Embedding Media for 1-2 Micron Sectioning. 2. Hydroxyethyl Methacrylate Combined with 2-Butoxyethanol

A hydroxyethyl methacrylate monomer medium incorporating 2-butoxyethanol requires 2 stock solutions for embedding. Solution A: 80 ml of hydroxyethyl methacrylate (Rohm and Haas Co., Philadelphia, Pa.) is mixed well with 16 ml of 2-butoxyethanol; 0.27 gm of benzoyl peroxide, the catalyst, is added and permitted to dissolve. Heating to 40-50 C may be used to accelerate its solution. Solution B: polyethylene glycol 200 or 400, 15 parts, and N,N-dimethylaniline, 1 part, are mixed thoroughly. Tissues are dehydrated in the customary manner to absolute ethanol or other comparable dehydrant, infiltrated completely with A, then cast in a mixture consisting of 42 parts of A well mixed with 1 part of B. Polymerizaion occurs in 4-7 hr. In a water bath at 20 C the time required was about 7 hr; at 28 C, 4 hr. This medium is based on the author's water-polyethylene glycol-hydroxyethyl methacrylate monomer medium (Stain Techn., 42: 119-23, 1967).     

Hydroxyethyl Methacrylate Combined with Polyethylene Glycol 400 and Water; an Embedding Medium for Routine 1-2 Micron Sectioning

Pieces of tissue, with the largest dimension not exceeding 7 mm, are fixed and dehydrated by the procedures of choice. Two stock solutions: A, for infiltration; and B, the accelerator, are used in embedding. Formulas: A, 80 ml of glycol methacrylate (2-hydroxyethyl methacrylate—Rohm and Haas Co., Philadelphia, Pa.) is mixed well with 12 ml of polyethylene glycol (Carbowax) 400 and 8 ml of water; then 0.27 gm of benzoyl peroxide added, heated to dissolve the peroxide, and allowed to cool to room temperature. B, polyethylene 200 or 400, 15 parts, and N,N-dimethylaniline, 1 part, mixed thoroughly. Tissues are first infiltrated completely with solution A, then cast in a mixture consisting of 42 parts of A mixed with 1 part of B. Polymerization occurs in 45 min to 3 hr, depending on the temperature. In a water bath at 20 C, the time required was found to be about 3 hr; at 25 C, 1.5 hr; and at 30 C, 45 min. The plastic block can be trimmed easily, and sections 1-2 μ thick readily cut. Sections can be attached to slides by water flotation, without adhesive, and should be dried at room temperature. Staining with aqueous solutions of basic and acid dyes, without removing the embedding matrix, is sharp and brilliant. When staining of the matrix by basic dyes occurs, this background stain can be completely removed by differentiating in either 2-butoxyethanol, pure ethanol, or a mixture of the two. A number of histochemical reagents have been found compatible with this embedding procedure.     

N-butyl Methacrylate and Paraffin as an Embedding Medium for Light Microscopy

A method of tissue embedding using n-butyl methacrylate and paraffin is described. Following alcohol dehydration and infiltration with the methacrylate monomer, tissues are embedded in gelatin capsules in a mixture consisting of 3.5 g of paraffin for each 10 ml of methacrylate. Benzoyl peroxide (0.2 g for each 10 ml of monomer) is added as the catalyst and the methacrylate polymerized in a 50 C oven for 18-24 h. Following polymerization the block is trimmed and embedded in paraffin to provide a firm support during sectioning. A water trough attached to the microtome knife is essential to facilitate the handling of sections and ribbons. For serial sections a mixture of equal weights of beeswax and paraffin is used to make the sections adhere to each other. Usual staining procedures can be used since the embedding medium is readily soluble in xylene.     

A simplified technique for low temperature methyl methacrylate embedding

A simplified method for low temperature methyl methacrylate embedding with inhibited methyl methacrylate monomer is demonstrated using proper concentrations of benzoyl peroxide and N,N-dimethylaniline. The polymerized tissue blocks cut well and the tissue sections obtained show excellent acid phosphatase activity when demonstrated with the newly improved technique and Goldner's staining. Likewise, double tetracycline labels are well revealed by fluorescence microscopy.     

