A Rapid Method for Resectioning 0.5-4 μ Epoxy Sections for Electron Microscopy

A simple and rapid method is described for resectioning semithin Epon sections which have been stained for light microscopy, mounted on slides, and examined under immersion oil. The immersion oil is removed with xylene and the section is air dried. A drop of distilled water is applied to the slide and a razor blade is slid under the section. Freed from the slide, the section floats on the surface of the water and is transferred to another drop of water on the surface of a smooth, newly prepared Epon block face. The water under the section is withdrawn with bibulous paper. The section is thoroughly dried and bonded to the block surface by briefly heating in a 60 C oven. The tissue may then be re-sectioned and stained for electron microscopy in the conventional manner. This method has been used by several different technicians to produce ultrathin sections equal in quality to those produced by conventional methods and it greatly facilitates the selection of critical areas for examination by electron microscopy.     

Notes on Technic: “Clearing” Steel Knife Epon Sections in a Polystyrene Film Sandwich

Serial sectioning epoxy embedments by steel knife permits rapid light microscope survey of large tissue volumes, and preselection of areas of interest for electron microscopy. Acetate film (Hollander 1970) and Turtox plastic slides (West 1972) have been suggested as substrates upon which the sections may be “cleared” with an added layer of cured epoxy. In our experience, these substrates are excessively adherent to Epon, and “cleared” sections thinner than 40-50 μm cannot be released from them reliably. The following method is suitable for processing Epon sections 10 or more microns thick.     

Polystyrene embedding: a new method for light and electron microscopy.

Polystyrene embedments of histological specimens can be obtained with a solution of 1:14 polystyrene-toluene, 5% benzyl alcohol and 1% dibutyl phthalate, allowing the solvent to evaporate in polyethylene containers for 2-3 days at 58 C. The resulting blocks are easily cut into truncated pyramids, each containing a piece of tissue, which are then glued to a Plexiglas support. Drying is completed at 80 C for 20 hr. The pyramids can then be sectioned to produce thick sections with a steel knife or to produce semi- or ultrathin sections with a glass knife. A 10% paraldehyde solution is used to mount the light microscopy sections on a slide heated on a hot plate to 80 C; these can be treated with the same techniques used with paraffin sections. The results are of high quality. Semithin sections of tissues fixed for electron microscopy can be stained directly after mounting, or by a wider range of stains once the polystyrene has been removed by organic solvents. In electron microscopy, the ultrathin sections obtained with the usual techniques are highly electron beam-resistant and given acceptable results.     

Polystyrene Embedding: A New Method for Light and Electron Microscopy

Polystyrene embedments of histological specimens can be Obtained with a solution 1 : 4 polystyrene-toluene, 5% benzyl alcohol and 1% dibutyl phthalate, allowing the solvent to evaporate in polyethylene containers for 2-3 days at 58 C. The resulting blocks are easily cut into truncated pyramids, each containing a piece of tissue. which are then glued to a Plexiglas support Drying is completed at 80 C for 20 hr. The pyramids can then be sectioned to produce thick sections, with a steel knife or to produce semi- or ultrathin sections with a glass knife. A 10% paraldehyde solution is used to mount the light microscopy dons on a slide heated on a hot plate to 80 C; those can be treated with the same techniques used with paraffin sections. The results are of high quality. Semithin sections of tissues fired for electron microscopy can be stained directly after mounting, or by a wider range of stains once the polystyrene has been removed by organic solvents. In electron-microscopy, the ultrathin sections obtained with the usual techniques are highly electron beam-resistant and give acceptable results.     

A Simple Method for the Selection of Specific Small Areas of Central Nervous Tissue for Electron Microscopy

An improved modification of an area or cell-selection technique is described. The method involves cutting 2.5-5.0 μm thick plastic sections, mounting than on 0.2 mm acetate sheet, examining them by phase-contrast microscopy, remounting selected sections and cutting these into ultrathin sections. Simplicity and speed are achieved by using acetate sheet instead of the usual glass slides and cover-slips. The method is suitable for topographic localization in small areas of the tissue and especially for the selection of dispersed single cells which are to be examined by electron microscopy.     

