Large area sectioning for morphologic studies of nonhuman primate nasal cavities

The nasal region is important for studies in inhalation toxicology but is difficult to prepare for histological examination, especially in species as large as primates. A method for the histologic preparation of undecalcified, complete transverse sections of the nonhuman primate nasal cavity is summarized as follows. After removal of excess soft tissue, mandible and calvaria, the head is fixed in 10% neutral buffered formalin. The nasal region is transversely sectioned into serial 3-mm-thick blocks from the nares to the posterior aspect of the soft palate using a low speed saw with a water-cooled diamond-coated blade. The blocks are embedded in a mixture of glycol and methyl methacrylates, with polyethylene glycol-1500 and dibutylphthalate as plasticizers. The plastic blocks average 5.0 x 5.0 x 1.5 cm; 2-4 microns sections are cut on an automated sliding microtome. In spite of the size of the blocks, this technique yields complete transverse sections of the nasal cavities with excellent morphologic detail. The sections are amenable to a wide range of staining procedures. The procedure lends itself to autoradiographic studies. The embedding mixture is ideally suited for studies of undecalcified bone and teeth.     

Embedding in Epoxy Resins for Ultrathin Sectioning in Electron Microscopy

Fixed tissue is dehydrated with tertiary butyl alcohol overnight. The following day it is cleared in toluene, infiltrated and embedded in Araldite resin-hardener-accelerator mixture without dibutyl phthalate, and polymerized at 60° C. More rapid than previous techniques, this method gives blocks which do not fracture unduly on trimming and provides sections of soft tissues at 1 μ for phase contrast microscopy, as well as ultrathin sections which cut as easily with glass knives as sections of methacrylate. Araldite manufactured in the U.S.A. and in England are different. Satisfactory proportions for the American are: hardener DDSA, 3.5 ml; casting resin 6005, 5.0 ml; accelerator B, 0.12 ml. For the British product, these are: hardener 964 B, 5.0 ml; casting resin M, 5.0 ml; accelerator 964 C, 0.25 ml. The use of 2% agar for orienting small specimens in Araldite is feasible. Mallory's borax-methylene blue has been applied to the staining of Araldite sections as thin as 0.5 μ mounted on glass slides.     

Epoxy Embedding, Sectioning and Staining of Plant Material for Light Microscopy

By using a formula which gives a relatively soft epoxy embedding medium, it is possible to cut sections of plant material with a sliding microtome equipped with a regular steel knife. Blocks having a cutting face of 10 × 10 mm, giving sections of 4-10 μm, can be used. Tissues are fixed in Karnovsky's fluid, postfixed in 1 or 2% OsO₄, embedded in Spurr's soft epoxy resin, Araldite, or Epon mixtures. 5% KMnO₄, followed by 5% oxalic acid, then neutralized in 1% LiCO₃, are used to mordant the sections. Some of the stains used are Mallory's phosphotungstic acid-hemotoxylin, acid fuchsin and toluidine blue, or toluidine blue. Mounting is done with whichever soft epoxy resin was used in casting the blocks.     

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.     

Selection for Electron Microscopy of Specific Areas in Large Epoxy Tissue Sections

Tissue blocks 2 × 2 × 0.4 cm were fixed 6-24 hr in phosphate-buffered 6% glutaraldehyde then sliced to 2 × 2 × 0.1 cm and rinsed in phosphate buffer for at least 12 hr. Fixation was continued for 2 hr in phosphate-buffered 1-2% OsO₄. The slices were dehydrated, infiltrated with Araldite, and embedded in flat-bottomed plastic molds. Sectioning at 4-8 μ with a sliding microtome was facilitated by addition of 10% dibutylphalate to the standard epoxy mixture. The sections were spread on water and attached to coverslips by drying, then heating to 80 C for 1 min. Staining 2 min with 1-3% KMnO₄ and temporary mounting in glycerol on a slide allowed the desired area for electron microscopy to be selected and marked. This area was then cemented to the facet of a conventional epoxy casting with a drop of epoxy resin (without added dibutylphthalate). After polymerization, the coverslip was removed by quick cooling leaving a flat re-embedded portion of the original section. This portion was viewed by transillumination in a dissecting microscope and trimmed of surplus tissue. Ultrathin sections for electron microscopy were obtained in the usual manner.     

