The influence of embedding media and fixation on the postembedment ultrastructural demonstration of complex carbohydrates. III. High iron diamine staining for sulfated glycoconjugates

The high iron diamine (HID) method for detection of sulfated complex carbohydrate has been applied directly on thin sections of variably fixed tissues embedded in epoxy and nonepoxy resins. Results with postembedment HID staining in mouse intestinal epithelium are compared to those previously obtained using preembedment methods. Sections from epoxy-embedded tissues have been found to exhibit the weakest staining intensity. Intense, specific staining was obtained in tissues not postfixed with osmium tetroxide and embedded in polystyrene, polyester resins, styrene-methacrylate, and especially the styrene-Vestopal W embedding mixture. Postosmication of tissues abolished HID staining in epoxy resins and the styrene-Spurr's resin embedding mixture, but only reduced the staining intensity in tissues embedded in nonepoxy resins.     

Epoxy Resins in Electron Microscopy

A method of embedding biological specimens in araldite 502 (Ciba) has been developed for materials available in the United States. Araldite-embedded tissues are suitable for electron microscopy, but the cutting qualities of the resin necessitates more than routine attention during microtomy. The rather high viscosity of araldite 502 also seems to be an unnecessary handicap. The less viscous epoxy epon 812 (Shell) produces specimens with improved cutting qualities, and has several features—low shrinkage and absence of specimen damage during cure, minimal compression of sections, relative absence of electron beam-induced section damage, etc.—which recommends it as a routine embedding material. The hardness of the cured resin can be easily adjusted by several methods to suit the materials embedded in it. Several problems and advantages of working with sections of epoxy resins are also discussed.     

Light microscopic histochemistry on plastic sections

As compared with conventional paraffin, celloidin, and frozen sections, semithin plastic sections offer a superior quality of the light microscopic image in terms of better resolution, absence of distortion and shrinkage artifacts, and suitability for calcified tissues. Application of histochemical methods to such sections often encounters, however, serious difficulties resulting from a considerably reduced reactivity of plastic-embedded biological material. Factors involved include a poor penetration of reagents into plastic embedding media due to a steric or hydrophobic hindrance, as well as a blockade of the reactive chemical groups in the sample due to interactions with fixatives and plastics. Embedding in polar (hydrophilic) plastics, such as glycol methacrylate, permits carrying out a large number of histochemical reactions, including the demonstration of enzymatic activities, directly on sections, but is less suitable for combined light/electron microscopic studies because of an imperfect ultrastructural preservation of tissues. Embedding in nonpolar epoxy resins, particularly if combined with a double aldehyde-osmium fixation, results in a high quality ultrastructure but almost fully inhibits the histochemical reactivity of the embedded material. In order to restore this reactivity, i.e. to unmask chemical groups bound by the polymerized resin, semithin epoxy sections require the removal of the embedding matrix by alkoxides prior to the histochemical procedure. Additional steps are also often necessary: treatment of osmium-fixed sections with oxidative agents, e.g., hydrogen peroxide or periodate which reoxidize the bound osmium and remove it from tissue, and a controlled proteolytic digestion, especially useful in immunocytochemical studies, which probably cleaves the bonds between the primary aldehyde fixative, and the reactive sites. This article reviews histochemical methods which have been successfully applied to plastic-embedded material. Using polar methacrylates and/or nonpolar epoxy resins as embedding media, it has been possible to demonstrate proteins and aminoacid residues, carbohydrates, lipids, nucleic acids, biogenic amines, inorganic ions, and some enzymes, although the spectrum of methods found as suitable for plastic-embedded material is far narrower than that available for paraffin or frozen sections.(ABSTRACT TRUNCATED AT 400 WORDS)     

Notes on Technic: Simple, Reliable Detection of Latex Microspheres in High Quality Tissue Sections

