Side effects of reaction media in histochemical blocking procedures

Synopsis 0.2 N NaOH, the reaction medium for 1,2-cyclohexanedione, a specific reagent for arginyl residues in proteins, was found to intensify, at some sites in rat abdominal skin and human gingiva, the Sakaguchi reaction, staining with Pauly's reagent, and anionic dye binding at pH 6.4; at other sites these reactions were reduced, presumably due to extraction of material from sections. 0.2 N NaOH slightly reduced staining after the ninhydrin-Schiff procedure at all sites in rat skin. The interpretation of this finding is obscure, because some sites giving a positive Sakaguchi reaction and staining with anionic dyes failed to stain after the ninhydrin-Schiff procedure. There were also alterations in staining, with the cationic dyes Alcian Blue and Alcian Yellow. It is suggested that 0.2 N NaOH ruptures linkages between polycationic residues of proteins and polanions, demonstrable by Alican Blue. The blockade produced by acetic anhydride-pyridine (4060 v/v) mixtures was stable, in the alkaline conditions required for staining with Pauly's reagent. Pretreatment with pyridine alone reduced tissue binding of anionic dyes.     

One-bath trichrome staining: Investigation of a general mechanism based on a structure-staining correlation analysis

Summary Dye pairs of contrasting colours were selected from acid dyes of varied chemical characteristics. The 44 dye pairs were investigated in a one-bath trichrome staining system in which the dye-baths were strongly acid. Dye concentrations, concentration ratios and staining times were varied for each dye pair. Thirty dye pairs stained collagen fibres distinctly different colours to muscle cytoplasm, while 14 dye pairs gave muddy, non-selective staining. Comparison of dye structures showed that in selective pairs the larger dye always stained the collagen fibres, with cytoplasm being coloured by the smaller species. With 28/30 of the selective dye pairs the differences in anionic weights of the dyes was > 200. However, in dye pairs giving non-selective staining, the anionic weights of the members of 13/14 of the dye pairs differed by < 200. As no other structural feature correlated so clearly with selectivity, it was concluded that the selectivity of one-bath trichromes is diffusion-rate controlled, involving the interaction of differentially permeable tissue sites (collagen being more permeable than muscle cytoplasm) with dyes diffusing at different rates (large dyes slower than small). In keeping with this, lengthening staining times reduced staining selectivity. The rate control mechanism suggested a rational trouble-shooting guide for one-bath trichromes, encompassing such practical factors as dye concentration, embedding medium, fixative, dye-bath pH, section thickness and staining time.     

Some effects of salts on staining: Use of the Donnan Equilibrium to describe staining of tissue sections with acid and basic dyes

Summary Using a wide variety of acid and basic dyes, and dyebaths of various pH’s and salt contents, it was shown that various effects of neutral inorganic salts on the staining of tissue sections could be explained by the Donnan Membrane Equilibrium. Thus the simultaneous increases in staining of some tissue components and decreases in staining of others, which occur on adding salt to the dyebaths, are often explicable in terms of the Donnan Equilibrium. The variation in staining intensity with dye charge, seen with a number of acid dyes, also agreed with the predictions of the Donnan Equilibrium. The Donnan Equilibrium was applied to understanding the mode of action of various biological staining methods requiring salt in the dyebaths; namely the Best’s Carmine glycogen stain, the Alcian Blue and Congo Red methods for amyloid, and the salty periodic acid-Schiff procedure for anionic mucosubstances.     

Deamination by the diazotization-deazotization method

Synopsis The diazotization-deazotization method for deaminating proteins in fixed tissue section, as originally described by Stoward (1963), has been investigated further with the following results. Blocking of arginine was confirmed by the Sakaguchi method and with anionic dyes. What appeared to be staining of lysine by anionic dyes was blocked but the dinitrofluorobenzene reaction was not. Blocking of histidine could not be demonstrated. Tyrosine was blocked to Millon's reagent but not to the coupled tetrazonium reaction. Staining of sulphydryl groups by Barrnett & Seligman's dihydroxydinaphthyldisulphide method was reduced but not obliterated. The colour of the reaction product between tryptophan residues and dimethylaminobenzaldehydenitrite was altered. Explanations for these findings are suggested.     