N-Butyl methacrylate and paraffin as an embedding medium for light microscopy.

A method of tissue embedding using n-butyl methacrylate and paraffin is described. Following alcohol dehydration and infiltration with the methacrylate monomer, tissues are embedded in gelatin capsules in a mixture consisting of 3.5 g of paraffin for each 10 ml of methacrylate. Benzoyl peroxide (0.2 g for each 10 ml of monomer) is added as the catalyst and the methacrylate polymerized in a 50 C oven for 18--24 h. Following polymerization the block is trimmed and embedded in paraffin to provide a firm support during sectioning. A water trough attached to the microtome knife is essential to facilitate the handling of sections and ribbons. For serial sections a mixture of equal weights of beeswax and paraffin is used to make the sections adhere to each other. Usual staining procedures can be used since the embedding medium is readily soluble in xylene.     

A Simplified Technique for Low Temperature Methyl Methacrylate Embedding

A simplified method for low temperature methyl methacrylate embedding with inhibited methyl methacrylate monomer is demonstrated using proper concentrations of benzoyl peroxide and N,N-dimethylaniline. The polymerized tissue blocks cut well and the tissue sections obtained show excellent acid phosphatase activity when demonstrated with the newly improved technique and Goldner's staining. Likewise, double tetracycline labels are well revealed by fluorescence microscopy.     

Silver Impregnation of the Golgi Apparatus, with Subsequent Nitrocellulose Embedding

The appearance of silver impregnation of the Golgi apparatus can be enhanced by the use of nitrocellulose as an embedding medium. Fixation of 1.5 mm thick pieces of fresh tissue for 8 hr in: glycine, 1.7 gm; 15% formalin, 100 ml; HNO₃, conc., 0.5 ml, at pH 2.6 followed by rinsing in water, 4 hr in 1.5% AgNO₃, another rinse, and 2 hr reduction in 1.5% hydroquinone in 15% formalin. This staining procedure yields consistently good results for rat, rabbit, and human tissues. Low-viscosity nitrocellulose embedding is done by infiltrating at 56 C in 7% nitrocellulose for 0.5 hr, 15% for 4 hr, and 27% for 1 hr. The nitrocellulose is hardened 2 hr in chloroform, after which, sections as thin as 5 μ can be cut on a sliding microtome. Gold toning and counterstaining can be done with the tissue affixed to the slide. The Golgi apparatus is stained dark brown to black, and there is better preservation of cellular detail than in tissues processed in paraffin.     

Methyl Green-Pyronin for Staining Autoradiographs of Hydroxyethyl Methacrylate-Embedded Lymphoid Tissue

Cells in the spleen in DNA-synthesis were labelled with tritiated thymidine. Tissue was fixed for 12 hr in 10% neutral formalin, washed for 4 hr in tap water and dehydrated through 70% and absolute ethanol. The tissue blocks were infiltrated overnight with a mixture consisting of glycol methacrylate, 80 ml; polyethylene glycol 400, 12 ml; and benzoyl peroxide, 0.27 gm. Specimens were cast in BEEM capsules with the final embedding medium consisting of 42 parts of the infiltration medium and 1 part of an acceleration mixture. This mixture consisted of N,N-dimethylaniline, 1 part and polyethylene glycol 400, 15 parts. The blocks hardened in 30 min and were sectioned with an ultramicrotome fitted with glass knives. Sections were coated with Ilford K5 liquid emulsion and exposed for 2 wk. Methyl green-pyronin staining of autoradiographs was carried out at pH 4.1 in acetate buffer containing 0.5% methyl green (Allied Chemicals) and 0.2% pyronin GS (Chroma). Staining was for 30-60 min, after which sections were washed for 1 min in water, blotted, allowed to dry, and mounted in Canada balsm. The procedure resulted in good quality autoradiographs in which the degree of basophilia of labelled cells could be assessed.     