Better Epoxy Resin Embedding for Electron Microscopy at Low Relative Humidity

In the absence of other factors known to influence sectioning properties, high environmental relative humidity is shown to yield poorly embedded tissue. Humidity-related effects are avoided if the following embedding precedure is used: impregnate tissues using the following solutions 1) 70% alcohol—5 minutes, 2) 95% alcohol—4 × 15 minutes, 3) absolute alcohol—3 × 40 minutes, 4) acetone—2 × 15 minutes, 5) 1:1 mixture of acetone-epoxy resin (DDSA, 63.4 g; Araldite 502, 5.6 g; Epon 814,39.4 g; DMP-30, 2.6 g)— 1 hour, 6) acetone-epoxy resin 13—1 hour, 7) epoxy resin—1 hour: complete the preparation of blocks as follows 8) when tissues have been oriented in epoxy resin in flat embedding molds, place molds in one evacuated vacuum desiccator 10 cm above a 2 cm layer of Drierite for 24 hours at room temperature, 9) raise temperature to 60 C and maintain for 3 days to cure resin.     

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.     

Preparation of Large Epoxy Sections for Light Microscopy as an Adjunct to Fine-Structure Studies

Tissue blocks 2 × 2 × 0.4 cm were fixed 6-24 hr in phosphate-buffered 5% glutaraldehyde then sliced to 2 × 2 × 0.1 cm and soaked in 0.1 phosphate-buffer (pH 7.3) for at least 12 hr. Fixation was continued for 2 hr in phosphate-buffered 1-2% OsO₄. The slices were dehydrated, infiltrated with Araldite, and embedded in flat-bottomed plastic molds. Sectioning at 1-8 μ with a sliding microtome was facilitated by addition of 10% dibutylphthalate to the standard epoxy mixture. The sections were spread on warm 1% gelatin and attached to glass slides by drying, baking at 60 C, fixing in 10% formalin or 5% glutaraldehyde and baking again. Sections were mordanted in 5% KMnO₄ (5 min), bleached with 5% oxalic acid (5 min) and neutralized in 1% Li₂CO₃ (1 min). Several stains could then be applied: azure B, toluidine blue, azure B-malachite green, Stirling's gentian violet, MacCallum's stain (modified), tribasic stain (modified) and phosphotungstic acid-hematoxylin. Nuclei, mitochondria, specific granules, elastic tissue or collagen were selectively emphasized by appropriate choice of staining procedures, and cytologic detail in 1-3 μ sections was superior to that shown by conventional methods. Selected areas from adjacent 4-8 μ sections could be re-embedded for ultramicrotomy and electron microscopy.     

Double Embedding Broad Thin Leaves in Paraffin

Paraffin pellets were melted in 24 × 24 × 5 mm stainless steel base molds. Specimens of leaves, 18 × 18 mm, were fixed, dehydrated and infiltrated with paraffin. Two specimens were transferred into molten paraffin on their laminar surfaces in a base mold and moved quickly onto a cold surface to cast them in a shallow block of paraffin. Each block was then scored with a razor blade, broken into two primary blocks, and trimmed to 20 × 9 mm with 5 mm flat edges. Each primary block was immersed upright on its long edge in a 22 × 22 × 20 mm Peel-A-Way® embedding mold containing molten paraffin. The leaf edge was held centrally in the mold while moving the double embedment onto a cold surface. In this secondary block, the leaf specimen stood perpendicular to the sectioning surface in perfect orientation for transverse ribbon sectioning. The two phases of paraffin bonded well.     

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.     

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 microns, 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.     

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 microns, 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.     