Adaptation of Mallory's Trichrome Stain to Embryonic and Fetal Material

Based upon results of an investigation of the role of phosphotungstic acid in connective tissue staining, the Mallory trichrome stain was adapted to sequential application of all three dyes, thus making it usable on embryonic and fetal material. Ten to twelve day postconception mouse fetuses were formalin fixed and paraffin embedded. Staining was as follows: (1) 1% aqueous acid fuchsin for 5 min followed by not more than 30 sec in running tap water; (2) 2% aqueous phosphomolybdic acid (PMA) for 10 min followed by a 2 min running tap water wash; (3) staining in 0.5% aniline blue in 8% acetic acid for 10 min, followed consecutively by 30 sec in running tap water, 2% aqueous PMA for 2 min, and 30 sec in running tap water; (4) 2% orange G in 8% acetic acid for 5 min, and rinsing for 30 sec in running tap water. Dehydration in ethanol, t-butanol, acetone, or by blotting followed by 1:3 terpineol-xylene, clearing in xylene and mounting, completed the procedure. The 30 sec tap water rinses can optionally be replaced by 1-2 min in 8% acetic acid. Sections can be made redder by increasing acid fuchsin staining time, or increasing time in the first PMA; red can be decreased by decreasing staining time, increasing time of the 2 min tap water wash, or decreasing time in the first PMA. Blue or orange staining can be increased or decreased by varying staining times in these solutions. Sharper differentiation may be obtained by increasing the time in PMA.     

Van Gieson's picrofuchsin. The staining mechanisms for collagen and cytoplasm,and an examination of the dye diffusion rate model of differential staining

The staining mechanism of van Gieson's picrofuchsin was studied by use of simple protein model systems and tissue sections, and by spectrophotometry and dialysis experiments. At the endpoint of the staining reaction (equilibrium) cytoplasm is yellow. Dye dilution experiments demonstrated that the highest affinity in the tissue section — picrofuchsin system is between binding sites in cytoplasmic protein and acid fuchsin. Nevertheless sections that were first stained in acid fuchsin (AcF) and then in picrofuchsin ended up with cytoplasm stained yellow. It was concluded that differences in the dye diffusion rates and differences in the permeability of tissue components cannot be invoked to explain the differential staining result. Model experiments with dissolved proteins demonstrated a positive relationship between protein concentration and uptake of picric acid (PA) from picrofuchsin. From this and experiments with additives (sodium dodecylsulphate, urea etc.) and organic solvents, it is proposed that coagulant interchain cross-linking at the high protein concentration of the cytoplasm masks potential dye-binding sites. This affects high affinity dyes with multiple binding sites more than small dyes, and so puts AcF at a disadvantage compared to PA. Staining of non-collagen proteins is mainly by hydrophobic bonding, involving ionic attractions, apolar bonds, and release of water. This mode of binding is relatively strong, decreases swelling and leads to slow dye exchange. Dye binding to collagen is mostly by hydrogen bonds, but in aqueous dye solvent nonpolar residues and charged residues may also participate. This structure remains relatively open during and after dye-binding, and the bound dye ions are therefore easily exchanged for other dye ions. Address at which the main part of the investigation was carried out     

Investigations of dye binding in the sequential staining of mucosaccharides by Alcian Yellow-Alcian Blue. 1. Histochemical experiments on different animal and human mucosaccharides