A Ribonuclease-Gallocyanin Stain for Sexing Skin Biopsies

Skin biopsies for sexing can be fixed best in 10-15% aqueous formalin or this solution saturated with HgCl₂. Bouin's fluid and all chromate mixtures should be avoided. Celloidin-paraffin double embedding is recommended but not essential. Sections are brought to water, mercurial residues removed if necessary, and then washed in distilled water. They are incubated at 37°C in a ribo-nuclease solution: approximately 1 mg of ribonuclease powder (Light's) in 100 ml of glass-distilled water; boiled 3-5 sec after dissolving, and kept in a refrigerator (usable about a week). The sections are rinsed and incubated at 37°C overnight in gallocyanin-chromalum (Einarson, 1951) made as follows: Dissolve 5 gm of chromalum in 100 ml of distilled water, add 0.15 gm of gallocyanin, shake thoroughly, heat slowly and boil 5 min; cool, filter, and wash through the filter with distilled water until the filtrate reaches 100 ml. This solution is usable at once and keeps at least a month. Sections should be dipped in acid alcohol to clean (optional), but no attempt made to differentiate them, and washed in tap water. Dehydration, clearing and covering complete the process. The method is nearly as precise as the Feulgen and more convenient and reliable for routine use on miscellaneous material.     

Serial Sections of Cooked Rice Embedded in Carbowax

Serial sections of cooked rice kernels may be obtained by following either of two dehydration schedules and embedding in Carbowax. In the first schedule the cooked, rinsed and drained kernels are immersed several days in a nonaqueous fixative composed of: isopropyl alcohol, 10 ml; propionic acid, 30 ml; acetone, 10 ml; methylal, 40 ml; dioxane, 30 ml; and propylene glycol, 30 ml (Newcomer's, modified), followed by 7 or 8 days in equal parts of propylene glycol, dioxane and glycerol (changed once), and 4 days on a warming table in the same mixture with 5% Carbowax added. The dehydrated kernels are then infiltrated 4-24 hr with a Carbowax embedding mixture. In the second schedule they are immersed several days in an aqueous solution consisting of: propylene glycol, 12.5 ml; polyethylene glycol 400, 12.5 ml; either with 75 ml of water containing 0.1% thymol, or with a mixture of water, 65 ml; formalin, 10 ml; CaCl₂, 1 gm; and CdCl₂, 1 gm; followed by 3 or 4 days in 50% propylene glycol, and 3 or 4 days on a warming table in 80% propylene glycol with 5% Carbowax added. Infiltration is as above. The composition of the embedding mixture is varied according to the temperature and humidity likely to prevail during sectioning. The texture of the wax may be improved by adding small amounts of gum arabic, spermaceti, and glycerol. Serial sections 3-10 μ thick are placed on clean dry slides, and adhesive dropped at the edges of the ribbon of Carbowax until it is dissolved. The adhesive consists of water-glass (concentrated solution), 1 ml; concentrated ammonia, 1 ml; Carbowax, 5 gm; and water, 98 ml. After the slides are dry they are stored, or immersed 10 min in chloroform, collodionized, and passed to staining solutions. Atmospheric conditions affect not only the Carbowax, but also the response to reagents of cooked rice and of sections.     

Bone Embedding Technique with Inhibited Pmma Monomer

Unwashed inhibited thin and thick methyl methacrylate monomer was used for successful embedding of bone by increasing the quantity of benzoyl peroxide catalyst until the activity of the hydroquihone inhibitor was overwhelmed. Seven bones were embedded using 1, 2, 4, 6, 8, 10 or 12 grams of benzoyl peroxide per 100 milliliters of thick monomer. Two grams per 100 ml was found to be optimal. Higher concentrations resulted in uncontrolled polymerization while at 1 g/100 ml the solution remained liquid.     

A Tungstate Modification of the Golgi-Cox Method

Pieces of fresh nervous tissue 4-5 mm thick are put into the following solution: HgCl₂, 1 gm; K₂Cr₂O₇, 1 gm; K₂CrO₄, 0.8 gm; K₂WO₄ (or Na₂WO₄), 0.5 gm; distilled water 100 ml. They are kept undisturbed in the dark at room temperature for 20-30 days, then transferred to the following alkaline solution: LiOH (or NaOH), 1 gm; KNO₃, 15 gm; distilled water, 100 ml. After 12-24 hr in this solution they are washed for 12-24 hr in several changes of distilled water. (If sodium hydroxide was used, 0.5 ml of acetic acid should be added per 100 ml of wash water.) Embedding in celloidin follows dehydration. Sections are dehydrated in 3 parts of absolute alcohol and 1 part of chloroform, cleared in iodobenzene and mounted with a cover slip using a mounting medium with a refractive index around 1.61. The use of tungstate improves the general results and allows especially successful impregnations in very young animals, when the usual technic fails.     

