A Method to Stain Decalcified Bone without Loss of Structural Detail

A modification of Bodian's protargol-S technique is done on 7 μm sections of decalcified bone. Light microscopic results are greatly improved when compared to either ground bone sections or decalcified bone stained routinely with hematoxylin and eosin.     

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.     

Rapid Single-Solution Polychrome Staining of Semithin Epoxy Sections using Polyethylene Glycol 200 (PEG 200) as a Stain Solvent

Rapid, onestep polychromatic staining of 0.75-1.5 μm epoxy sections of glutaraldehyde-osmium fixed tissues can be obtained with mixtures of basic fucbsin and toluidme blue O in alkaline polyethylene glycol ZOO (PEG ZOO). Sections are attached to slides by heating at 100 C for 45 seconds and stained at that temperature for 2-3 minutes with a solution consisting of PEG 200 (50 ml), 0.2 N KOH (0.75 ml), basic fuchsin (1.7 gm), and toluidine blue O (0.3 gm). Red-blue balance and selective staining of different structures can be controlled by varying the amount of toluidine blue added. After rinsing with 10% acetone and rapid drying, sections are covered with immersion oil or mounting medium and a cover-slip. Total time from cutting of a section to finished preparation is less than 6 minutes. This staining solution is stable, does not produce precipitates on the sections, and does not wrinkle or lift the sections from the slides.     

Improved Polyester Wax Embedding for Histology

Polyester waxes are fatty add esters of polyethylene glycol. Polyethylene glycol 400 distearate melts at 35°C, infiltrates tissues well, and sections readily at 2 μ to more than 30 μ. Sections 2 μ to 6 μ are more easily cut when a kitchen strainer full of solid CO₂ (dry ice) is mounted above the microtome to cool the block and the knife, and when the knife crosses the block very slowly. Ribbons are flattened in water at room temperature and are mounted conventionally. Polyester ribbons are somewhat stickier than paraffin ribbons. Polyethylene glycol 400 distearate is slightly hydrophilic; immediately after microtomy and before the ribbon is affixed to the microscope slide, sections in the wax ribbon may conveniently be stained with 0.05% toluidine blue in aqueous benzoate buffer, pH 4.4. Tissue structure is better preserved in polyester than in paraffin wax, probably because structural lipids are better retained and localized. However, this difference between waxes is slight if tissues are well fixed and dehydrated. Other advantages of polyester wax are that sections fragment less, hard tissues rarely split away from the wax ribbon, no static electricity is generated, and the microtome knife seems to remain sharp for a longer time.     

A Simple Method of Staining Juxtaglomerular Granules in the Rat Kidney for High Resolution Light Microscopy

A simple method for the demonstration of juxtaglomerular granules in Epon embedded semithin (0.5-1 μm) sections has been developed as follows: sections are prepared as for routine electron microscopy except that before dehydration, the tissues are immersed in 0.5% uranyl acetate in Veronal acetate buffer (pH 5.0) overnight at room temperature. After sectioning on an ultramicro-tome, the semithin sections are briefly stained with toluidine blue-pyronin Y. After staining, the section is rinsed in running tap water and then air dried. Under a light microscope with a 40 × or a 100 × objective, the juxtaglomerular granules appear as deep purple particles and are thus easily separated from the bluish cytoplasm of the juxtaglomerular cells. Cellular organelles in other cells of the kidney were also clearly stained and their fine structure distinguishable.     

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.     

Embedding Plant Tissue with Plastic Using High Pressure: A New Method for Light and Electron Microscopy

An embedding technique has been developed to overcome difficulties that confront light and electron microscopists working with so-called “hard-to-embed” plant tissue. The method was originally described for freeze-dried material. It uses a modified Quickfit Rotaflo Valve and low heat to generate high pressure to aid in the infiltration and embedding of tissue with propylene oxide and plastic. The technique is not too cumbersome and requires 6 days from the dehydration step to the end of the polymerization process. Thick sections (1-2 μm) obtained from material prepared by this method stain readily with toluidine blue, and thin sections for the electron microscope stain satisfactorily following standard treatment with uranyl acetate and lead citrate. The thin sections are stable under the beam of the electron microscope. Results indicate that the quality of tissue preservation with this high pressure embedding technique is as good as that observed using standard embedding methods for electron microscopy.     