Latex microspheres used in biological research have been visualized by light microscopy in mounts of cell suspensions, disrupted cells, or cleared tissues (Mishima et al 1987, Koonce et al 1986, LeFevre et al 1978); in unembedded coverslip monolayers (Koerten et al 1980); in fixed (Cornwall and Phillipson 1988) or unfixed (Wells et al 1988) frozen sections; in paraffin sections cleared and deparaffinized with n-butyl alcohol (Callebaut and Meeussen 1989); and in tissues embedded in resins suitable for transmission electron microscopy, such as Spurr's (Hampton et al 1987), Epon (Herzog and Miller 1979), or Ladd Low Viscosity Epon (LeFevre et al 1985). Paraffin embedding, and some plastic embedments, are impractical for demonstration of latex beads because the beads are dissolved by such organic solvents as xylene, dioxane, or chloroform (Van Furth and Diesselhoff-Den Dulk 1980), propylene oxide (Lentzen et al 1984), amyl acetate (Okada et al 1981), or toluene, the solvent in commonly used mounting media such as Fisher Permount (personal observation). The space remaining after dissolution of a bead is not maintained with paraffin embedding as it is with resin embedding. Even after plastic embedding, the resolving power of light microscopes may be inadequate to distinguish such spaces from other spaces found in and between cells. Latex beads are stable in methanol (Van Furth and Diesselhoff-Den Dulk 1980), ethanol. and n-butyl alcohol (Callebaut and Meeussen 1989).     

Assessment of the Acrylic Resin Technovit 7200 VLC for Studying the Gingival Mucosa by Light and Electron Microscopy

Technovit 7200 VLC is an acrylic resin formulated for embedding undecalcified hard tissues which are prepared for light microscopy according to a cutting-grinding technique. To employ this resin for embedding and cutting soft tissues by ultramicrotomy, we carried out a qualitative study on biopsies of canine gingival mucosa using light and transmission electron microscopy. For a critical evaluation of this resin, some biopsies were embedded in Agar 100, an epoxy resin widely used in morphological studies. At the light microscopic level the samples embedded in Technovit 7200 VLC showed good morphology and excellent toluidine blue staining of different cell types and extracellular matrix. At the ultrastrueturallevel, nuclei, cytoplasmic organelles, collagen fibrils and ground substance appeared well preserved and showed high electron density. The acrylic resin was stable under the electron beam and its degree of shrinkage appeared to be very low. We conclude that Technovit 7200 VLC can be employed for ultramicrotomy for both light and electron microscopic investigation of soft tissues.     

Assessment of the Acrylic Resin Technovit 7200 VLC for Studying the Gingival Mucosa by Light and Electron Microscopy

Technovit 7200 VLC is an acrylic resin formulated for embedding undecalcified hard tissues which are prepared for light microscopy according to a cutting-grinding technique. To employ this resin for embedding and cutting soft tissues by ultramicrotomy, we carried out a qualitative study on biopsies of canine gingival mucosa using light and transmission electron microscopy. For a critical evaluation of this resin, some biopsies were embedded in Agar 100, an epoxy resin widely used in morphological studies. At the light microscopic level the samples embedded in Technovit 7200 VLC showed good morphology and excellent toluidine blue staining of different cell types and extracellular matrix. At the ultrastrueturallevel, nuclei, cytoplasmic organelles, collagen fibrils and ground substance appeared well preserved and showed high electron density. The acrylic resin was stable under the electron beam and its degree of shrinkage appeared to be very low. We conclude that Technovit 7200 VLC can be employed for ultramicrotomy for both light and electron microscopic investigation of soft tissues.     