Consecutive light microscopy, scanning-transmission electron microscopy and transmission electron microscopy of traumatic human brain oedema and ischaemic brain damage

Cortical biopsies of 11 patients with traumatic brain oedema were consecutively studied by light microscopy (LM) using thick plastic sections, scanning-transmission electron microscopy ((S)TEM) using semithin plastic sections and transmission electron microscopy (TEM) using ultrathin sections. Samples were glutaraldehyde-osmium fixed and embedded in Araldite or Epon. Thick sections were stained with toluidine-blue for light microscopy. Semithin sections were examined unstained and uncoated for (S)TEM. Ultrathin sections were stained with uranyl and lead. Perivascular haemorrhages and perivascular extravasation of proteinaceous oedema fluid were observed in both moderate and severe oedema. Ischaemic pyramidal and non-pyramidal nerve cells appeared shrunken, electron dense and with enlargement of intracytoplasmic membrane compartment. Notably swollen astrocytes were observed in all samples examined. Glycogen-rich and glycogen-depleted astrocytes were identified in anoxic-ischaemic regions. Dark and hydropic satellite, interfascicular and perivascular oligodendrocytes were also found. The status spongiosus of severely oedematous brain parenchyma observed by LM and (S)TEM was correlated with the enlarged extracellular space and disrupted neuropil observed by TEM. The (S)TEM is recommended as a suitable technique for studying pathological processes in the central nervous system and as an informative adjunct to LM and TEM.     

Structural analysis of the mitotic cycle in pre-gastrula Xenopus embryos

The long-known phenomenon of karyomere (chromosome vesicle) formation at early telophase of the nuclear cycle during early embryogenesis of a wide range of organisms including amphibians (Rubaschkin 1905; for review, see Richards 1917) was investigated in the early cleavage cycles of Xenopus laevis embryos before the mid blastula transition. Embryos were fixed and Epon embedded at successive time intervals and consecutive thick (3 m) and ultrathin sections cut. Using conventional light microscopy at low magnification as well as phase and/or interference contrast video microscopy at high magnification, a substantial amount of information could be obtained from the analysis of optical sections in thick-sectioned material. In addition, details of the ultrastructural organization could be analysed from corresponding ultrathin sections by electron microscopy. The light microscopic analysis of serial thick sections allowed precise determination of the arrangement and sizes of telophase karyomere structures during the embryonic nuclear division cycle. It was found that small, widely spaced 1st order karyomeres fuse to larger (2nd order) karyomeres which then progressively exhibit lateral fusion of neighbouring karyomeres. The final coalescence of adjacent karyomeres marks the onset of the reorganization of the typical interphase nuclear structure. The data are discussed with regard to the occurrence of karyomeres during the embryonic nuclear cycle of arthropods, dipteran insects, and echinoderms as well as recent progress in the use of Xenopus egg extracts for in vitro assembly of nuclear structures around protein-free DNA.     

Immunocytochemical localization of cathepsin H in rat kidney. Light and electron microscopic study

Light and electron microscopic localization of cathepsin H in rat kidney was studied using post-embedding immunocytochemical techniques. For light microscopy, Epon sections of the kidney were stained by immunoenzyme method after removal of Epon and for electron microscopy, ultrathin sections of the Lowicryl K4M-embedded material were labeled by protein A-gold (pAg) technique. By light microscopy, fine granular staining was found in throughout the nephron, but the staining intensity considerably varied. The strongest staining was noted in the S1 segment of the proximal tubules followed by the S2 and S3 segments and the medullary collecting tubules. The glomeruli, the distal tubules, and the cortical collecting tubules were weakly stained. By electron microscopy, a gold label was found exclusively in lysosomes, which showed various sizes and labeling intensity. The results were quite consistent with the light microscopic results. The labeling intensity tended to increase as the matrix of lysosomes was condensed. Quantitative analysis of the labeling density of lysosomes demonstrated that the highest labeling density is found in the S1 segment of the proximal tubules and the labeling density of other renal segments is significantly low levels. The results indicate that a main site for cathepsin H in rat kidney is the S1 segment of the proximal tubules.     

