Grinding Thin Sections of Plastic-Embedded Bone

The method describes an adaptation of a metallurgical procedure whereby dry, calcined bone may be simultaneously infiltrated and embedded in a transparent plastic, Transoptic, and then ground to the desired thinness for microscopic observation with transmitted light. A 2 mm.-thick specimen of bone, ground smooth on one side, is placed ground side up in a 1' mold assembly of a metallurgical specimen mount press. About 5 ml. of the plastic medium is added, the temperature raised to 130° C, and the pressure raised to 100 pounds. When 130° C. is reached, the heater is disconnected, the pressure immediately raised to 3500 pounds and maintained at that level until the mold cools to 68° C. The pressure is then released and the 5 mm.-thick plastic disc, with the embedded specimen therein, expressed from the mold. Grinding, as well as polishing, is dry; abrasives in fluid media are not used. The disc and specimen are coarse ground on #340 grit dry silicon carbide paper until histological details begin to appear. Final fine grinding is done on #600 grit dry silicon carbide paper. The disc is then polished and may be mounted on a 1 × 3 Plexiglas slide.     

Apparatus for Bone Sectioning

A new type of apparatus for cutting 100-200µ sections of bone is described. This apparatus consists of an especially designed bone vise and a mounted circular saw with three directional movement controls. The saw is driven by one D.C. motor and its vertical movement assembly is driven by another. Their speeds can be regulated individually. The bone sections may be made serially at intervals of 0.3 to 0.5 mm. and bones as large as 2 cm. in diameter or longitudinal slabs of larger bones may be sectioned.     

A Simplified Procedure for Preparation of Undecalcified Human Bone Sections

A new type of apparatus for sectioning samples of hard, undecalcified bone is described. Slices of fresh or archeological human bone 4-5 mm thick are dehydrated and then embedded in epoxy resin. The apparatus used to prepare sections from the resulting blocks consists of a low-speed rim-type diamond cut-off wheel and a slowly advancing table carrying the specimen held in a rotating mount. Sections may be cut at a thickness of 80 μm ± 1%. After cleaning in an ultrasonic bath, these can be mounted on slides for quantitative microscopic examination with transmitted light. Grinding and polishing are not necessary. The results obtained are illustrated.     

Suggestions on the Preparation of Undecalcified Bone for Microradiography

In microradiography the thickness of the specimen usually governs the degree of discrete structural detail attainable. A cause of poor detail in the historadiography of bone sections thinner than 30 micra is distortion attributable to lack of uniform contact between the undecalciiied specimen and the photographic emulsion. The use of a strong but radio-lucent supporting membrane on which the section can be mounted is an approach to the solution of this difficulty. Cementing the polished section under pressure to a 2 μ nylon membrane mounted on a modified specimen ring produces a flat section in close contact with the film. By mounting microtome-cut sections of frozen-dried developing bone directly on a supporting film of a polyvinyl resin, histochemical staining as well as microradiography can be performed on the same section.     

Sectioning of Undecalcified Bone; with Special Reference to Radioautographic Applications

A rapid technic for the preparation of 6 μ serial sections of undecalcified bone is described. The specimen is fixed and dehydrated in acetone and ether. It is then treated with a 1:1 mixture of the monomers of ethyl and n-butyl methacrylate catalyzed with benzoyl peroxide. The monomers are removed with ether and the ether is removed under vacuum. Infiltration is accomplished under vacuum using a partial polymer of the same mixture of monomers. Polymerization is completed in 36 hours under pressure at 50°C. The tissue is sectioned with a heavy-duty microtome, the sections are mounted on glass slides and nuclear emulsions applied. Young and adult bone of laboratory animals and man have been cut successfully. Microscopic structural detail is preserved and there is no evidence of translocation of the radioactivity.     

Automatic grinding of undecalcified bone sections with exact adjustment of thickness]

A new grinding machine for preparing thin undecalcified bone sections after methylmethacrylate embedding is described. About 20 rather small bone sections can be ground at the same time; bigger specimens, up to 8 cm of length, are allowed. Bone sections are mounted on a cylindrical specimen holder by an adhesive film. Then the final thickness of the sections is exactly adjusted by screwing three rubies out of the holder's bottom. Now the prepared holder is set in a guide ring on a turntable carrying a rough ended glass plate. The desired thickness of the sections is reached as soon as the three rubies touch the glass surface. The variation in the thickness of the sections is less than +/- 3 micron. The machine is simply constructed, easily to handle and rapidly to clean.     

