avian and bovine) in sections. Fresh tissue is fixed in 10% neutral formalin and processed in the usual manner for embedding in paraffin. Sections are cut approximately 6 μ. thick, dewaxed, hydrated, and stained with Harris' hematoxylin. They are rinsed in tap water, differentiated in add alcohol, washed in tap water, given a distilled water rinse and stained at 20-30° C in a 1% solution of new fuchsin in 5% phenol. Each slide is then handled individually by placing it directly into a saturated aqueous solution of Li₂CO₃ and agitated gently for a few seconds. This is followed by differentiation with 5% glacial acetic acid in absolute or 95% ethyl alcohol until the color stops running. Two rinses in absolute or 95% ethyl alcohol follow. The sections are then counterstained in the color add of eosin Y prepared according to the method of Schleicher (Stain Techn., 28, 119-23, 1953) and used as an 0.025% solution in absolute alcohol. Following passage through 2 changes of absolute alcohol, the sections are cleared in xylene, then mounted in Permount or similar synthetic resin. The add-fast barilli are emphasized by their bright retractile red color within a contrasting background of hematoxylin and eosin.     

New Fuchsin-Hematoxylin-Eosin; A Stain for Acid-Fast Bacilli and Surrounding Tissue

This is a staining technique for histopathologic evaluation of tissue reaction in the environs of acid-fast tubercle bacilli (avian and bovine) in sections. Fresh tissue is fixed in 10% neutral formalin and processed in the usual manner for embedding in paraffin. Sections are cut approximately 6 μ. thick, dewaxed, hydrated, and stained with Harris' hematoxylin. They are rinsed in tap water, differentiated in add alcohol, washed in tap water, given a distilled water rinse and stained at 20-30° C in a 1% solution of new fuchsin in 5% phenol. Each slide is then handled individually by placing it directly into a saturated aqueous solution of Li₂CO₃ and agitated gently for a few seconds. This is followed by differentiation with 5% glacial acetic acid in absolute or 95% ethyl alcohol until the color stops running. Two rinses in absolute or 95% ethyl alcohol follow. The sections are then counterstained in the color add of eosin Y prepared according to the method of Schleicher (Stain Techn., 28, 119-23, 1953) and used as an 0.025% solution in absolute alcohol. Following passage through 2 changes of absolute alcohol, the sections are cleared in xylene, then mounted in Permount or similar synthetic resin. The add-fast barilli are emphasized by their bright retractile red color within a contrasting background of hematoxylin and eosin.     

The Determination of Apparent Isoelectric Points of Cell Structures by Staining at Controlled Reactions

The staining reactions at controlled pH-values of various dyes with the nucleus and cytoplasm of Trichonympha collaris under different conditions were investigated. When staining intensity was plotted against pH, it was found that with each dye a different curve was obtained. “Isoelectric points” obtained by superposition of acid and basic dye curves varied for the same material with the dyes employed. It was found that, with the same dye, the curves of staining intensity plotted against pH varied with the buffer system utilized. Moreover, the intensity of staining at any pH was found to vary directly with the concentration of dye and inversely with the concentration of buffer. Various factors modifying staining intensity were studied. In the staining of a protein in buffered solution, it was shown that staining intensity (the index of the concentration of the dye-protein compound) at a given pH-value is dependent upon the interaction of the dye-protein, buffer-protein and dye-buffer systems, and that as the dye or buffer or their concentrations were varied, the resultant “isoelectric points” which were obtained also varied. In view of these facts and of the present lack of knowledge of dyes and dye-protein combinations it would be impossible to determine a true isoelectric point by staining at controlled pH-values without further extensive work on the subject. It follows that no true isoelectric points have hitherto been obtained for nucleus, cytoplasm or other tissue elements by staining at controlled pH.     

Standard specimens for stain calibration: application to Romanowsky-Giemsa staining.

Standardized specimens with reproducible staining properties were fabricated from extracts of biological objects (bovine liver, nucleoprotamine and defatted muscle). The standard specimens were stained with two formulations of the Romanowsky-Giemsa stain (RG), using the same azure B and eosin Y. One formulation used methanol and Sorensen's buffer and the other DMSO and Hepes buffer as solvents. The standard specimens were stained either in the composite stain or in the individual dyes dissolved in the same solvents and at the same concentration as the composite stain. Solution spectroscopy demonstrated different spectra for the two formulations with some wavelength regions varying by more than an order of magnitude. The RG spectra were also very different from those of the individual dyes dissolved at the RG concentration in the respective solvents. The stained standard specimens were analyzed by microspectrophotometry and were found to have spectra similar to those of cell smears. Furthermore, the standard specimens were shown to be a repeatable substrate for stain uptake. The transmitted light intensity from random fields of the same standardized specimen varied +/- 5%. When specimens were stained at the same time, the specimen-to-specimen variation depended on preparation conditions and the measurement wavelength, but was as good as +/- 5% for some conditions. The quantitative stain performance of both formulations was studied and compared. The standardized specimens provide a tool for the quantitative study of staining processes and specimen preparation procedures and for stain calibration.     

Metallic Lakes of the oxazines (Gallamin Blue, Gallocyanin and Coelestin Blue) as Nuclear Stain Substitutes for Hematoxylin

Becher's investigations upon the soluble metallic lakes of the oxazines have been re-investigated, extended and results described. Gallamin blue, gallocyanin and coelestin blue in combination with ferric ammonium sulfate gave the best results. The dyes are dissolved in a five per cent aqueous solution of ferric ammonium sulfate. The solution is boiled for 2-3 minutes, cooled, filtered and ready for immediate use. The iron lakes of these dyes stain nuclei excellently giving a deep blue or blue black in 3-5 minutes. No differentiation with acid is required. Coelestin blue gives the most stable solution and is recommended as a routine nuclear stain. The protoplasm remains practically colorless and counter-staining with acid dyes such as ethyl-eosin, orange G, or fuchsin gives pictures which cannot be distinguished from a good hematoxylin stain.

Counter-staining with van Gieson solution is also possible. Benda's modification of the van Gieson solution is recommended. Staining of fat with Sudan, scarlet red, etc., does not interfere with nuclear staining by these dyes.

As applied to the central nervous system these dyes are far superior to hematoxylin. Ganglion and glia cells are as excellently stained as with thionin.

The most widely used fixatives, namely formaldehyde, Mueller-formaldehyde, Zenker's and alcohol, give equally as good results. The nature of the staining process is briefly discussed and a prospectus offered.     

A combination Verhoeff's elastic and Masson's trichrome stain for routine histology

A method for the combined staining of elastic, muscle and connective tissue for routine use in histopathology is described. The elastica, stained black by Verhoeff's technique, is contrasted with the muscle and connective tissue stained red and green or blue respectively by a modification of Masson's trichrome. Cell nuclei stain blue-black with Weigert's iron hematoxylin. The procedure takes approximately two hours and is most suitable for the study of vascular pathology in surgical and autopsy sections.