Immunocytochemical localization of cathepsin H in rat kidney

Summary Light and electron microscopic localization of cathepsin H in rat kidney was studied using post-embedding immunocytochemical techniques. For ligh microscopy, Epon sections of the kidney were stained by immunoenzyme method after removal of Epon and for electron microscopy, ultrathin sections of the Lowicryl K4M-embedded material were labeled by protein A-gold (pAg) technique. By light microscopy, fine granular staining was found in throughout the nephron, but the staining intensity considerably varied. The strongest staining was noted in the S1 segment of the proximal tubules followed by the S2 and S3 segments and the medullary collecting tubules. The glomeruli, the distal tubules, and the cortical collecting tubules were weakly stained. By electron microscopy, a gold label was found exclusively in lysosomes, which showed various sizes and labeling intensity. The results were quite consistent with the light microscopic results. The labeling intensity tended to increase as the matrix of lysosomes was condensed. Quantitative analysis of the labeling density of lysosomes demonstrated that the highest labeling density is found in the S1 segment of the proximal tubules and the labeling density of other renal segments is significantly low levels. The results indicate that a main site for cathepsin H in rat kidney is the S1 segment of the proximal tubules.     

Wafer embedding: Specimen selection in electron microscopic cytochemistry with osmiophilic polymers

Synopsis A new wafer embedding procedure is described that permits light microscopic screening of embedded tissue prior to ultrathin sectioning. It is particularly valuable when used on specimens obtained with an automatic sectioner and treated cytochemically to obtain visible intermediate or visible and electron opaque final reaction products. Aldehyde-fixed tissues are cut into sections with an automatic sectioner, incubated cytochemically including osmication if required, then embedded in epoxy resin between fluorocarbon-coated coverglasses which are supported by a platform specially designed for this purpose. The resultant wafer, less than 0.2 mm thick, is examined by light microscopy for optimal areas of cytochemical reaction and desirable structural features. Such areas are cut out and glued to blank blocks with fast curing cyanoacrylate cement for subsequent ultrathin sectioning. The usefulness of this technique is demonstrated by the location of: (1) esterase-positive lysosomes in kidney and trigeminal ganglia; (2) palatal sensory endings stained for acetylcholinesterase; and (3) phagosomes arising from the resorption of horseradish peroxidase tracer by the cuboidal parietal epithelial cells of Bowman's capsule in the male mouse.     

Membrane-associated carbonic anhydrase IV in skeletal muscle: subcellular localization

 Carbonic anhydrase IV (CA IV) was examined by light microscopy and electron microscopy in rat soleus muscle. Semithin sections of aldehyde-fixed Epon-embedded muscle were stained with rabbit anti-rat lung CA IV and the avidin-biotin-peroxidase complex. With this technique, capillaries and sarcolemma showed positive CA IV staining. For electron microscopy, rat soleus specimens were aldehyde-fixed, with or without subsequent osmication, and embedded in Epon. Ultrathin sections were immunostained with anti-rat lung CA IV/immunogold. Omitting osmium allowed ample antigen-antibody reactions but could not prevent the release of glycosylphosphatidylinositol-anchored CA IV from the membranes, which led to apparent background staining. Postosmication significantly reduced tissue antigenicity but kept the antigen bound to the membranes and thus allowed a very precise localization of CA IV. By electron microscopy, membrane-bound CA IV is found to be associated with capillary endothelium, sarcolemma, and sarcoplasmic reticulum (SR). Conceivably, the presence of SR staining in ultrathin sections and its absence in semithin sections reflect a problem of accessibility of the antigenic sites. Accepted: 17 May 1996     

Staining of Different Endocrine Cells with Hydrochloric Acid-Toluidine Blue in Epon Embedded Rat Tissue

The usual HCl-toluidine blue staining of different endocrine cells is applicable to paraffin embedded material. A modification for Epon embedded tissue suitable for consecutive light and electron microscopic studies is described which makes it possible to find the same stained cell, both in a semithin section and in subsequent ultrathin sections. This method facilitates the search for scattered specific endocrine cells. Without removing the resin, sections of Epon embedded tissues were hydrolyzed for 17 hr in 1% HCl at 65 C and stained for 2 turn 0.1% toluidine blue in McIlvaine buffer, pH 5.8. The following cells were stained: C cells in thyroid glands; A and D cells in pancreatic islets; B cells in anterior pituitary; G, D and Ec cells in the gastrointestinal tract; Ad cells of the adrenal medulla.     