Use of a Technovit 7200 VLC to Facilitate Integrated Determination of Aluminum by Light and Electron Microscopy

Technovit 7200 VLC is an excellent embedding medium for both inorganic histochemistry by light microscopy and X-ray microanalysis by scanning and transmission electron microscopy. Liver samples from rats after intraperitoneal treatment with aluminum chloride were fixed in glutaraldehyde and embedded in the resin. Thick sections were easily cut on an ultramicrotome and stained with aluminon for aluminum (Al). An intense positive reaction with aluminon was observed in the Kupffer cells by light microscopy. The surface structures of the same resin block cut for light microscopy were observed under a scanning electron microscope fitted with an energy dispersive X-ray spectrometer. The Kupffer cells appeared white in the backscattered mode. Localization of Al in the Kupffer cells was confirmed by an X-ray distribution map in the scanning electron microscope. Subcellular localization of Al in the Kupffer cells was performed on the same semithin sections using a transmission electron microscope equipped with an energy dispersive X-ray spectrometer. Most Al was found in lysosomes of the Kupffer cells. The resin was stable in the electron beam and chlorine-free.     

Ultrastructural localization of tubulin and actin in polyethylene glycol-embedded rat seminiferous epithelium by immunogold staining

The polyethylene glycol (PEG) method for immunofluorescence localization of cytoskeletal antigens has been extended to the ultrastructural level using glutaraldehyde-fixed tissues and immunogold staining. Semithin sections of fixed tissue embedded in polyethylene glycol are divested of the PEG, exposed to purified antibodies (e.g., antiactin, antitubulin) and anti-IgG-colloidal gold. The sections may be processed by dehydration and critical-point drying, or reembedment in hydrophilic substances. Tubulin is demonstrated in the mitotic spindles of dividing spermatogonia, manchettes, axonemes and centrioles of developing spermatids, and in the Sertoli cell cytoplasm; actin localization is demonstrated in the myoid cells of the tunica propria, and smooth muscle cells of arterioles in the interstitial tissue. The results demonstrate the applicability and versatility of PEG embedding for immunocytochemistry.     

Immunohistochemistry on Resin Sections: A Comparison of Resin Embedding Techniques for Small Mucosal Biopsies

We have modified resin embedding methods to provide optimal information from en-doscopic biopsies. Mucosal biopsies were fixed either in buffered formalin and processed for embedding in Araldite or in acetone containing protease inhibitors and embedded in glycol meth-acrylate (GMA). GMA embedding generated an im-munophenotypic profile similar to that obtained in frozen sections while yielding far superior morphology and greater numbers of sections from small biopsies. The phenotypic markers included those for T cells, macrophages, mast cells, eosin-ophils and neutrophils. We have also demonstrated collagens, cell adhesion molecules and integrin molecules. Sections of similar quality were obtained with Araldite but the repertoire of antibodies was restricted to those which can be applied to formalin fixed, paraffin embedded tissues. We suggest that for optimal results, small biopsies to be subjected to immunochemistry are fixed in acetone at -20 C with the inclusion of protease inhibitors and embedded in GUIA with careful temperature control.     

Ultrastructural localization of tubulin and actin in polyethylene glycol-embedded rat seminiferous epithelium by immunogold staining

The polyethylene glycol (PEG) method for immunofluorescence localization of cytoskeletal antigens has been extended to the ultrastructural level using glutaraldehyde-fixed tissues and immunogold staining. Semithin sections of fixed tissue embedded in polyethylene glycol are divested of the PEG, exposed to purified antibodies (e.g., antiactin, antitubulin) and anti-IgG-colloidal gold. The sections may be processed by dehydration and critical-point drying, or reembedment in hydrophilic substances. Tubulin is demonstrated in the mitotic spindles of dividing spermatogonia, manchettes, axonemes and centrioles of developing spermatids, and in the Sertoli cell cytoplasm; actin localization is demonstrated in the myoid cells of the tunica propria, and smooth muscle cells of arterioles in the interstitial tissue. The results demonstrate the applicability and versatility of PEG embedding for immunocytochemistry.     

