Orcein, collastin and pseudo-elastica: a re-investigation of Unna's concepts.

Orcein has been recommended for identification of elastin. Since other traditional elastica stains proved to be unspecific, it was deemed of interest to determine the selectivity of orcein and to review pertinent literature. Orcein was employed as a textile dye in ancient Egypt and was used for dyeing of wool and silk until the early 20th century. It was introduced into histological technic in 1878 as a stain for cytoplasm. Unna recommended it for demonstration of elastic tissue in 1890 and retracted claims for its specifity in 1894 because orcein colored also certain collagen fibers. Unna suggested the term collastin for collagen fibers which share the affinity of elastin for acid orcein. Other orcein solutions were used as selective stains for collagen. In histochemical studies, the staining properties of resorcin-fuchsin and orcein were very similar; elastin and various collagen fibers were strongly colored. Unna's collastin is apparently identical with the pseudo-elastica described in sections stained with resorcin-fuchsin. Both dyes react with meshworks of fine fibers, embryonic, experimentally or pathologically altered collagens. It is suggested to use the term collastin, instead of pseudo-elastica, for collagenous fibers which bind the traditional elastica stains.     

Orcein,collastin and pseudo-elastica: a re-investigation of Unna's concepts

Summary Orcein has been recommended for identification of elastin. Since other traditional elastica stains proved to be unspecific, it was deemed of interest to determine the selectivity of orcein and to review pertinent literature.Orcein was employed as a textile dye in ancient Egypt and was used for dyeing of wool and silk until the early 20th century. It was introduced into histological technic in 1878 as a stain for cytoplasm. Unna recommended it for demonstration of elastic tissue in 1890 and retracted claims for its specifity in 1894 because orcein colored also certain collagen fibers. Unna suggested the term collastin for collagen fibers which share the affinity of elastin for acid orcein. Other orcein solutions were used as selective stains for collagen.In histochemical studies, the staining properties of resorcin-fuchsin and orcein were very similar; elastin and various collagen fibers were strongly colored. Unna's collastin is apparently identical with the pseudo-elastica described in sections stained with resorcin-fuchsin. Both dyes react with meshworks of fine fibers, embryonic, experimentally or pathologically altered collagens. It is suggested to use the term collastin, instead of pseudo-elastica, for collagenous fibers which bind the traditional elastica stains.     

On the mechanism of Verhoeff's elastica stain: a convenient stain for myelin sheaths.

Verhoeff (1908) recommended an iron-hematein formula containing Lugol's solution for demonstration of elastic tissue; sections are differentiated until desired staining patterns are obtained. Verhoeff's stain colored a variety of tissue structures and showed higher substantivity for myelin sheaths than for elastin. Addition of HCL or omission of Lugol's solution decreased or abolished coloration of pseudo-elastica and thus enhanced selectivity for elastin. Substitution of Fe++ for Fe+++ abolished dye binding by elastin. A review of chemical data indicated interaction of components of Lugol's solution with the dye. Hematein and Fe+++ form a variety of cationic, anionic and non-ionic chelates; the ratio of these compounds changes with time. Dye binding apparently occurs mainly via van der Waals forces and hydrogen bonds. Verhoeff's elastica stain is definitely not specific for elastin and is inferior to orcein and resorcin-fuchsin because of the required differentiation with its inherent bias to produce patterns which conform to expectations. However, Verhoeff's elastica stain is far superior to other metal-hematein technics for myelin sheaths. The combined Verhoeff-picro-Sirius Red F3BA stain can be performed in 30 min and does not require differentiation. It is therefore suggested to reclassify Verhoeff's elastica stain as a method for myelin sheaths.     

Basic Fuchsin-Ferric Chloride: a Simplification of Weigert's Resorcin-Fuchsin Stain for Elastic Fibres

Weigert's resorcin-fuchsin stain for elastic fibres can be simplified by the omission of the resorcinol. The resulting “basic fuchsin-ferric chloride” gives results indistinguishable from those achieved with resorcin-fuchsin on tissues fixed in Bouin, Carnoy, Gendre, neutral formah, Susa or Zenker solutions. Gel filtration chroma tography on Sephadex LH20 showed that the staining components of basic fuchsin-ferric chloride had a high molecular weight, so selective staining of elastic fibres by this method may well be due to van der Waals attractions.     

A simple polychrome stain for conventionally fixed Epon-embedded tissues.