Staining of different endocrine cells with hydrochloric acid-toluidine blue in Epon embedded rat tissue

The usual HCl-toluidine blue staining of different endocrine cells is applicable to paraffin embedded material. A modification for Epon embedded tissue suitable for consecutive light and electron microscopic studies is described which makes it possible to find the same stained cell, both in a semithin section and in subsequent ultrathin sections. This method facilitates the search for scattered specific endocrine cells. Without removing the resin, sections of Epon embedded tissues were hydrolyzed for 17 hr in 1% HCl at 65 C and stained for 2 hr in 0.1% toluidine blue in McIlvaine buffer, pH 5.8. The following cells were stained: C cells in thyroid glands; A and D cells in pancreatic islets; B cells in anterior pituitary; G, D and Ec cells in the gastrointestinal tract; Ad cells of the adrenal medulla.     

Cerium as amplifying agent--an improved cerium-perhydroxide-DAB-nickel (Ce/Ce-H2O2-DAB-Ni) method for the visualization of cerium phosphate in resin sections

A new visualization (Ce/Ce-H2O2-DAB-Ni) procedure for cerium (Ce III) phosphate in semithin and ultrathin plastic sections (Epon 812, Lowicryl K4M, glycol methacrylate) of rat kidney tissues that had been incubated before embedding for the demonstration of phosphatases (alkaline and acid phosphatase, 5(1)-nucleotidase, Mg-dependent ATPase) is described. For this purpose the hydrophobic Epon resin was removed in NaOH-ethanol solution, whereas the hydrophilic Lowicryl and methacrylate sections did not required any etching. The primary reaction product Ce III-phosphate was amplified in a Ce III-citrate solution, subsequently oxidized with H2O2 and then visualized in a H2O2 containing DAB-nickel medium (Ce IV-perhydroxy induced DAB polymerization principle). The method yielded a very clear localization of enzyme activity. The final reaction product (DAB-nickel polymers) in 0.5 - 2.0 microns semithin sections is blue-black; the background staining is completely prevented. An increase of the staining contrast was obtained by posttreatment with OsO4 (osmium black formation). Furthermore, the enzyme reaction product could be demonstrated in 40 nm thick ultrathin sections by silver intensification, which utilized the high argyrophilia of the polymerized DAB-nickel complexes. This procedure replaces the earlier published technique.     

Multiple correlative immunolabeling for light and electron microscopy using fluorophores and colloidal metal particles.

Multiple correlative immunolabeling permits colocalization of molecular species for sequential observation of the same sample in light microscopy (LM) and electron microscopy (EM). This technique allows rapid evaluation of labeling via LM, prior to subsequent time-consuming preparation and observation with transmission electric microscopy (TEM). The procedure also yields two different complementary data sets. In LM, different fluorophores are distinguished by their respective excitation and emission wavelengths. In EM, colloidal metal nanoparticles of different elemental composition can be differentiated and mapped by energy-filtering transmission electron microscopy with electron spectroscopic imaging. For the highest level of spatial resolution in TEM, colloidal metal particles were conjugated directly to primary antibodies. For LM, fluorophores were conjugated to secondary antibodies, which did not affect the spatial resolution attainable by fluorescence microscopy but placed the fluorophore at a sufficient distance from the metal particle to limit quenching of the fluorescence signal. It also effectively kept the fluorophore at a sufficient distance from the colloidal metal particles, which resulted in limiting quenching of the fluorescent signal. Two well-defined model systems consisting of myosin and alpha-actinin bands of skeletal muscle tissue and also actin and alpha-actinin of human platelets in ultrathin Epon sections were labeled using both fluorophores (Cy2 and Cy3) as markers for LM and equally sized colloidal gold (cAu) and colloidal palladium (cPd) particles as reporters for TEM. Each sample was labeled by a mixture of conjugates or labels and observed by LM, then further processed for TEM.     

Rapid Three-Dimensional Reconstruction at the Light Microscopic Level and a Technique for Re-Embedding the Same Semithin Sections for Electron Microscopic Examination

Rapid three-dimensional reconstruction of serial sections at the light microscopic and ultrastructural levels was accomplished using a two-step technique. Fixed specimens were embedded in Epon and 1 μm sections were cut and placed on glass slides. One of every four sections was drawn onto transparency film for rapid three-dimensional reconstruction. The semi-thin sections were re-embedded in Epon and sectioned at 90 nm for examination in the electron microscopy.     