LR White is preferable to Unicryl for immunogold detection of fixation-sensitive nuclear antigens

The purpose of this study was to compare two electron microscopy embedding media - LR White and Unicryl - with regard to cell morphologyical and immunohistochemical preservation properties for the study of fixation-sensitive nuclear antigens. Human cervical carcinoma (HeLa) cells were fixed with 2% paraformaldehyde and 0.1% glutaraldehyde, and embedded in parallel in the two resins: LR White and Unicryl using; two different polymerization protocols were used for each resin. Preservation of fine nuclear structure was good after LR White and poor after Unicryl embedding. Immunogold labeling of Sm antigen was significantly stronger on LR White sections. Polymerization by UV light resulted in stronger and more specific labeling than heat polymerization. These results show that LR White is advantageous over Unicryl for the study of nuclear antigens requiring delicate aldehyde fixation.     

Polychromatic staining of epoxy semithin sections: a new and simple method

A simple, rapid method is described for the polychromatic coloration of semithin sections, which is applicable to material routinely processed for transmission electron microscopy. Material fixed with a glutaraldehyde-paraformaldehyde mixture and postfixed in osmium tetroxide with or without potassium ferrocyanide and embedded in different types of resin (Durkupan-ACM, Spurr resin, Taab resin) can be used. Constant and homogenous results are obtained with this technique, the staining procedure being achieved at room temperature in no more than 10 min. Sections of 0.5–1 m in thickness are oxidised and bleached. After washing, sections are stained in two steps with carbol methylene blue/carbol gentian violet solution and pararosaniline solution. Using the method described in this paper, a polychromatic coloration of the different cells and tissues was obtained (epithelial cells in various shades of blue-violet, connective tissue and elastic laminae of blood vessels in pink or red, etc.). This procedure provides greater contrast between cytoplasm and nuclei, and among the different types of cells and tissues than is seen with toluidine blue, which is very useful for observation and photography of semithin sections. Polychromatic methods found in the literature are normally complex and require a lengthy staining time or cannot be applied on material routinely processed for transmission electron microscopy. Our method is simple, rapid and can be used on any type of material routinely processed for transmission electron microscopy and embedded in epoxy resins.     

Immunocytochemical localization of amylase in gerbil salivary gland acinar cells processed by rapid freezing and freeze-substitution fixation

We examined the immunocytochemical localization of amylase in cryofixed serous acinar cells of gerbil major salivary glands by indirect immunostaining, using anti-gerbil parotid amylase antibody and protein A-gold complex. Fresh tissue blocks were quickly frozen by the metal-contact method, using liquid helium, and were freeze-substituted with either osmium-acetone solution or glutaraldehyde-containing acetone. They were then embedded in an epoxy resin mixture which was polymerized at 60 degrees C. Some tissue blocks substituted with aldehyde-acetone solution were embedded in Lowicryl K4M, polymerized at -30 degrees C. Thin sections of epoxy resin-embedded materials were treated with an oxidizing agent before immunostaining. The labeling density on the materials processed by various protocols for preparatory procedures was quantitatively compared to examine the usefulness of application of cryofixation to immunocytochemistry. The central dense core of heterogeneous secretory granules in the serous acinar cells of the parotid and sublingual glands was heavily labeled with immunogold, regardless of substitution media and embedding resins employed. The immunolabeling pattern clearly distinguished between the dense core and the surrounding matrix. Labeling density in the cryofixed materials was about 1.5 times greater than in those processed by conventional chemical fixation. Seromucous secretory granules in the submandibular gland acinar cells were only faintly labeled. The results obtained indicate that application of immunostaining to quick-frozen, substitution-fixed tissues is useful for high-resolution immunocytochemistry.     

Post-embedding staining with high-iron diamine-thiocarbohydrazide-silver proteinate and its application to visualizing sulfated glycoconjugates in cryofixed kidney and cartilage.