The described technique, based upon a one-step Mallory-Heidenhain stain, can be applied as a routine stain for glutaraldehyde or OsO4 fixed, Epon embedded tissues of various organs. The technique consists of a short treatment of the sections with H2O2, a nuclear staining with celestine blue B and a final staining in a modified Cason's solution. The different tissue and cell components are displayed as follows: dark brown nuclei, yellow cytoplasm, red collagen fibers and blue elastic fibers. Intracytoplasmic components as glycogen and mucus are stained respectively blue and violet, whereas other inclusions such as leucocyte granules are colored orange to red.     

On the mechanism of Verhoeff's elastica stain: A convenient stain for myelin sheaths

Summary Verhoeff (1908) recommended an iron-hematein formula containing Lugol's solution for demonstration of elastic tissue; sections are differentiated until desired staining patterns are obtained. Verhoeff's stain colored a variety of tissue structures and showed higher substantivity for myelin sheaths than for elastin. Addition of HCL or omission of Lugol's solution decreased or abolished coloration of pseudo-elastica and thus enhanced selectivity for elastin. Substitution of Fe⁺⁺ for Fe⁺⁺⁺ abolished dye binding by elastin.A review of chemical data indicated interaction of components of Lugol's solution with the dye. Hematein and Fe⁺⁺⁺ form a variety of cationic, anionic and non-ionic chelates; the ratio of these compounds changes with time. Dye binding apparently occurs mainly via van der Waals forces and hydrogen bonds.Verhoeff's elastica stain is definitely not specific for elastin and is inferior to orcein and resorcin-fuchsin because of the required differentiation with its inherent bias to produce patterns which conform to expectations. However, Verhoeff's elastica stain is far superior to other metal-hematein technics for myelin sheaths. The combined Verhoeff-picro-Sirius Red F3BA stain can be performed in 30 min and does not require differentiation. It is therefore suggested to reclassify Verhoeff's elastica stain as a method for myelin sheaths.     

Light microscopic distinction between elastin,pseudo-elastica (type III collagen?) and interstitial collagen

Summary Distinction between elastin and collagen in arteriosclerotic lesions is difficult because the so-called elastica stains are bound also by collagen fibers which resemble collagen of premature infants. Investigations of effects of organic solvents on dye binding led to the development of methods for selective demonstration of pseudo-elastica, and for simultaneous visualization of elastin and pseudo-elastica in contrasting colors.Paraffin sections of human autopsy material were stained with solutions of resorcin-fuchsin, orcein or aldehyde fuchsin in absolute ethanol. In other series, sections pretreated with this resorcin-fuchsin solution were counter-stained with tannic acid-phosphomolybdic acid (TP)-dye technics.Solutions of these elastica stains in absolute ethanol colored only pseudo-elastica; elastin, e.g. elastic membranes of aorta, remained unstained. In sections counterstained with TP-dye technics elastin was colored red; pseudo-elastica retained the purplish blue coloration imparted by resorcinfuchsin. Other collagens were stained yellow.A review of the literature showed that until the 1920's elastin was classified as a gelatinoid of the collagen group. Elastic fibers were identified by mechanical properties, not a particular chemical composition. Hence, the elastic fibers of classical histology cannot be equated with the elastin of modern chemistry. Correlation of histochemical observations with chemical data indicates that the collagenous pseudo-elastica corresponds to [1(III)]₃ collagen.     

Specific Staining of Glycogen with Haematoxylin and Certain Anthraquinone Dyes

Specific staining of glycogen in rat liver fixed in chilled 80% alcohol, chilled formol alcohol or 10% neutral formalin has been accomplished with acid alizarin blue SWR, alizarin brilliant blue BS, alizarin red S, gallein, haematein, and haematoxylin solutions. TO prepare a staining solution, 1 gm dye, 1 gm K₂CO₃ and 5 gm KCl were dissolved by heating in 60 ml of water. Concentrated NH₄OH (0.880 sp.gr.), 15 ml, followed by 15 ml of dry methanol were added to 20 ml of the cooled solution. Paraffi sections were stained for 5 min, rinsed in dry methanol, cleared in xylene, and mounted in D.P.X. The high specificity obviated the need for counterstaining: nuclei and cytoplasm were unstained. Precipitation of stain onto the slide was rare. As all the dyes carried, like carminic acid, numerous groups capable of forming hydrogen bonds, it is suggested that the staining mechanism involved hydrogen bonding.     

