A Hematoxylin and Eosin-Like Stain for Glycol Methacrylate Embedded Tissue Sections

A staining procedure is described for use with glycol methacrylate embedded tissue sections which does not stain the plastic embedment or remove the sections from the glass slides. The basic dye is celestine blue B. It is prepared by treating 1 g of the dye with 0.5 ml concentrated sulfuric acid. It is then dissolved with the following solution. Add 14 ml glycerine to 100 ml 2.5 percent ferric ammonium sulfate and warm the solution to 50 C. Finally adjust the pH to 0.8 to 0.9 The acid staining solution consists of 0.075 percent ponceau de xylidine and 0.025 percent acid fuchsin in 10 percent acetic acid. Slides containing the dried plastic sections are immersed in the celestine blue solution for five minutes and in the ponceau-fuchsin solution for ten minutes with an intervening water rinse. After a final wash, the sections are air dried and coverslipped. This staining procedure colors the tissues nearly the same as hematoxylin and eosin procedures.     

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.     

A New Method for Flat Embedding in Glycol Methacrylate

Glycol methacrylate (GMA) is a useful polymer for embedding tissue because of its stability, hydrophilic properties, and resistance to many solvents (Feder a d O'Brien 1968, Bennett et a/. 1976). Undue solvent extraction is also avoided as GMA contains water, making complete dehydration unnecessary (Cole and Sykes 1974). This property shows some evidence that GMA embedded sections may be useful in energy dispersive analysis by X-ray for some elements (DeNee et al. 1977). GMA also does not exclude water soluble dye molecules and has thus become a useful medium for histochemical studies (Bennett et al. 1976).     

An Improved Hematoxylin-Eosin Stain for Sections of Marrow Units

The procedure recommended is: Fix “marrow units” (small functional structures of bone marrow) in 10% formol-saline solution for 1-2 hours and dehydrate in 80% alcohol, 95% alcohol and acetone 30 minutes each. Place in fresh 50° and 53°C. paraffin for 30 minutes each. Embed in fresh 53°C. paraffin. Serially section at 5μ thickness and mount with Schleicher's floating solution. Allow to dry for 1 hour in an oven and deparaffinize by passing through xylene I and II, absolute alcohol I and II, and 95% alcohol. Rinse in fresh distilled water and place in dilute Harris' hematoxylin (stock solution 50 ml., distilled water 200 ml.) for 2 to 3 minutes. Rinse well in distilled water and check staining under the microscope. Dip in acid-alcohol 5 times (1 dip to equal about 1 second). Rinse well in weak (0.02%) ammonia water and distilled water. Dip in 2% aqueous phosphotungstic acid about 3 to 5 times (equal to 3-5 seconds). Rinse in fresh distilled water and place in weak ammonia water for 1 minute. Rinse in fresh distilled water I and II. Place in 80% alcohol for 5 minutes and check under the microscope for “blueness” and nuclear differentiation. Place in dilute alcoholic eosin (0.5% alcohol-eosin stock solution 10 parts and 95% alcohol 90 parts) for 1 to 2 minutes. Rinse in 80% alcohol and place for 1 minute in 95% alcohol. Check under the microscope for staining quality. Place in absolute alcohol for 1 minute, alcohol-xylene (equal parts), 10 dips, and xylene I and II. Mount. This hematoxylin-eosin staining schedule brings out minute structural detail of bone marrow tissue heretofore not demonstrable.     

Glycol Methacrylate Sections of the Crystalline Lens

Sections of the crystalline lens are difficult to prepare because of the hardness of the fixed lens. After paraffin procedures the lens shatters and cracks when cut because the reagents and high temperatures used for infiltration further harden it. Plastic has been successfully used as an embedding medium for other difficult tissues. It allows prolonged infiltration times at room temperature, and provides a firm matrix for tissues containing areas of varying density. However, standard procedures for embedding tissue in plastic do not allow for complete infiltration of the crystalline lens. The purpose of this report is to describe a modification of the glycol methacrylate embedding technique which ensures complete infiltration of the lens. The following protocol was found to produce consistently good 1-5 μm sections of lenses from 10-2O-day-old rats.     