Cryofixation is generally believed to provide optimal tissue preservation. However, certain post-embedding cytochemical reactions, such as high-iron diamine (HID) staining for sulfated glycoconjugates, are not applicable to cryofixed and freeze-substituted tissues. In the present study, the HID technique was therefore adapted for post-embedding staining. HID staining was performed on thin sections of chemically and cryofixed kidney and growth plate cartilage, embedded in Epon and various acrylic-based resins. All resins and most tissue preparation conditions allowed post-embedding staining with HID, albeit to variable degrees. However, no significant cytochemical reaction was obtained with tissue sections of osmicated kidney embedded in Epon. Profile views of re-embedded sections showed that large stain deposits were usually restricted to the surface, whereas small ones were observed throughout the entire thickness of the section. The staining pattern was essentially similar between chemically fixed and cryofixed specimens. In the glomerulus, stain deposits were mainly seen over the free surface of podocyte foot processes and over the lamina rara externa. The pericellular cartilage matrix of chemically fixed specimens often appeared as condensed elements, usually stained with large deposits. In cryofixed tissues this matrix formed a meshwork composed of thin, extended filamentous structures, many of which showed linear arrays of smaller stain deposits. The data presented here indicate that post-embedding HID-TCH-SP staining can be successfully performed on thin sections of tissues embedded in various resins and, as a result, can be further adapted to cryo-prepared specimens to give a high resolution localization of sulfated glycoconjugates in tissues with optimal molecular preservation.     

Histochemical and immunohistochemical protocols for routine biopsies embedded in Lowicryl resin

Tissue processing and analysis require good preservation of both the shape and content of cells. Lowicryl resin is one of the few embedding media that allow good preservation of both tissue architecture and cellular contents. Therefore, different histochemical and immunohistochemical reactions can be applied to semithin sister sections from one biopsy. Further examination of a zone of interest can be carried out under the electron microscope. The hydrophilic property of Lowicryl resins makes possible different histochemical reactions; however, the technique used for paraf?n sections must be adapted for each reaction. Antigenic preservation of cells by low temperature embedding allows immunolabeling on either semithin sections or in the zone of interest on ultrathin sections. We have shown the application and adaptation of different histochemical and immunohistochemical reactions on semithin and ultrathin sections from hepatic biopsies that were large, but thin. The variety of techniques that can be used on sister Lowicryl sections of a single biopsy makes this medium useful for extensive pathological studies of precious needle biopsies.     

Light and electron microscopical postembedding lectin histochemistry for WGA-binding sites in the renal cortex of the mouse embedded in polyhydroxy aromatic resins LR-White and LR-Gold

Summary This work describes a technique which permits study of the postembedding lectin histochemistry for WGA-binding sites at the light and electron microscopical level on the same resin embedded tissue without removing or etching of the resin. Unfixed kidney pieces or kidney pieces fixed in 4% formaldehyde were embedded in the hydrophilic polyhydroxy aromatic resins LR-Gold and LR-White, following dehydration in up to 70% ethanol, 90% ethanol or 100% ethanol. LR-Gold was cryopolymerised at –25° C using the light sensitive initiator benzil, whereas LR-White was heat-cured at +50° C. The localisation of WGA-binding sites at the light microscopical level was investigated using FITC-labelled WGA. The ultrastructural localisation of WGA-binding sites was performed using 15 nm gold-labelled WGA. The best fluorescence staining results were obtained on fixed or unfixed tissue dehydrated in up to 70% ethanol and embedded in LR-Gold. At the ultrastructural level, the best staining results for WGA-binding sites were seen on tissue sections, dehydrated in up to 90% ethanol prior to embedding in LR-Gold.     