Ageing domestic sheep (Ovis aries L.) from growth lines in the cementum of the first incisor

First incisor teeth from known‐age domestic sheep were examined to determine whether annual lines developed, and to test 3 processing techniques. Fluorescing lines in undecalcified, unstained transverse sections indicated completed years in 44 % of teeth. Dark lines in decalcified, stained transverse sections indicated completed years in 8 % of teeth. Dark lines seen by reflected light in undecalcified roots ground transversely by hand indicated completed years in 62 % of teeth. Grinding by hand was the simplest, quickest, and most dependable method.     

Histochemical identification of osteoclasts. Review of current methods and reappraisal of a simple procedure for routine diagnosis on undecalcified human iliac bone biopsies

Osteoclasts are known to have a high acid phosphatase content. We have adapted the simple simultaneous mono-coupling azo-dye method of Grogg and Pearse to undecalcified bone sections. A cold embedding in a mixture of glycol and methyl methacrylate was shown to well preserve the enzyme activity. Sodium alpha-naphtyl phosphate (1 mg/ml) and fast violet B (2 mg/ml) are used in 0.1 M acetate buffer, pH 5.0. The addition of 1 mM L(+) sodium tartrate selectively inhibits the acid phosphoprotein phosphatase ("osteoblastic acid phosphatase") but not osteoclastic lysosomal acid phosphatase. Counterstaining with phosphomolybdic aniline blue WS leads to well contrasted sections, providing accurate measurements of osteoclast number.     

Bromodeoxyuridine (BrdUrd) immunohistochemistry in undecalcified plastic-embedded tissue. Elimination of the DNA denaturation step

Summary We examined the application of BrdUrd immunohistochemistry to detect S-phase cells in undecalcified bone and cartilage from the growing rat embedded in Spurr's resin. The effect of fixation on the procedure was studied, and the validity of the technique examined by a comparative study with tritiated thymidine ([³H]-TdR) autoradiography. The use of sodium-ethoxide to remove plastic from tissue sections prior to immunohistochemistry resulted in the production of sufficient ssDNA to make a separate DNA denaturation step unnecessary, thus sparing sections from potentially destructive treatment and shortening the immunohistochemical procedure. Fixation in formalin or Bouin's fluid gave the most satisfactory results. The distribution of BrdUrd labeled cells was restricted to the sites of cell proliferation in growing long bones. Combined studies with BrdUrd immunohistochemistry and [³H]-TdR autoradiography showed that the majority of BrdUrd labeled cells had also incorporated [³H]-TdR, thus attesting to the validity of the technique. This novel approach is suitable for the study of undecalcified hard tissues as well as soft tissues.     

Bromodeoxyuridine (BrdUrd) immunohistochemistry in undecalcified plastic-embedded tissue. Elimination of the DNA denaturation step

We examined the application of BrdUrd immunohistochemistry to detect S-phase cells in undecalcified bone and cartilage from the growing rat embedded in Spurr's resin. The effect of fixation on the procedure was studied, and the validity of the technique examined by a comparative study with tritiated thymidine ([3H]-TdR) autoradiography. The use of sodium-ethoxide to remove plastic from tissue sections prior to immunohistochemistry resulted in the production of sufficient ssDNA to make a separate DNA denaturation step unnecessary, thus sparing sections from potentially destructive treatment and shortening the immunohistochemical procedure. Fixation in formalin or Bouin's fluid gave the most satisfactory results. The distribution of BrdUrd labeled cells was restricted to the sites of cell proliferation in growing long bones. Combined studies with BrdUrd immunohistochemistry and [3H]-TdR autoradiography showed that the majority of BrdUrd labeled cells had also incorporated [3H]-TdR, thus attesting to the validity of the technique. This novel approach is suitable for the study of undecalcified hard tissues as well as soft tissues.     