A Selective Stain for Renal Basement Membranes

Paraffin sections from human kidneys fixed in Carnoy's fluid No. 2 were treated consecutively with periodic acid-sodium bisulfite and stained with resorcin-fuchsin. Basement membranes were colored black in cross sections, dark gray in tangential sections. Cytoplasm, nuclei, reticulin and collagen fibers remained unstained or were only lightly colored, depending on duration of fixation. Elastic fibers were colored black. In sections counterstained with Kernechtrot, the sharp black coloration of basement membranes and the pink staining of nuclei facilitated the study of glomerular lesions. After counterstaining with Van Gieson's picro-fuchsin, the black basement membranes contrasted well with the red reticulin and collagen fibers. Because this method does not require differentiation, it gave uniform results in the hands of different users. No fading was observed in section stored for 3 yr.     

The Peracetic-Orcein-Halmi Stain: A Stain for Connective Tissues

A selective stain useful for the study of connective tissues is described. The stain demonstrates elastic and oxytalan fibers as well as fibrils in mucous connective tissues previously undescribed. Reticular fibers are not stained. The stain may be used on sections that have been fresh frozen or fixed in formalin or ethanol. Sections are deparaffinized, washed in absolute ethanol, oxidized in peracetic acid 30 min, washed in running water, stained in Taenzer-Unna orcein 15 min, 37°C, differentiated in 70% ethanol, washed in running water, stained in Lillie-Mayer alum hematoxylin 4 min, blued in running water, and counterstained 20 sec in a modified Halmi mixture of 100 ml distilled water, 0.2 gm light green SF, 1.0 gm orange G, 0.5 gm phosphotungstic acid and 1.0 ml glacial acetic acid. Sections are rinsed briefly in 0.2% acetic acid in 95% ethanol, dehydrated and mounted.     

A Tribasic Stain for Thin Sections of Plastic-Embedded, OsO4-Fixed Tissues

Thin (0.5-1 μ) sections of plastic-embedded, OsO₄-fixed tissues were attached to glass slides by heating to 70 C for 1 min. A saturated solution combining toluidine blue and malachite green was prepared in ethanol (8% of each dye) or water (4% of each dye). Methacrylate or epoxy sections were stained in the ethanol solution for 2-5 min. The water solution was more effective for some epoxy sections (10-80 min). Epoxy sections could be mordanted by 2% KMnO₄, in acetone (1 min) before use of the aqueous dye, reducing staining time to 5-10 min and improving contrast. Aqueous basic fuchsin (4%) was used as the counter-stain in all cases; staining time varied from 1-30 min depending upon the embedding medium and desired effects, methacrylate sections requiring the least time. In the completed stain, nuclei were blue to violet; erythrocytes and mitochondria, green; collagen and elastic tissue, magenta; and much and cartilage, bright cherry red. Sections were coated with an acrylic resin spray and examined or photographed with an oil-immersion lens.     

The Application of Miller's Elastic Stain to Glycol Methacrylate Tissue Sections

The application of Miller's dilute elastic stain followed sequentially by Gill's III hematoxylin and a fast green counterstain produced a reliable and consistent method for differentially staining elastic fibers, nuclei, muscle and collagen in glycol methacrylate tissue sections. Evaluation of different methods of fixation and conditions of staining on animal tissue sections showed that elastic fibers in both perfusion and immersion fixed tissues can be intensely stained. The stability of Miller's elastic stain offers the potential of a commercially available histological stain reagent for coarse and fine elastic fibers in glycol methacrylate tissue sections.     

The application of Miller's elastic stain to glycol methacrylate tissue sections

The application of Miller's dilute elastic stain followed sequentially by Gill's III hematoxylin and a fast green counterstain produced a reliable and consistent method for differentially staining elastic fibers, nuclei, muscle and collagen in glycol methacrylate tissue sections. Evaluation of different methods of fixation and conditions of staining on animal tissue sections showed that elastic fibers in both perfusion and immersion fixed tissues can be intensely stained. The stability of Miller's elastic stain offers the potential of a commercially available histological stain reagent for coarse and fine elastic fibers in glycol methacrylate tissue sections.     

Acceleration of the Movat Pentachrome One Stain by Heat

The conventional staining time for Movat's pentachrome I stain (Arch. Path., 60: 289-295, 1955) was shortened from about 18-19 hr to about 2.5 hr. The ammoniated alcohol and the resorcin-fuchsin staining baths were heated to 56 C. All other steps in the technic were performed at 25-27 C. Staining properties of paraffin sections of many types of tissue fixed in formalin, formol-sublimate-acetic, or in Bouin's fluid, showed that staining with resorcin-fuchsin at the elevated temperature gave the same results as staining at room temperature.     