Methacrylate as an Embedding Medium for Woody Tissues

Methacrylate can be readily infiltrated into woody tissues. After infiltration, the tissue is transferred to a polymerizing mixture of 95:5 butyl methacrylate to methyl methacrylate by volume. For each 100 ml of polymerizing mixture, 2 grams of Luperco CDB catalyst are added. The hardness of the matrix may be increased by increasing the proportion of methyl methacrylate. Polymerization is accomplished by 2 days in a 50° C oven or 2 days in a small ultraviolet radiation chamber (42° C), the latter being the technique of choice. The blocks can be sectioned readily at 6 μ to more than 30 μ. Sectioning is facilitated by keeping the block wet with a 1:1 glycerol-alcohol solution. Best preparations are obtained when the matrix is removed after sectioning; however, staining in safranin O-fast green FCF may be-accomplished through the matrix. The technique is very rapid, convenient to use, and has produced excellent preparations from several species of woody plants.     

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.     

Ultramicrotome Chucks for Flat Castings

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.     

Counterstaining Golgi-Cox Impregnations with Luxol Fast Blue as a Myelin Stain

Immerse pieces of brain tissue 4 wk in solutions A and B, mixed just before use: A. K₂Cr₂O₇, 1 gm; HgCl₂, 1 gm; boiling distilled water, 85 ml. Boil A for 15 min, cool to 2 C and add: B. K₂CrO₄, 0.8 gm; Na₂WO₄, 0.5 gm; distilled water, 20 ml. Rinse in water and immerse 24 hr in LiOH, 0.5 gm; KNO₃, 15 gm; distilled water, 100 ml. Wash 24 hr in several changes of 0.2% acetic acid and then for 2 hr in tap water. Dehydrate and embed in celloidin. Process a 60 μ section through 70 and 95% ethanol, a 3:1 mixture of absolute ethanol and chloroform, and toluene. Immerse it for 5 min in a solution containing methyl benzoate, 25 ml; benzyl alcohol, 100 ml; chloroform, 75 ml. Orient the section on a chemically clean slide and let air-dry 5-10 min. Process through toluene, 3:1 ethanol-chloroform and 95% ethanol. Place the section for 5-60 min at 60 C in a solution made up of: Luxol fast blue G (Matheson, Coleman and Bell), 1 gm; 95% ethanol, 1000 ml; 10% acetic acid, 5 ml. Hydrate to water and immerse in 0.05% Li₂CO₃ for 3-4 min. Differentiate in 70% ethanol and place in water. Immerse for 5-15 min in a mixture of two solutions: A. cresylechtviolet (Otto C. Watzka, Montreal), 2 gm; 1 M acetic acid, 185 ml; B. 1 M sodium acetate, 15 ml; distilled water, 400 ml; absolute ethanol, 200 ml. Dehydrate to 3:1 ethanol-chloroform. Clear in toluene and apply a coverslip. The technique produces fast Golgi-Cox impregnated neurons against a background of counterstained myelinated fibers. Patterns of the myelinated fibers can be used to localize impregnated neurons.     

Silver Staining of Bone Prior to Decalcification for Quantitative Determination of Osteoid in Sections

Slices, 1-2 mm thick, of alcohol-fixed bone are immersed in 2% aqueous AgNO₃ in the dark for 48 hr. After thorough washing in running tap water, the silver phosphate formed at the interface of osteoid and calcified bone is reduced to a black deposit by 5% aqueous sodium hypophosphite containing 0.1 N NaOH, 0.2 ml/100 ml. The blocks are then immersed in 5% aqueous Na₂S₂O₃ and after further washing pass through a routine formic acid decalcification and paraffin wax embedding schedule. Sections cut at 5 μ thickness and counterstained with Van Gieson's picrofuchsin show a clear differentiation between osteoid tissue and the outer limit of calcification in trabecular or cortical bone, thus making them suitable for quantitative studies. The main advantage of the method is the production of intact stained sections without specialised embedding or cutting techniques.     