Synopsis It may be assumed that, histochemically, carboxyl groups and sulphate half-ester groups of muco electrolyte concentration of the dye baths in the two steps of a sequential Alcian Yellow-Alcian Blue method. In the present study the specificity and reliability of this method has been investigated.When the staining conditions were the same in both steps, the second dye (Alcian Blue) was found to stain mucosubstances in spite of the prior staining with Alcian Yellow. Binding of Alcian Blue was observed in all but very dilute Alcian Blue solutions. The degree of Alcian Blue binding depended on the dye concentration and staining time of the second step (Alcian Blue), and it varied widely for different mucosubstances. Although an incomplete saturation of anionic groups with dye molecules in the first step cannot be completely excluded, it is thought that Alcian Blue displaces Alcian Yellow from the carboxyl and sulphate groups of mucosubstances in tissue sections.It seems that the sequential Alcian Yellow-Alcian Blue method, under the conditions investigated, does not provide a reliable means for differentiating carboxyl and sulphate groups of mucosbstances in tissue sections simultaneously, because the second dye obviously is capable of displacing the first dye from sulphate groups. However, it is possible to distinguish non-sulphated acid mucosaccharides from sulphated mucosaccharides.     

An alternative Alcian Blue dye variant for the evaluation of fetal cartilage

BACKGROUND: The most comprehensive evaluation of vertebrate skeletal development involves the use of Alizarin Red S dye to stain ossified bone and various other dyes to stain cartilage. The dye used most widely to stain fetal cartilage in rodents and rabbits is Alcian Blue 8GX. However, the global supply of this specific dye has been exhausted. Several forms of the dye marketed as Alcian Blue 8GX are now available, although they are not synthesized via the original 8GX manufacturing process. METHODS: One new Alcian Blue 8GX form and two Alcian Blue dye variants were evaluated in rats and rabbits using standard staining procedures. The staining quality of these dyes were evaluated relative to the original form of Alcian Blue 8GX based on cartilage uptake of the dye, clarity of the cartilaginous components, staining intensity of the dye, and overall readability of the specimens under stereomicroscopic evaluation. RESULTS: Staining with the newer form of Alcian Blue 8GX resulted in poor staining quality. The Alcian Blue-Pyridine variant performed well, although staining intensity was less than optimal. The Alcian Blue-Tetrakis variant provided staining characteristics that were most similar to the original form of Alcian Blue 8GX. CONCLUSIONS: Alcian Blue-Tetrakis was markedly better in its ability to stain fetal cartilage than the newer form of Alcian Blue 8GX.     

Supravital Uptake of Cationic Dyes by Mast Cell Granules: A Light and Electron Microscope Study

Methylene blue and neutral red were selected for staining mast cell granules by supravital injections. A new technique was applied for embedding in paraffin and Araldite® without dislocation or loss of dye. Stabilization and electron microscopic identification of the dyes were achieved by transforming them into electron-dense precipitates using phosphomolybdic acid dissolved in a paraformaldehyde-glutaraldehyde mixture to preserve the ultra structure of the tissues. It was found that in general the intensity of the light microscopic staining correlated directly with the electron density. Closer study revealed that not all cytoplasmic granules exhibited the same strong affinity for the cationic dyes. Furthermore, differences in dye distribution were observed within the granules themselves. The difference in the staining pattern can be explained by the heterogeneous occurrence of the anionic residues. Because of its high sensitivity and relatively low toxicity, the method described here is well suited for detecting the binding sites of organic cations in tissues under supravital or vital conditions     

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.     

The staining of elastic fibres with Direct Blue 152. A general hypothesis for the staining of elastic fibres

Summary Elastic fibres may be stained by a number of dyes, e.g. Direct Blue 1 (C.I. 24410), Direct Blue 10 (C.I. 24340), Direct Blue 15 (C.I. 24400), Direct Blue 152 (C.I. 24366) and Direct Violet 37 (C.I. 24370). A convenient method using Direct Blue 152 has been developed which is specific for elastic fibres. The method is simple and allows the demonstration of other connective tissue fibres. Staining of elastic fibres is unimpaired by numerous blocking procedures or by changes in dyebath pH. These properties are shared by several standard elastic fibre stains.As the Direct dyes and several of the standard elastic fibre stains possess numerous aromatic rings a wide range of dyes containing varying numbers of aromatic rings were examined for ability to stain elastic fibres. No association was observed between the ability to stain elastic fibres and dye class, formal charge or the presence of hydrogen bonding groups. Staining was, however, definitely associated with the presence in the dye molecule of 5 or more aromatic rings. This suggested that van der Waals forces of attraction may be responsible for elastic fibre staining both by Direct dyes and the standard elastic fibre stains. Staining of elastic fibres as a side-effect in many procedures is similarly explicable.     