A Versatile Stain for Pollen Fungi, Yeast and Bacteria

A versatile stain has been developed for demonstrating pollen, fungal hyphae and spores, bacteria and yeasts. The mixture is made by compounding in the following order: ethanol, 20 ml; 1% malachite green in 95% ethanol, 2 ml; distilled water, 50 ml; glycerol, 40 ml; acid fuchsin 1% in distilled water, 10 ml; phenol, 5 g and lactic acid, 1-6 ml. A solution has also been formulated to destain overstained pollen mounts. Ideally, aborted pollen grains are stained green and nonaborted ones crimson red. Fungal hyphae and spores take a bluish purple color and host tissues green. Fungi, bacteria and yeasts are stained purple to red. The concentration of lactic acid in the stain mixture plays an important role in the differential staining of pollen. For staining fungi, bacteria and yeasts, the stain has to be acidic, but its concentration is not critical except for bacteria. In the case of pollen, staining can be done in a drop of stain on a slide or in a few drops of stain in a vial. Pollen stained in the vial can be used immediately or stored for later use. Staining is hastened by lightly flaming the slides or by storing at 55±2 C for 24 hr. Bacteria and yeasts are fixed on the slide in the usual manner and then stained. The stock solution is durable, the staining mixture is very stable and the color of the mounted specimens does not fade on prolonged storage. Slides are semipermanent and it is not necessary to ring the coverslip provided 1-2 drops of stain are added if air bubbles appear below the coverslip. The use of differentially stained pollen mounts in image analyzers for automatic counting and recording of aborted and nonaborted pollen is also discussed.     

A Simple Polychrome Stain for Conventionally Fixed Epon-Embedded Tissues

The described technique, based upon a one-step Mallory-Heidenhain stain, can be applied as a routine stain for glutaraldehyde or OsO₄ fixed, Epon embedded tissues of various organs. The technique consists of a short treatment of the sections with H₂O₂, a nuclear staining with celestine blue B and a final staining in a modified Cason's solution. The different tissue and cell components are displayed as follows: dark brown nuclei, yellow cytoplasm, red collagen fibers and blue elastic' fibers. Intra cytoplasmic components as glycogen and mucus are stained respectively blue and violet, whereas other inclusions such as leucocyte granules are colored orange to red.     

A Department Devoted to Abstracts of Books and Papers from Other Journals Dealing With Stains and Microscopic Technic in General

TO enable staining of insoluble calcium salts with glyoxal bis(2-hydroxyanil) (GBHA), the original solution containing 2 ml of 0.4% GBHA in absolute ethanol, and 0.3 ml of aqueous 5% NaOH, and limited to staining only soluble calcium salts, was modified as follows: 1, 2 ml of 0.4% GBHA in absolute ethanol in 0.6 ml of 10% aqueous NaOH; 11, 0.1 gm GBHA in 2 ml of 3.4% NaOH in 75% ethanol. To prevent diffusion and loss of calcium, the tissues were processed by the freeze-substitution or freeze-dry method and sections stained without removing the paraffin. Modification I is effective only when 1 or 2 drops placed on the section are evaporated gradually to dryness, concentrating the GBHA and NaOH on the insoluble calcium salts. Modification II is effective when dried or poured on the the section and allowed to stain for 5 min. The stained slides are immersed for 15 min in 90% ethanol saturated with KCN and Na₂CO₃ for specificity to calcium; rinsed and counterstained in 95% ethanol containing 0.1% each of fast green FCF and methylene blue; rinsed and dehydrated in ethanol; deparaffinized and cleared in xylene; and mounted in neutral synthetic resin. Although the modified methods tested on models failed to stain reagent grade CaCO₃ and Ca₃(PO₄)₂ crystals completely, apatite in developing vertebrae and calcified plaques in soft tissues were stained intensely red. The distribution of gross deposits of insoluble calcium salt in tissue sections corresponded with that shown in adjacent sections by the alizarin red S, ferrocyanide, and von Kossa methods. The modified GBHA method revealed smaller quantities of insoluble as well as soluble calcium salts discretely within cells where the other methods failed; also, calcium in cytoplasm of hypertrophied cartilage cells of developing vertebrae, and in cytoplasm of renal tubular cells of magnesium-deficient rats, not described previously, was demonstrated.     