Glycol Methacrylate Sections of Frozen-Dried Tissues for Histofluorescence

Paraformaldehyde-induced fluorescence in frozen-dried tissues survives embedding in glycol methacrylate. After freeze-drying and treatment with paraformaldehyde vapor, tissues to be examined by this technique are immersed in glycol methacrylate and placed in a dessicator which is then evacuated. They are usually left overnight in the dark; next day, the polymerizer is added and the tissues are again left overnight in the dark in the evacuated dessicator; for smaller blocks or certain tissues, these times can be shortened. The blocks are cut on a JB-4 microtome. Sections of 1-10μ can be made readily with a dry glass knife according to standard procedures.     

Alcian Blue Method for Attaching Glycol Methacrylate Bone Marrow Sections to Glass Slides

Detachment of glycol methacrylate sections from glass slides is a common problem during histochemical and immunohistochemical procedures, particularly when large or hard tissue sections are stained and when using caustic solutions, alcohols, or proteases.     

Glycol Methacrylate in Light Microscopy a Routine Method for Embedding and Sectioning Animal Tissues

Glycol methacrylate (GMA), a water and ethanol miscible plastic, was introduced to histology as an embedding medium for electron microscopy. This medium may be made soft enough for cutting thick sections for routine light microscopy by altering its composition. A procedure for the infiltration, polymerization, and sectioning of animal tissues in GMA for light microscopy is presented which is no more complex than paraffin techniques and which has a number of advantages: (I) The GMA medium is compatible with both aqueous fixatives (formaldehyde, glutaraldehyde, Bouin's, and Zenker's) and non-aqueous fixatixes (Carnoy's, Newcomer's, ethanol, and acetone). (2) Undue solvent extraction of the tissue is avoided because adequate dehydration occurs during infiltration of the embedding medium. Separate dehydration and clearing of the tissue prior to embedding is eliminated. (3) When polymerized, the supporting matrix is firm enough that hard and soft tissues adjacent to one another may be sectioned without distortion. (4) Thermal artifact is reduced to a minimum during polymerization because the temperature of the tissue may be maintained at 0-4 C from fixation through ultraviolet light polymerization of the embedding medium. (5) Shrinkage during polymerization of the embedding medium is minimized by prepolymerization of the medium before use. (6) Sections may be easily cut using conventional steel knives and rotary microtomes at a thickness of 0.5 to 3.0 microns, thus improving resolution compared with routinely thicker paraffin sections. (7) The polymerized GMA medium is porous enough so that staining, auto radiography, and other histological procedure are done without removal of the embedding medium from the sections. A list of these stains and related procedures are included. (8) Enzyme digestion of ultra thin sections of tissue embedded in GMA is common in electron microscopic cyto chemistry. me same digestion techniques appear compatible with the thicker seaions used in light microscopy.     

Improved Stability of A Purified Glycol Methacrylate Preparation: Comments

The technical note from Bernier et al. (1984) presents additional observations on our procedure for purifying glycol methacrylate (GMA), a hydrophylic resin (Chappard et al. 1982). It is becoming increasingly popular and widely used as an embedding medium for light microscopic studies. GMA is prepared by esterification of methacrylic acid (MA), but about 1% of free unreacted MA remains in the monomer. MA can copolymerize with GMA and it also binds strongly to thiazin and other basic dyes (Tipett and O'Brien 1975) so as an undesirable impurity it must be removed.     

Assessment of Demyelination in Glycol Methacrylate Sections: A New Protocol for Cresyl Fast Violet Staining

A simple staining technique for nervous tissue is described. Tissue perfused with glutaraldehyde and formaldehyde and postfixed with osmium tetroxide is embedded in glycol methacrylate. One-micrometer sections are stained with 0.05% cresyl fast violet aqueous solution at 60 C for 5 min, washed with tap water and air dried. With this method the details of all nervous tissue elements are clearly demonstrated. The technique is particularly useful for assessing demyelination because the staining of axoplasm allows demyelinated axons to be well visualized.     

A Method for Removing Stain Precipitate and Destaining Sections

Subjecting electron microscope sections to NaOH treatment removes stain precipitate from the section surface. The alkali treatment also extracts stain from the tissue itself. Following this treatment, sections can be restained to obtain clean images. Alternatively, after being viewed or photographed using one stain and then destained, the same sections can be treated with a different stain to obtain additional histochemical information.     