The Benzidine Staining Method for Blood Vessels

Two modifications of the method are described: A. Living specimens of sabellid and serpluid polychaetes, earthworms, small tadpoles, or fish larvae are immersed in an approximately saturated solution of benzidine for 30 minutes and then 3% hydrogen peroxide is added until bubbles of gas appear. When the blood vessels appear dark blue, the specimens are fixed in acidified 70% alcohol, dehydrated, cleared and either mounted in Canada balsam as whole mounts, or embedded in paraffin, sectioned at 100 to 250µ and mounted. B. Material fixed in 10% formalin in sea-water, or in formalin hypertonic saline, is incubated at 37°C. for one hour in an aqueous mixture containing sodium nitroprusside, 0.1%; benzidine, acetic acid 0.5%, followed by a weak (0.01-0.02%) hydrogen peroxide solution for a further hour, embedded in paraffin, cut into thick sections and mounted.     

Shadow Casting of Stained Virus Bodies to Enhance Visibility by Light Microscopy

Materials used for study were viral smears or ultra-thin sections containing viral cell inclusions. They were stained with the Feulgen reaction and other cytochemical procedures. Stained preparations were dried and then shadow-cast with metallic chromium for 30 seconds in a bell jar with a vacuum of at least 0.1 µ (10^-4mm.) of mercury, and placed at a shadowing angle of 10-12°. Shadow-cast preparations were cleared with xylene and mounted in Canada balsam. Dried smears or deparaffinized sections without staining were suited to this method also. A virus which stained indistinctly with cytochemical procedures alone could be adapted to visible light microscopy by shadowing, and in addition, used for observations on its chemical composition.     

Preparing Single or Serial Sections of Calcified Bones and Teeth

An apparatus for cutting single or serial sections of calcified bone and teeth consists of a motor-driven shaft on which is mounted one saw (for single section cutting) or a gang (for serial sectioning at one cutting operation). The plastic-embedded specimen is attached to a cylindrical plastic holder which is in turn mounted on the machine and fed into the saw. Prior to cutting the specimen may be oriented in two planes, as well as rotated, with respect to the cutting edge. Single or serial sections made by means of repeated cuts with a single saw, may be 0.3 mm or more thick as determined by the setting of a micrometer screw. For serially sectioning a tooth or bone specimen at one cutting operation, the thickness of the separators between adjacent saws (0.5 mm or more) determines the section thickness. After sectioning, specimens may be ground and polished, with or without reimbedding in fresh plastic.     

Polyester Resin Embedding for Sectioning of Hard and Soft Tissues

Soft and calcareous tissues embedded in polyester resin may be cut on a sledge microtome to produce thin sections of 3-4 β thickness. Fixed tissues, dehydrated in ethyl alcohol, cleared in methyl benzoate and chloroform, are taken into a wide-necked bottle containing equal parts of polyester resin and chloroform with 0.75% catalyst. The bottle kept in water bath at 37°C is connected to a vacuum pump. With the evaporation of the chloroform under reduced pressure (approximately 10 mm Hg) infiltration is complete. Tissues transferred into a blocking form containing pure polyester resin with 1.5% catalyst are polymerized at 37° C until blocks are firm (48 hr or more). Blocks are prepared with at least 5 mm margin of plastic surrounding the tissue. The edge of the block adjacent to the knife is then filed at an angle of 45° to the cutting movement. Sections are cut with a wide-backed biplanar knife having a cutting edge of 40-44° positioned at an angle of 30° to the plastic block. As the resin is permeable to most stains, staining is carried out through the plastic Sections carried through staining procedures in wire baskets are floated onto slides and mounted in polystyrene; the cover-glass is compressed with a spring-clamp. Microscopic examination shows no staining of plastic, minimal shrinkage and good cellular detail.     

The Demonstration of a new nerve-cell Organoid

A method is described for the demonstration of a new nerve-cell organoid— the binary spheroid systems (Baker bodies). Zenker-formol or acetic-osmium-bichromate materials are postchromed at 37°C. and embedded in paraffin, sectioned and mounted in the ordinary manner. The sections are colored in a 70% alcohol solution of Sudan black B, rinsed in 70% alcohol, counter-stained in Mayer's carmalum and mounted in Farrant's medium. After examination the cover may be removed and the Sudan black extracted in 96% alcohol. The sections can then be restained by the azan method of Heidenhain, and other cytoplasmic inclusions can be correlated accurately to the functional states of the spheroid systems.     