Low Temperature Sulfation of Tissues and the Demonstration Of Metachromasy

Sulfation of tissue sections which contained nonmetachromatic polysaccharides was done in an equivolume mixture of concentrated sulfuric acid and glacial acetic acid at 0°C. The sections were washed successively in glacial acetic acid and water. Aqueous solutions of toluidine blue, 1.5 × 10^-4 M, were used for staining. The procedure produced a metachromatic substrate in sites previously nonmetachromatic. Normal metachromasy was unaffected. There was no loss, damage or distortion of the tissue sections.     

Evaluation of LR white resin for histology of the undecalcified rat tibia

Histology of plastic embedded undecalcified bone represents a challenging problem to the histotechnologist. We outline here an exploration of LR White resin as a suitable medium for histologic study of undecalcified rat tibia. A procedure was developed for light microscopy of rat tibia embedded in LR White and sectioned by sawing-grinding technics. The specimens were fixed in 10% neutral buffered formalin or alcohol-acetic acid-formol, dehydrated in ethanol, defatted in chloroform followed by resin infiltration and heat-curing of embedded blocks. The procedure of dehydration, defatting, infiltration, and polymerization can be completed within 10 days. Cold curing with accelerator provided by the manufacturer did not yield superior results compared to blocks cured with heat. Thick sections were obtained using a diamond wire saw, attached to plexiform slides, then ground and polished. Surface staining with Von Kossa silver reagent or toluidine blue revealed satisfactory morphological preservation of the mineralized bone sections. Artifacts like small bubbles appeared occasionally and could not be avoided despite prolonged infiltration or cold curing of blocks. Our method is relatively simple for base-line histologic study of rat tibia. The method offers advantages such as easy adaptability, reliable stainability, contrast, and resolution of bone architecture and marrow cells. Two other embedding media, Micro-Bed resin and Unicryl, were also tested, but produced inferior results.     

Staining protocols for human pancreatic islets

Estimates of islet area and numbers and endocrine cell composition in the adult human pancreas vary from several hundred thousand to several million and beta mass ranges from 500 to 1500 mg. With this known heterogeneity, a standard processing and staining procedure was developed so that pancreatic regions were clearly defined and islets characterized using rigorous histopathology and immunolocalization examinations. Standardized procedures for processing human pancreas recovered from organ donors are described in part 1 of this series. The pancreas is processed into 3 main regions (head, body, tail) followed by transverse sections. Transverse sections from the pancreas head are further divided, as indicated based on size, and numbered alphabetically to denote subsections. This standardization allows for a complete cross sectional analysis of the head region including the uncinate region which contains islets composed primarily of pancreatic polypeptide cells to the tail region. The current report comprises part 2 of this series and describes the procedures used for serial sectioning and histopathological characterization of the pancreatic paraffin sections with an emphasis on islet endocrine cells, replication, and T-cell infiltrates. Pathology of pancreatic sections is intended to characterize both exocrine, ductular, and endocrine components. The exocrine compartment is evaluated for the presence of pancreatitis (active or chronic), atrophy, fibrosis, and fat, as well as the duct system, particularly in relationship to the presence of pancreatic intraductal neoplasia. Islets are evaluated for morphology, size, and density, endocrine cells, inflammation, fibrosis, amyloid, and the presence of replicating or apoptotic cells using H&E and IHC stains. The final component described in part 2 is the provision of the stained slides as digitized whole slide images. The digitized slides are organized by case and pancreas region in an online pathology database creating a virtual biobank. Access to this online collection is currently provided to over 200 clinicians and scientists involved in type 1 diabetes research. The online database provides a means for rapid and complete data sharing and for investigators to select blocks for paraffin or frozen serial sections.     

A simple method for preparing thin (10 microM) histological sections of undecalcified plastic embedded bone with implants

A simple method for preparing undecalcified thin sections of bone with implants has been developed. After exposing a surface of bone and implant in a plastic block by sawing thick sections, the surface is stained prior to making a thin section. A glass coverslip is affixed with a thin layer of cement to the stained surface to stabilize the tissue and implant during sectioning. A mixture of glycerine and water is used as a coolant and lubricant. The orientation in situ is preserved allowing demonstration of bone architecture and cells, and the tissue-implant interface.