Rapid Removal of Acid from Glycol Methacrylate for Improved Histological Embedding

A method for the rapid and complete removal of methacrylic acid from commercial samples of glycol methacrylate is presented. It entails conversion of the acid to an insoluble N-acylurea by treatment with an equivalent amount of N, N'-dicyclohexylcarbodiimide. Sections of tissue embedded in polymer prepared from the purified monomer can be stained with basic dyes without simultaneously staining the polymer.     

Further Experimentation with A New Differential Staining Method for Connective Tissue Combined with the Ordinary Hematoxylin-Eosin Stain

There appeared recently in the University of Oklahoma Bulletin an article by Jos. M. Thuringer¹ describing a new differential staining method for connective tissue. Dr. W. J. Baumgartner suggested to the writer that she undertake to stain a series of sections using the method described by Mr. Thuringer. We wished especially to test this method in order to determine if it could be introduced into the course in technic as one of the routine stains for connective tissue.     

A Simple Stain for Myelin in Frozen Sections: A Modification of Mahon's Method

A simple and rapid method for demonstrating myelinated nerve fibers in frozen sections of the central and peripheral nervous system is described. Material fixed by perfusion with mixed aldehydes gives the best results but the method also works on specimens fixed by immersion in formaldehyde. Frozen sections varying in thickness from 15-50 μm are mounted on slides subbed with chrome alum-gelatin. After hydration (60-140 min), Sections are mordanted (20-40 min) in 2.5% iron alum and rinsed briefly in three changes of distilled H₂O (total 2 min). Staining is for 60-180 min in 40 cc freshly made 10% alcoholic hematoxylin diluted with 165 cc distilled H₂O to which 15 cc saturated Li₂CO₂is added. the sections are washed in distilled H₂O (5-15 min) and dehydrated in graded alcohols without differentiation in mordant, and covered. Myelin stains a dark blue-purple against a light grey background. Fiber tracts, as well as individual myelinated fibers, are clearly demonstrated.     

A Glycol Methacrylate Method for the Routine Histologic Evaluation of Rat Inner Ear

A method has been developed for the histologic evaluation of rat inner ear using glycol methacrylate (GMA) and steel knife sectioning. The necropsy, fixation, and histologic techniques described are not so complex and difficult as to preclude their routine use. The method is particularly useful in studies in which the entire inner ear of a large number of animals must be evaluated histologically.     

The Combined Gram-Pappenheim Stain as Modified for Films and Paraffin Sections

A combination of the Gram-Pappenheim stains for the examination of gonorrheal pus, cellular exudate and paraffin sections of formalin-fixed tissues has been described elsewhere (Scudder and Lisa, 1931). The crystal violet solution was made stable for the first time by employing phosphate buffers on the acid side of neutrality, and a stable counterstain was prepared for the first time from National Aniline dyes, ethylated methyl green and pyronin yellowish. Original findings were demonstrated by means of color plate I and II (Scudder, 1931) to show gonococci, pneumococci and cells in smears, and formalin-fixed tissue brought down to water in the usual way. A new color plate is published herewith to show the microscopic appearance of cells, Gram-positive and Gram-negative bacteria, higher bacteria, fungi and spermatozoa in the study of genitourinary and gynecological cases. The method has a value in the field of medical jurisprudence. Crystals were well demonstrated, especially those resulting from sulfa drug therapy. The National Aniline methyl green batches numbered NG 10, 11, 13 to 19, and their batches of pyronin numbered NP 5 to 10 were found consistently stable. Earlier dyes were found either too purple or too blue for the technic and the most satisfactory dyes were found to require a ripening time of several days and could be prepared in amounts of from 1 to 4 liters and stored indefinitely without preservatives.     

An Improved Method for Embedding Hard Tissue in Poeymethyl Methacrylate

An improved routine method for embedding tissue, especially hard tissue, in poly-methyl methacrylate (pMMA) is described. The improvements were: the final dehydration step before MMA infiltration was performed with methanol in a Soxhlet apparatus; the stabilizer hydroquinone was not extracted from the monomer (MMA), and more important, the commonly used polymerization initiator, benzoyl peroxide (bpo), was replaced by the initiator, bis (4-tert-butylcyclohexyl)peroxydicarbonate (bbpd). Bbpd is preferred to bpo because it is not explosive, far less is needed and it has a suitable half life. Moreover, bbpd, as obtained from the manufacturer, needs no further purification, in contrast to bpo. Temperatures during bbpd initiated polymerization did not exceed 48 C. In bbpd initiated pMMA, bubbles were almost never generated.