Gallocyanin as A Nuclear Stain

Gallocyanin has been used successfully as a nuclear stain. Sections are cut by the freezing method of either fixed or unfixed tissue. The tissues are warmed (not exceeding 70°C.) for 2-4 minutes in the gallocyanin solution. A counterstain may be used if desired. The most effective are Biebrich scarlet, phloxine, or eosin Y. The sections are then dehydrated and mounted in clarite. The nuclear pattern is clearly demonstrated and the sections are permanent.     

Embedding and Sectioning Undecalcified Bone, and its Application to Radioautography

A method is described for embedding and sectioning hard, undecalcified bone, which is designed for use by technical personnel. Bone fixed in a variety of ways is progressed through alcohols to ether-alcohol and then infiltrated with ether-alcohol solvented plastic (plasticized nitrocellulose) by a combination of centrifugation and high pressure embedding technics. The ether-alcohol is evaporated in a partially closed container in a manner similar to that employed in celloidin embedding, but differs from the latter by the removal of all of the solvent. Celloidin is the source of nitrocellulose and Amoil-S, the added plasticizer. Undecalcified adult bone of all types is readily cut at a thickness of 5-8μ on a heavy duty sliding microtome. The sections are then mounted on gelatinized slides. The procedures for preparing strip film radio-autograms of bone sections and subsequent staining of the preparation are given. The results obtained are illustrated.     

Histological Methods for the Demonstration of Gold in Tissues

Two methods for the demonstration of gold in tissues are described. The tissue is fixed in neutral formalin, embedded in paraffin, sectioned and run down to water. In the SnCl₂ method, modified from that of Christeller, it is then incubated for 24 hours at 56° C. in a mixture of ten parts of 5% SnCl₂·2H₂O and one part of concentrated HCl. The interpretation of the results obtained by this method is frequently difficult because of the presence of accessory precipitates and the presence of the normal pigments of the tissue. This has led to the development of a new method, in which the sections are incubated for periods varying from 24 hours to 6 days at 37° C. in 3% H₂O₂. The gold is reduced to the metallic state, the interfering tissue pigments are bleached, and, since no metallic ions have been added, accessory precipitates do not occur. After both methods, the sections are washed thoroughly, run up, and mounted in damar.     

A Chlorate-Formaldehyde Modification of the Golgi Method

Pieces of fresh nervous tissue 3-5 mm thick are put into a mixture of: 6% K₂Cr₂O₇, 40 ml; 5% KClO₃, 20 ml; 20% chloral hydrate, 30 ml; and concentrated formalin (38% HCHO), 10 ml; allowed to fix 3 days, with a daily change of fluid; transferred to 3% K₂Cr₂O₇ for 3 days, with twice daily changes; then to 1% AgNO₃ for 3 days at 20-25° C. Frozen sections are cut, dehydrated, cleared and mounted in Permount with a cover glass. The method gives good results for microglia and oligodendroglia in addition to the usual staining of nerve cells and their processes.     

Histochemical Demonstration of Carbonic Anhydrase Activity

Fresh tissue slices fixed in chilled acetone for 1 hour and washed in distilled water for 10-30 minutes were incubated for 30-45 minutes at 37°C. in the freshly prepared incubating mixture: filtrate of a mixture of 8% sodium bicarbonate, 100 ml., and MnCl₂·4H₂O, 1 g. After washing in distilled water for 1 hour, they were dehydrated and embedded in paraffin. Sections were cut 15-20μU, deparaffinized, rinsed in absolute alcohol and placed in a 0.1% solution of potassium periodate for 48 hours at 37°C. The mounted sections were counterstained (if desired), dehydrated in alcohol, cleared in xylene (not carbol-xylene) and mounted in balsam. Many brown granules were produced on the sites of enzyme activity by this procedure. The results obtained seem to be in good agreement with previous findings by biochemical determinations.     

Cement Line Staining in Undecalcified Thin Sections of Cortical Bone

A technique for demonstrating cement lines in thin, undecalcified transverse sections of cortical bone has been developed. Cortical bone samples are processed and embedded undecalcified in methyl methacrylate plastic. After sectioning at 3-5 μm, cross-sections are transferred to a glass slide and flattened for 10 min. Sections of cortical bone are stained for 20 sec free-floating in a fresh solution of 1% toluidine blue dissolved in 0.1% formic acid. The section is dehydrated in t-butyl alcohol, cleared in xylene, and mounted with Eukitt's medium. Reversal lines appear as thin, scalloped, dark blue lines against a light blue matrix, whereas bone formation arrest lines are thicker with a smooth contour. With this technique cellular detail, osteoid differentiation, and fluorochrome labels are retained. Results demonstrate the applicability of a one-step staining method for cement lines which will facilitate the assessment of bone remodeling activity in thin sections of undecalcified cortical bone.     