A Modified Verhoeff-Van Gieson Elastin Histochemical Stain to Enable Pulmonary Arterial Hypertension Model Characterization

Optimal histochemical staining is critical to ensure excellent quality stained sections to enable light microscopic and histomorphometric image analysis. Verhoeff-van Gieson is the most widely used histochemical stain for the visualization of vascular elastic fibers. However, it is notoriously difficult to differentiate fine elastic fibers of small vasculature to enable histomorphometric image analysis, especially in organs such as the lung. A tissue fixation procedure of 10% neutral buffered formalin with subsequent fixation in 70% ethanol further compounds the problem of small vessel staining and identification. Therefore, a modified Verhoeff’s elastin stain was developed as a reliable method to optimally highlight the internal and external elastic laminae of small arteries (50-100 µm external diameter) and intra-acinar vessels (10-50 µm external diameter) in 3 µm thick lung tissue sections from models of pulmonary arterial hypertension. This modified Verhoeff’s elastin stain demonstrated well-defined staining of fine elastic fibers of pulmonary blood vessels enabling subsequent histomorphometric image analysis of vessel wall thickness in small arteries and intra-acinar vessels. In conclusion, modification of the standard Verhoeff-van Gieson histochemical stain is needed to visualize small caliber vessels’ elastic fibers especially in tissues fixed in 10% neutral buffered formalin followed by additional fixation in 70% ethanol.Key words: Histochemical stain, histomorphology, lung, Verhoeff-van Gieson, elastin     

The Glyoxal BIS(2-Hydroxyanil) Method Modified for Localizing Insoluble Calcium Salts

TO enable staining of insoluble calcium salts with glyoxal bis(2-hydroxyanil) (GBHA), the original solution containing 2 ml of 0.4% GBHA in absolute ethanol, and 0.3 ml of aqueous 5% NaOH, and limited to staining only soluble calcium salts, was modified as follows: 1, 2 ml of 0.4% GBHA in absolute ethanol in 0.6 ml of 10% aqueous NaOH; 11, 0.1 gm GBHA in 2 ml of 3.4% NaOH in 75% ethanol. To prevent diffusion and loss of calcium, the tissues were processed by the freeze-substitution or freeze-dry method and sections stained without removing the paraffin. Modification I is effective only when 1 or 2 drops placed on the section are evaporated gradually to dryness, concentrating the GBHA and NaOH on the insoluble calcium salts. Modification II is effective when dried or poured on the the section and allowed to stain for 5 min. The stained slides are immersed for 15 min in 90% ethanol saturated with KCN and Na₂CO₃ for specificity to calcium; rinsed and counterstained in 95% ethanol containing 0.1% each of fast green FCF and methylene blue; rinsed and dehydrated in ethanol; deparaffinized and cleared in xylene; and mounted in neutral synthetic resin. Although the modified methods tested on models failed to stain reagent grade CaCO₃ and Ca₃(PO₄)₂ crystals completely, apatite in developing vertebrae and calcified plaques in soft tissues were stained intensely red. The distribution of gross deposits of insoluble calcium salt in tissue sections corresponded with that shown in adjacent sections by the alizarin red S, ferrocyanide, and von Kossa methods. The modified GBHA method revealed smaller quantities of insoluble as well as soluble calcium salts discretely within cells where the other methods failed; also, calcium in cytoplasm of hypertrophied cartilage cells of developing vertebrae, and in cytoplasm of renal tubular cells of magnesium-deficient rats, not described previously, was demonstrated.     

Papanicolaou stain: Is it economical to switch to rapid, economical, acetic acid, papanicolaou stain?

OBJECTIVE: To standardize an inexpensive and rapid Papanicolaou staining technique with limited ethanol usage. STUDY DESIGN: Smears from 200 patients were collected (2 per patient) and fixed in methanol. Half were subjected to conventional Papanicolaou and half to stain ing with rapid, economical, acetic acid Papanicolaou (REAP) stain. In REAP, pre-OG6 and post-OG6 and post-EA36 ethanol baths were replaced by 1% acetic acid and Scott's tap water with tap water. Hematoxylin was preheated to 60 degrees C. Final dehydration was with methanol. REAP smears were compared with Papanicolaou smears for optimal cytoplasmic and nuclear staining, stain preservation, cost and turnaround time. RESULTS: With the REAP method, cytoplasmic and nuclear staining was optimal in 181 and 192 cases, respectively. The staining time was considerably reduced, to 3 minutes, and the cost per smear was reduced to one fourth. The staining quality remained good in all the smears for > 2 years. CONCLUSION: REAP is a rapid, cost-effective alternative to Papanicolaou stain. Though low stain penetration in large cell clusters is a limitation, final interpretation was not compromised.