Use of the Four-and-a-Half Clearing Technique to Study Gymnosperm EmbryoIogy: Cunninghamia lanceolata

Since its introduction in 1971, the four-and-a-half clearing technique has been widely applied to the study of ovule and female gametophyte development in flowering plants as an alternative to the more arduous paraffin section methods. The technique has undergone several modifications that have broadened its application in studies of Angiosperm embryology. To date, however, the technique has not been successfully applied to embryological features of Gymnosperms. Dark coloration caused by naturally occurring substances and by-products of fixation render the clearing fluid ineffective, and special pretreatment methods used to remove dark substances in Angiosperm ovules have little or no effect on Gymnosperm material. In the technique reported here, paraffin sections of ovules and young seeds of Cunninghamia lanceolata 80-120 μm thick are cleared in benzyl benzoate-412 clearing fluid and examined with phase contrast optics. Observations of the mature female gametophyte in these cleared preparations are compared with those obtained from 10 μm sections, stained with safranin and fast green, and examined with bright-field optics. Although contrast and definition are more pronounced in stained sections than in cleared ones, the differences would not alter one's interpretation of characteristic structural features. The thick, cleared section offers an advantage over the thin, stained one in that many structural entities are contained within a single section rather than spread through several serial sections. The time required for clearing thick sections is much shorter than that required for making permanent stained preparations.     

A Method of Relating Craniofacial Sections to Topography in Embryos

The transparent properties of the embedding agent glycol methacrylate facilitate orientation of the complex embryonic craniofacial region. This technique allows for consistent and reproducible section-to-topography orientation. We find it to be a valuable adjunct for envisioning three-dimensional relationships. the contrast of external features of the embryo is enhanced when stained lightly with hematoxylin prior to embedding. the craniofacial region of the embedded embryo is removed with a fine surgical saw and re-imbedded. Section-to-topography relationships are readily monitored and documented photographically. Furthermore, it is possible to “preview” sections for symmetry and other considerations of orientation by viewing the cutting face of the block under oblique illumination. A relief image of structures is then visible.     

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.     

Microwave Fixation of Whole Fetal Specimens

This study compares microwave fixation of whole fetal specimens with conventional techniques performed at room temperature. All fetuses were obtained from the same pregnant rat; half of them were placed in neutral formalin for 15 min at room temperature, then irradiated for 2.5 min in a domestic microwave oven. The remaining fetuses were placed in neutral formalin at room temperature for 48 hr as a control. Both experimental and control groups were exposed to routine tissue processing for light microscopy and embedded in paraffin wax. Sections 5 μm thick were stained with hematoxylin and eosin. Our results showed that the microwave technique reduced the fixation time while providing thin sections that were equal to or better in quality than those in the control group.     

A Modified Mallory-Cason Staining Procedure for Large Cryosections

The classic Mallory-Cason staining procedure has been modified for application to sections “on tape” obtained from large deep frozen tissue specimens. These 20 μm cryosections are collected on tape from a large heavy duty cryomicrotome. The stained sections provide anatomical details that are not revealed by other techniques. The merit of this procedure is found in the support of modern medical modalities, both for research and educational purposes.     

Method for Histological Preparation of Bone Sections Containing Titanium Implants

A thin sectioning technique involving hand grinding has been developed to produce 20—40-μn-thick sections of bone-titanium implant sites. Components include: 1) surface staining of sections prior to mounting on slides so bone labels (oxytetracycline-HCI and 2,4-bis(N,N-dicarbometnyl) aminomethylfluorescein (DCAF)) can be seen in sections viewed with transmitted light, 2) a pneumatic sample press for bonding sections to slides with a thin, uniform glue line and without trapped air bubbles, and 3) bonding methyl methacrylate embedded sections to clear acrylic slides with methyl methacrylate monomer to provide enhanced bond strength and grinding properties compared to those obtainable with glass slides. Sample cracking and distortion is minimized and the tissue-implant interface can be kept intact The expense of start-up equipment for this technique is minimal.     