Phosphotungstic Acid-Hematoxylin; Spectropho-Tometry of the Lake in Solution and in Stained Tissue

Job's method of continuous variation (Ann. Chim., ser. 10; 9, 113-203, 1928) was applied to tungstate-hematein and molybdate-hematein lakes. For phosphotungstic acid-hematein (PTA-Hn), sodium tungstate-hematein, or molybdic acid-hematein, it demonstrates that each forms a single complex in solution, with ratios of composition (PTA to Hn) 1:2, 1:2 and 1:1 respectively. PTA-Hn was the best stain, as judged by its ability to differentiate collagenous connective tissues from muscle, and to delineate nuclear and cytoplasmic detail. Hematein is used in place of hematoxylin because a reproducible, potent staining solution can be prepared without lengthy aging periods or uncertain oxidants. With this lake, staining is independent of fixation and obviates the necessity of mordanting procedures prior to staining. Microspectrophotometric evidence indicates that the blue component of the well-recognized polychromasia of these lakes is a true example of bathochromic metachromasia. Staining by the lake at various pH values and by acid and basic dyes after PTA treatment of tissues indicate that PTA-Hn is an acid lake dye and therefore different from the iron and aluminum hematoxylin lakes. Observations on the distribution of metachromasia suggest that it is topographically related to tissue components having a high content of basic protein.     

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.     

Mucosal mast cells of the rat intestine: a re-evaluation of fixation and staining properties, with special reference to protein blocking and solubility of the granular glycosaminoglycan

Mucosal mast cells of the gastrointestinal tract constitute a separate cell line within the mast cell system of the rat, differing in several respects from the classical connective tissue mast cells and, unlike the latter, requiring special fixation techniques for their demonstration. We have examined some histochemical properties of mucosal mast cells of the duodenum and compared them with connective tissue mast cells of the tongue or skin. The results indicate that the structural integrity of the granules of both types of mast cell is partly dependent on ionic linkages between glycosaminoglycan and protein. The so far unidentified glycosaminoglycan of mucosal mast cells appears to be more soluble than the heparin of connective tissue mast cells. The strongly fluorescent binding of Berberine to the granules of connective tissue mast cells and, depending on their content, of heparin is absent from mucosal mast cells, confirming previous findings which suggested that they contain a glycosaminoglycan with a lower degree of sulphation. Aldehyde fixation by routine procedures reversibly blocks the cationic dye binding of mucosal mast cell granules. The dye binding groups may be unmasked by trypsination or by long staining times of the order of several days. The results suggest that the blocking of staining by aldehydes is caused by a diffusion barrier of a protein nature. Mucosal and connective tissue mast cells thus differ with respect to the spatial arrangement of glycosaminoglycan and protein in their granules. As a result of the study a modified method for the demonstration of mucosal mast cells in tissue sections is described, based on normal formaldehyde fixation and staining in Toluidine Blue for a long time. It has some advantages over previous methods and preserves the structure of mucosal and connective tissue mast cells equally well.     

Mechanism of connective tissue techniques I. The effect of dye concentration and staining time on anionic dye procedures