A Urea Silver Nitrate Method for Nerve Fibers and Nerve Endings

A silver nitrate stain for nerve fibers and endings applicable to paraffin sections on the slide utilizes the properties of urea to accelerate the procedure and improve the specificity of the stain. After removal of the paraffin the sections are run through absolute, 95% and 80% alcohol and placed for 60-90 minutes at 50-60°C. in: 1% aqueous silver nitrate, 100 ml.; urea, 20-30 g.; 1g. mercuric cyanide and 1 g. picric acid in 100 ml. of distilled water, 1-3 drops. After the silver bath they are rinsed quickly in 2 changes of distilled water and reduced for 3-5 minutes at 25-30°C. in: water, 100 ml.; sodium sulfite, anhydrous, 10g.; hydroquinone, 1-2g.; urea, 20-30g. They are then washed thoroughly in 4-5 changes of distilled water, passed through graded alcohols into 80% alcohol and examined under the microscope. If nerve fibers are not distinct, the sections are returned to the same urea-silver-nitrate bath for 10-15 minutes, rinsed, reduced, washed and dehydrated as before. This process may be repeated until staining is adequate; then they are dehydrated, cleared, and mounted.

Nerve fibers show a color range from brown to black; nerve cells from yellow to brown; and the background, depending on the type of tissue and its fixation, from yellow to light brown.     

Demonstration of Cholinesterase in Teeth

Human teeth have been studied by treatment with copper thio-choline, the method developed by Koelle for demonstrating activity of both specific and nonspecific cholinesterases. Freshly extracted teeth were collected and immediately sectioned on a cutting machine designed for calcified tissues. One series of teeth was sectioned sufficiently thin for microscopic study. Another series of teeth was bisected to expose the pulp chambers to the reagents. These teeth were divided into 5 experimental groups. The first group was treated with 10^-6M di-isopropylfluorophosphate (DFP) for 30 min at 37°C and then incubated with acetylthiocholine (AThCh) for 16 to 20 hr at 37°C in order to reveal the sites of activity of the specific enzyme, AChEase. The second group was incubated in a substrate of butyrylthiocholine (BuThCh) for 12 to 16 hr at 37°C to indicate the sites of the nonspecific ChEase. The third group was incubated in AThCh for 16 to 20 hr at 37°C without previous treatment by an inhibitor in order to reveal the presence and location of both the specific and nonspecific ChEase. The fourth and fifth groups were utilized as controls. Group 4 tissues were incubated without a substrate while those of group 5 were treated with DFP and then incubated with BuThCh. The specimens then were treated with ammonium sulfide to outline the sites of ChEase activity. The thin sections were mounted directly but the series of halved teeth were decalcified, embedded in paraffin, sectioned and then mounted. By these methods the presence and location of both specific and nonspecific ChEase activity were observed in human teeth. Concentration of specific ChEase was observed along the coronal aspect of the pulp chamber and along the course of the pulpal nerves. The nonspecific ChEase was observed throughout the pulpal tissue and appeared to be concentrated along the nerves and blood vessels. Neither series of control tissues exhibited any staining in the pulp tissue.     

Staining Streptomyces Scabies in Lesions of Common Scab of Potato

Toluidine blue can be used to stain Streptotnyces scabies distinctively in slide cultures or in the lesions of common potato scab. This staining method is based on the metachromaticism of volutin, a constant constituent of the spores and mycelium of S. scabies. Either sections or smears are fixed in FPA (formalin, 5 parts; propionic acid, 7.5; 50% alcohol, 87.5), stained in a 1:100 dilution of saturated aqueous toluidine blue from 20 minutes to 24 hours, dehydrated in an acetone-xylene series and mounted. Cellular constituents of the potato tuber stain blue or are colorless whereas the mycelium of Streptomyces appears as a series of red volutin spheres in the blue stained cytoplasm. The criteria of volutin and cytoplasmic staining along with the 1 µ diameter of the mycelium make it possible to distinguish Streptomyces from the other microorganisms and cells in the lesion region.