Use of colloidal gold and ruthenium red in stereo high-voltage electron microscopic study of Con A-binding sites in mouse macrophages

Concanavalin A (Con A)-binding sites were labeled with colloidal gold (CG), stained with ruthenium red, and observed under a high-voltage electron microscope. Mouse peritoneal macrophages were labeled by the indirect Con A/CG labeling method at 0 degree C. After washing, some of the cells were incubated in phosphate-buffered saline (PBS) at 37 degrees C. The specimens were then stained with ruthenium red, to enhance the contrast of the cell surface, and embedded in Epon. Sections (0.3 approximately 3 micron thick) were cut and examined by high-voltage electron microscopy at accelerating voltages of 200 approximately 1,000 kV. Staining with ruthenium red provided a strong contrast of the cell surface and the invaginating tubules beneath it against the cytoplasm; in thick sections, both of them were clearly seen by stereomicroscopy. CG particles which represented Con A-binding sites were also sufficiently electron dense to be recognized by high-voltage electron microscopy of thick sections. The two- and three-dimensional distribution of CG particles on the ruthenium-red-positive cell surface was clearly visualized. At 0 degree C, Con A-binding sites were randomly distributed on the cell surface. The redistribution and endocytosis of Con A-binding sites were seen at 37 degrees C. The three-dimensional organization of membrane invagination, which represented the process of endocytosis, was clearly seen by stereomicroscopy. The combination of CG labeling and ruthenium red staining is a useful method for high-voltage electron microscopic analysis of the two- and three-dimensional distribution of CG-labeled ligands on the cell surface in thick sections.     

Immunocytochemical localization of acid phosphatase in rat liver

Localization of acid phosphatase (ACPase) in rat liver was investigated by immunocytochemical techniques. Rat liver was fixed by perfusion and cut into thick tissue slices, which were embedded in Epon or Lowicryl K4M. For light microscopy (LM), semithin Epon sections were stained for the enzyme ACPase by an indirect immunoenzyme technique. For electron microscopy (EM), ultra-thin Lowicryl K4M sections were stained by a protein A-gold technique. By means of LM, granular reaction deposits were observed in hepatocytes and sinus-lining cells. Stained granules were present in the juxtanuclear cytoplasm, but they did not correspond to a typical staining pattern for the Golgi complex. EM revealed that gold particles indicating ACPase antigens were present on lysosomes and on some vesicles locating in the trans Golgi region. Endosomelike vesicles were strongly positive for the labeling. Golgi cisterna were mostly negative, but weak signals were noted in dilated sacules. The plasma membranes on the sinusoidal and bile canalicular sides were labeled by a few gold particles. The results indicate that ACPase is present in endosomes and in a restricted area of plasma membrane, as well as in the lysosomal system.     

Immunofluorescent staining of Epon embedded kidney sections through simultaneous use of two different fluorochrome-conjugated antisera

Kidney biopsies can be examined in Epon sections for comparison of immunofluorescence and histology. This is possible by an incubation method which has now been modified to allow simultaneous localization of two antigens using fluorescein and rhodamine-conjugated antibodies on the same semithin sections of formalin fixed tissue. Consecutive sections from the same blocks can also be cut for electron microscopy. The method is now used in our immunopathological diagnostic procedures for examination of kidney biopsies.     

A Study of Criteria Permitting the Use of Plastinated Specimens for Light and Electron Microscopy

Plastination permits the preservation of anatomical specimens in a physical state approaching that of the living condition. We studied the possibility of using silicone plastinated fragments of spleen and pancreas for optical and electron microscopy, and found that with an adequate fixation protocol, plastinated specimens can be used for both light microscopy and ultra-structural studies. Deplastination with sodium methoxide permitted production of clean sections. Artifacts produced by plastination/deplastination could be nearly eliminated by glutaraldehyde/formaldehyde fixation. The (Biodur) silicone S10 polymer is transparent and stable in an electron beam, and plastinated tissues can be contrasted or colored similar to tissues embedded in Epon 812. In addition to being very life-like, plastinated tissues are stable and easy to handle. They can also be used for electron and light microscopic studies. This technique may also allow retrospective epidemiological studies of archived pathology specimens.