Summary Anionic dye connective tissue procedures were performed by staining for 5 min and 24 h with (a) 0.00018m and 0.0018m solutions of 28 dyes, and 0.018m solutions of 21 dyes in saturated picric acid (SPA), and (b) 0.0018m and 0.018m solutions of 20 dyes in 1% (w/v) phosphomolybdic acid (PMA). The staining obtained with dyes in SPA was classified as selective (no cytoplasmic staining), moderately selective (traces of cytoplasmic staining) and non-selective (all other staining patterns). The staining of collagen and cytoplasm with dyes in PMA was separately classified on a scale of 1–5 (1 = no staining, 5 = maximum staining). The selectivity of the staining obtained with SPA with solutions of dyes at concentrations of 0.00018m and 0.0018m, and both staining times, was correlated (p < 0.001) with an empirical sulphonic acid constant (SAC) defined as the (number of dye sulphonic acid groups/dye molecular weight) × 10³. Correlation with molecular weight was poor and was significant only when staining was performed with 0.00018m dye solutions for 24 h. The dyes were divisible into three groups: group 1 (selectivity independent, or almost independent of staining time), group 2 (selective to moderately selective when staining was performed for 5 min), and group 3 (non-selective). The SAC of the group 1 dyes differed significantly from those of the group 2 and 3 dyes. Selectivity was essentially lost at dye concentrations of 0.018m. The staining with acidic dyes (no amines or substituted amines) in PMA differed significantly (p < 0.001) from that obtained with amphoteric dyes (containing basic substituents). In general, acidic dyes stained cytoplasm. Amphoteric dyes with the exception of indigocarmine stained collagen. However, most of these dyes also stained cytoplasm. In contrast to the results obtained with dyes in SPA, selectivity correlated strongly with molecular weight and only poorly with the SAC. Staining time and dye concentration affected selectivity only when the acidic dyes were used for 5 min at concentrations of 0.0018m and 0.018m. The data obtained do not permit a clear distinction between the rate control and chemical affinity models for the mechanism of staining with anionic dyes. However, it seems possible that different groups of dyes stain by different mechanisms. Part of this work was performed by M.I., S.N., M.J. and L.M. in partial fulfilment of the requirements for the completion of Pathology 438. A partial account of this work was presented at the annual convention of the British Columbia Society of Medical Technology, Victoria, British Columbia, October 1991.     

NILE BLUE, ANILINE BLUE AND NEUTRAL RED AS INDICATORS OF LIPOLYSIS

SUMMARY: Dyes which have been used to detect lipolysis (Nile Blue, Aniline Blue and Neutral Red) and others (Methylene Blue, Toluidine Blue and Thionin) were critically examined for their inhibitory effects in both liquid and solid media. It was confirmed that Nile Blue would inhibit the Gram-positive bacteria tested, even at 2 × 10⁻⁵. Gram-negative bacteria were not inhibited at 1 × 10⁻⁴ and the colour change in fat media was good. Aniline Blue and Neutral Red did not inhibit Gram-positive organisms at 1 × 10⁻⁴ and the colour change was moderately good. The other three dyes were not toxic at 2·5 × 10⁻⁵, but there was no colour change. When butter fat saturated with the precipitated bases of Nile Blue, Basic Fuchsin, Crystal Violet or Malachite Green was incorporated in peptone-Yeastrel agar, the resulting media were toxic to Gram-positive bacteria. Fat saturated with the bases of Aniline Blue or Neutral Red permitted growth, but the colour change with lipolytic species was not striking, being one of intensity only. Satisfactory growth and colour changes were obtained using butter fat stained with the inert dye Waxolene Green in medium containing Neutral Red in the aqueous phase, and with butter fat stained with the oxazine base of Nile Blue in agar containing Aniline Blue.     

Victoria blue B--a nuclear stain for cytology. A cytophotometric study

The aim of this study was to investigate the staining characteristics of Victoria Blue B in alcohol solutions. Cytological specimens (liver and spleen tissue imprints, blood smears) were stained with methanol solutions of commercially available Victoria Blue B-Cl and with pure Victoria Blue B-BF4. The dye concentration, staining time, and protone concentration of the dye solution were varied. The dye solutions were characterized using spectrophotometry and thin-layer chromatography. Cytophotometry and image analysis were used to quantitate the staining pattern of cell nuclei. Feulgen-stained slides were used as controls. Victoria Blue B-BF4 gave excellent nuclear staining exhibiting a quantitative dye-substrate relationship, whereas commercial dyes resulted in lower staining intensity and less distinct nuclear texture. Dye concentration and staining time were, over wide ranges, not of critical importance for the quality of the staining. Under certain staining conditions, only cell nuclei were stained, with the background remaining completely unstained. We presume that, in alcohol solutions, Victoria Blue dye binds as a neutral dye molecule in conjunction with its anion. Victoria Blue B-BF4 staining provides a simple and reproducible staining technique for cytology which is suitable for use in automated cell-pattern recognition.     