Light and electron microscopical postembedding lectin histochemistry for WGA-binding sites in the renal cortex of the mouse embedded in polyhydroxy aromatic resins LR-White and LR-Gold

This work describes a technique which permits study of the postembedding lectin histochemistry for WGA-binding sites at the light and electron microscopical level on the same resin embedded tissue without removing or etching of the resin. Unfixed kidney pieces or kidney pieces fixed in 4% formaldehyde were embedded in the hydrophilic polyhydroxy aromatic resins LR-Gold and LR-White, following dehydration in up to 70% ethanol, 90% ethanol or 100% ethanol. LR-Gold was cryopolymerised at -25 degrees C using the light sensitive initiator benzil, whereas LR-White was heat-cured at +50 degrees C. The localisation of WGA-binding sites at the light microscopical level was investigated using FITC-labelled WGA. The ultrastructural localisation of WGA-binding sites was performed using 15 nm gold-labelled WGA. The best fluorescence staining results were obtained on fixed or unfixed tissue dehydrated in up to 70% ethanol and embedded in LR-Gold. At the ultrastructural level, the best staining results for WGA-binding sites were seen on tissue sections, dehydrated in up to 90% ethanol prior to embedding in LR-Gold.     

Histochemical and immunohistochemical protocols for routine biopsies embedded in Lowicryl resin.

Tissue processing and analysis require good preservation of both the shape and content of cells. Lowicryl resin is one of the few embedding media that allow good preservation of both tissue architecture and cellular contents. Therefore, different histochemical and immunohistochemical reactions can be applied to semithin sister sections from one biopsy. Further examination of a zone of interest can be carried out under the electron microscope. The hydrophilic property of Lowicryl resins makes possible different histochemical reactions; however, the technique used for paraffin sections must be adapted for each reaction. Antigenic preservation of cells by low temperature embedding allows immunolabeling on either semithin sections or in the zone of interest on ultrathin sections. We have shown the application and adaptation of different histochemical and immunohistochemical reactions on semithin and ultrathin sections from hepatic biopsies that were large, but thin. The variety of techniques that can be used on sister Lowicryl sections of a single biopsy makes this medium useful for extensive pathological studies of precious needle biopsies.     

A Simple Methylene Blue-Azure Ii-Basic Fuchsin Stain for Epoxy-Embedded Tissue Sections

One micron-thick sections of tissues fixed in glutaraldehyde, or in glutaraldehyde followed by osmium tetroxide, and embedded in a variety of plastic resins were stained in a methylene blue-azure II solution at 65 C, then counterstained in 0.05% basic fuchsin in 2.5% ethanol at room temperature (24 C). Considerable variation was found in methylene blue-azure II staining times for different embedding media. Aged Epon-812 required less staining time than freshly polymerized blocks of Epon-812. The procedure is a simple, rapid staining technique suitable for photomicrography and tissue orientation for electron microscopy.     

A new method for transfer of polyethylene glycol-embedded tissue sections to silanated slides for immunocytochemistry

Polyethylene glycol (PEG) is an excellent embedding medium for immunohistochemical studies. It provides structural preservation superior to frozen sections and increased sensitivity of antigen detection compared with paraffin sections. One limitation of PEG embedment is that PEG sections are difficult to handle and adhere poorly to glass slides. Here we present a simple and effective method for embedding tissues in PEG and transferring the resultant sections onto silanated glass slides. In addition, a method for silver enhanced colloidal gold immunostaining was combined with common dye staining to demonstrate the excellent structure preservation and sensitive antigen detection. Bovine chorionic membrane was fixed with Bouin's fixative, embedded in polyethylene glycol (PEG) 1500, cut into 5-microns sections, flattened over agarose blocks (10 x 10 x 2 mm3), and blotted onto Digene silanated slides. Slides were then washed in PBS, which removed the PEG and agarose blocks. Tissue sections were immunocytochemically stained with dilute antiserum raised in a rabbit against purified bovine placental retinol binding protein (bpRBP). Sections were washed and incubated with 1-nm colloidal gold-labeled goat anti-rabbit IgG. The immunogold particles were enhanced by silver staining (IGSS). Specimens were observed and photographed with an Olympus epipolarization microscope. The new method offered excellent morphological preservation of cell structure and the epipolarization microscopy provided high sensitivity for detection of specific immunogold-silver particles.