A Method to Prevent Wrinkles in Autoradiographic Emulsion when Staining Plastic Embedded Sections with Hematoxylin and Eosin-Phloxine

A procedure was developed which prevents wrinkles in autoradiographic emulsion when sections, embedded in glycol methacrylate, are stained with hematoxylin and eosin-phloxine. Craniofacial tissues labeled with tritiated thymidine were collected and mounted on slides. Slides were dipped in emulsion, stored for one month and developed. The slides were immersed in liquefied celloidin and subsequently stained with a modified hematoxylin and eosin-phloxine procedure. Results showed that the emulsion did not wrinkle and the procedure did not effect the occurrence of labeled cells.     

Application of Glycol Methacrylate Embedding to Herbarium Specimens of Fruits

Aldehyde fixation and glycol methacrylate embedding were applied to herbarium specimens of fruits of the Compositae. Sections 1-2 μm thick were cut with glass knives. Softening was unnecessary and the hydrophilic properties of the resin permitted staining with a number of dyes. Specimens were examined with bright field and polarized light microscopy. The technique gives good structural preservation and resolution even with 81-year-old herbarium material.     

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.     

Selective Staining of Neurosecretory Material in Semithin Epoxy Sections by Gomori's Aldehyde Fuchsin

The epoxy resin was removed from semithin (1 μm) sections by immersing them for 30 sec in sodium methoxide (Mayor et al., J. Biophys. Biochem. Cytol., 9: 909-10, 1961) and then processed as follows: (1) left for 1-3 hr at 60 C in a mixture of formalin, 25 ml; glacial acetic acid, 5 ml; CrO₃, 3 gm; and distilled water, 75 ml: (2) oxidized 10 min in a 1:1:6 v/v mixture of 2.5% KMnO₄, 5% H₂SO₄ and distilled water: (3) bleached in 1% oxalic acid, and (4) stained for 15 min in aldehyde fuchsin, 0.125% in 70% alcohol, or in a 1% aqueous solution of toluidine blue. The neurosecretory material is selectively stained.     

Histoautoradiographic Localization of Calcium in Oat Plant Tissues

The leaching of water-soluble and exchangeable calcium in histoautoradiog-raphy of oat tissue can be prevented by using acetone as the dehydration fluid (freeze substitution technique) and by keeping the tissue sections, while stretching on water, embedded in the methacrylate matrix. Ca⁴⁵ was either added to the mineral solution on which the oat plants were grown (75 μc), or applied on the leaf surface (8 μc). After freezing in melting isopentane, specimens of 1-2 mm dimensions are fixed for 24 hr in an acetone-OsO₄ (1%) solution at—80 C. Dehydration is obtained by transferring the material every day for 6 successive days to a fresh acetone solution at—80 C. The material is infiltrated by a three-time renewed monomer methacrylate mixture (methylmethacrylate I, butylmethacrylate 4) at—50 C. The specimens are embedded in the polymerizing methacrylate mixture at room temperature. Sections of 4-8 μ are easily cut with a rotating microtome. If the methacrylate is not removed from the sections, they can be stretched on water without leaching of calcium. The presence of methacrylate in no way hinders microscopic observation nor effective histoautoradiography.     

Improvements in Histological Techniques for Epoxy-Resin Embedded Bone Specimens

A procedure is presented in which some of the processing difficulties with fixation, embedding and cutting whole mouse bones and large bone pieces from other species are considered. The bone specimens are fixed in acetone or by a Karnovsky-formol-saline process which preserves intact endosteal surface-to-cortex layers. After fixation the bones are embedded in a hard mixture of epoxy resin to provide blocks with face sizes up to 3.5 × 3.0 cm. Mineralized sections are cut at 4 μm; demineralized at 3 μm. Sections are fastened to gelatin-subbed slides with pressure plates which produce flat, secure sections. After removal of the plastic, an unmodified Mayer's hematoxylin and a polychromatic eosin staining method is applied to demineralized sections, and a slightly modified method to mineralized sections.