Selection of a dye for use in semen transport studies in the cow

A series of experiments was carried out to select a dye and diluent that would facilitate identification of bovine inseminate in the uterus of the live cow when using hysteroscopic techniques. Of the dyes tested, Aniline Blue and the permitted food dye Green S as 1% solutions were the most suitable when added to semen with milk buffer diluent. Neither stained the uterine mucosa nor adversely affected the equipment, and both were visually distinctive during hysteroscopy. Using 1% concentrations of these dyes, sperm motility scores were acceptable before and after slow and fast freezing processes.     

Modified Whipf's Polychrome: A Connective Tissue Stain with Special Application for Demonstrating Leishmania

A polychrome stain procedure was developed to demonstrate amastigotes of the protozoan parasite Leishmania braziliensis as well as cytoplasmic and other tissue components in cutaneous lesions of infected animals. The procedure is as follows: stain nuclei for 10 minutes with an iron hematoxylin containing 0.5% hematoxylin and 0.75% ferric ammonium sulfate dissolved in 1:1 0.6 N H₂SO₄:95% ethanol; rinse 4 minutes in distilled water. Cytoplasmic staining is achieved by exposing tissues for 10 minutes to a solution containing 0.25% Biebrich scarlet, 0.45% orange G, 0.5% phosphomolybdic acid and 0.5% phosphotungstic acid in 1% aqueous acetic acid. These first two solutions are modified from Whipf's polychrome stain. Sections are differentiated for 10 seconds in 50% ethanol, rinsed in water, stained 3 minutes in 0.1% aniline blue WS in saturated aqueous picric acid, rinsed in water and differentiated for 1 minute in absolute ethanol containing 0.05% acetic acid. Mordanting overnight in 6% picric acid in 95% ethanol produced optimal results.

This procedure was applied to sectioned material from experimental animals with various protozoa. Trypanosoma cruzi, Besnoitia Jellisoni, Toxoplasma gondii and especially Leishmania braziliensis were well demonstrated. Combining cytoplasmic dyes and phosphomolybdic-phosphotungstic acids into one solution afforded differential staining of tissues by Biebrich scarlet and orange G; connective tissues were stained by this solution. Substantially improved definition of connective tissues resulted after counterstaining. This procedure differs from the Massou sequence in which connective tissues are first stained by cytoplasmic dyes along with other tissues and then destained prior to specific counter-staining. in comparing dyes structurally related to Biebrich scarlet, it was found that Crocein scarlet MOO, but not Poncenu S, was an acceptable substitute. Sirius supra blue GL and Sirius red FSBA were not useful as replacements for aniline blue WS in this procedure.     

Staining Paraffin Sections Without Prior Removal of the Wax

Paraffin sections are usually rehydrated before staining. It is possible to apply aqueous dye solutions without first removing the wax. Staining then occurs more slowly, and only if the embedding medium has not melted or become unduly soft after catting. To avoid this problem, sections are flattened on water no hotter than 45 C and dried overnight at 40 C. Minor technical modifications to the staining procedures are needed. Mercury deposits are removed by iodine, and a 3% solution of sodium thiosnlfate in 60% ethanol is used to remove the iodine from paraffin sections. At room temperature, progressive staining takes 10-20 tunes longer for sections in paraffin than for hydrated sections; at 45 C, this can be shortened to about three times the regular staining time. After staining, the slides are rinsed in water, air dried, dewaxed with xylene, and coverslipped in the usual way. Nuclear staining in the presence of wax was achieved with toluidine blue, O, alum-hematoxylin and Weigert's iron-hematoxylin. Eosin and van Gieson's picric acid-acid fuchsine were effective anionic counterstains. A one-step trichrome mixture containing 3 anionic dyes and phosphomolybdic acid was unsuitable for sections in wax because it Imparted colors that were nninformative and quite different from those obtained with hydrated sections. Advantages of staining in the presence of wax include economy of solvents, reduced risk of overstaining and strong adhesion of sections to slides.