Correlation of CrystaL Growth with the Staining of Axons by the Golgi Procedure

The surface of the specimens subjected to a modified Golgi technique (formalin fixed material; specimens in the following solution for 8-10 days at 27 C: 3% K₂Cr₂O₇, 100 ml, with the addition of 2.5-10 ml of 10% formalin and 6-25 gm of sucrose; then in 0.75% AgNO₃ for at least 2 days at 27 C) is sometimes covered with a fur of filamentous crystals and sometimes with a powdery precipitate of laminar crystals. In a series of experiments in which about 500 blocks of tissue were treated with variations of the staining procedure, good axonal stain was positively correlated with the appearance of filamentous crystals. These filaments have a thickness of 1-4 μ and grow at a rate of 160-330 μ/hr, reaching a length of 2-7 mm.     

Staining Sex Chromatin; Biebrich Scarlet and Fast Green Fcf as a Mixture Versus Their Use in Sequence

Human skin was fixed in Davidson's solution (95% alcohol, 35; formalin, 20; glacial acetic acid, 10; and distilled water, 35—parts by volume) and sections prepared through paraffin embedding in the usual manner. Stock stains were: I(BS)—Biebrich scarlet, 1 gm in 100 ml of 50% alcohol to which 0.3 gm of phosphotungstic acid and 5 ml of glacial acetic acid were added—and II(FG)—fast green, 0.5 gm in 85 ml of 50% alcohol to which 0.3 gm of phosphotungstic acid, 0.3 gm of phosphomolybdic acid, and 15 ml of glacial acetic acid were added. Experimental staining solutions were prepared in the following proportions of stock BS to stock FG—1:1, 2:1, 3:1, 1:2 and 1:3. Sections were brought to 50% alcohol and stained for 15, 20, 25 and 30 min in each of the five BS-FG mixtures, rinsed in 50% alcohol, then dehydrated in 70%, 95%, and absolute alcohol, 2 min each; cleared in xylene, and covered in balsam. The 2:1 (optimum proportion) combination of BS with FG, acting for 20 min, yielded 97% sex chromatin-positive nuclei in female material. If sections were stained in stock solution BS for 2 min, they could be differentiated by a 20 min treatment in the mordanting component of stock FG (without dye) to give a one-color stain. Such stains gave about the same percentage of sex chromatin-positive nuclei as those obtained by the regular two-color procedure. These modifications are simpler, more rapid, and yield results comparable to previously employed techniques.     

Staining Sex Chromatin; Biebrich Scarlet and Fast Green Fcf as a Mixture Versus Their Use in Sequence

Human skin was fixed in Davidson's solution (95% alcohol, 35; formalin, 20; glacial acetic acid, 10; and distilled water, 35—parts by volume) and sections prepared through paraffin embedding in the usual manner. Stock stains were: I(BS)—Biebrich scarlet, 1 gm in 100 ml of 50% alcohol to which 0.3 gm of phosphotungstic acid and 5 ml of glacial acetic acid were added—and II(FG)—fast green, 0.5 gm in 85 ml of 50% alcohol to which 0.3 gm of phosphotungstic acid, 0.3 gm of phosphomolybdic acid, and 15 ml of glacial acetic acid were added. Experimental staining solutions were prepared in the following proportions of stock BS to stock FG—1:1, 2:1, 3:1, 1:2 and 1:3. Sections were brought to 50% alcohol and stained for 15, 20, 25 and 30 min in each of the five BS-FG mixtures, rinsed in 50% alcohol, then dehydrated in 70%, 95%, and absolute alcohol, 2 min each; cleared in xylene, and covered in balsam. The 2:1 (optimum proportion) combination of BS with FG, acting for 20 min, yielded 97% sex chromatin-positive nuclei in female material. If sections were stained in stock solution BS for 2 min, they could be differentiated by a 20 min treatment in the mordanting component of stock FG (without dye) to give a one-color stain. Such stains gave about the same percentage of sex chromatin-positive nuclei as those obtained by the regular two-color procedure. These modifications are simpler, more rapid, and yield results comparable to previously employed techniques.