Increase in the calcium content of cardiac tissue after postfixation with osmium tetroxide

The concentration of osmium has been measured by destructive chemical analysis in glutaraldehyde fixed heart tissue postfixed with osmium tetroxide and embedded in epoxy resin. After such treatment, the mean atomic number of the specimen (Z) is close to 10, which permits a quantitative analysis of calcium (Ca) by the continuum method, using Z2/A as a correcting factor (A: atomic weight). Wavelength-dispersive X-ray microanalysis has been used to determine the Ca concentration of frog cardiac tissue fixed in glutaraldehyde and embedded in resin. These measurements have been repeated on tissue postfixed in osmium tetroxide; contrary to expectations, the apparent Ca concentration is much higher in osmium treated than in nontreated tissue. However, this result is observed with OsO4 solutions prepared in glass, not with solutions prepared in plastic. It is shown by energy dispersive X-ray analysis of droplets that OsO4 solutions prepared in glass contain large amounts of calcium, potassium and silicon. Care must be taken in preparing OsO4 fixatives when the fixed tissues are to be subjected to X-ray microanalysis of such elements as Ca or Si.     

Observations on the Kinetics of Uranyl Acetate and Phosphotungstic Acid Staining of Chromatin in thin Sections for Electron Microscopy

When thin sections of spermatogenic chromatin are fixed with either glutaraldehyde alone or postfixed with osmium tetroxide (OsO₄) and stained with uranyl acetate (UAc) for increasing times, even after as little as 1 min, stain uptake is proportional to section thickness. Greater UAc uptake is observed in chromatin fixed with gutaraldehyde only, but stain uptake is reduced following a long wash with distilled water to a level similar to that seen with postfixed chromatin. Lead citrate poststaining of chromatin fixed with either glutaraldehyde or postfixed with OsO₄ increases UAc uptake by a factor of about 3.

The staining of thin sections of spermatogenic chromatin with ethanolic phosphotungstic acid (PTA) shows a region where stain uptake is proportional to section thickness followed by a plateau. This staining pattern is seen in chromatin fixed with glutaraldehyde alone or postfixed with OsO₄; similar levels for final PTA uptake are also observed.

An increase in the resin content of embedded chromatin postfixed with OsO₄ is proposed to explain the decrease and increase in the rate of migration of UAc and ethanolic PTA staining solutions, respectively.     

ASSOCIATION OF CALCIUM WITH MEMBRANES OF SQUID GIANT AXON : Ultrastructure and Microprobe Analysis

Giant axons from the squid, Loligo pealei, were fixed in glutaraldehyde and postfixed in osmium tetroxide. Calcium chloride (5 mM/liter) was added to all aqueous solutions used for tissue processing. Electron-opaque deposits were found along the axonal plasma membranes, within mitochondria, and along the basal plasma membranes of Schwann cells. X-ray microprobe analysis (EMMA-4) yielded signals for calcium and phosphorus when deposits were probed, whereas these elements were not detected in the axoplasm.     

Observations on the kinetics of uranyl acetate and phosphotungstic acid staining of chromatin in thin sections for electron microscopy

When thin sections of spermatogenic chromatin are fixed with either glutaraldehyde alone or postfixed with osmium tetroxide (OsO4) and stained with uranyl acetate (UAc) for increasing times, even after as little as 1 min, stain uptake is proportional to section thickness. Greater UAc uptake is observed in chromatin fixed with glutaraldehyde only, but seen with postfixed chromatin. Lead citrate poststaining of chromatin fixed with either glutaraldehyde or postfixed with OsO4 increases UAc uptake by a factor of about 3. The staining of thin sections of spermatogenic chromatin with ethanolic phosphotungstic acid (PTA) shows a region where stain uptake is proportional to section thickness followed by a plateau. This staining pattern is seen in chromatin fixed with glutaraldehyde alone or postfixed with OsO4; similar levels for final PTA uptake are also observed. An increase in the resin content of embedded chromatin postfixed with OsO4 is proposed to explain the decrease and increase in the rate of migration of UAc and ethanolic PTA staining solutions, respectively.     

Straight Oso4 versus Glutaraldehyde-Oso4 In Sequence as Fixatives for the Granular Vesicles in Sympathetic Axons of the Rat Pineal Body

Pineal bodies were removed immediately after death from 6 rats: representing both sexes, and adult and 21-day postnatal ages; cut into 2 or 3 pieces, and subjected to experimental fixations at pH 7.3, 0-4 C as follows: 1-2 hr in 1% OsO₄, with veronal-acetate buffer of phosphate buffer; 3-4 hr in 3% or 6% glutaraldehyde in 0.1 M or 0.2 M phosphate buffer, with or without 1% sucrose. Specimens from OsO₄ were dehydrated, and embedded in epoxy resin; those from glutaraldehyde were allowed to soak in buffer for 12-16 hr, then transferred to 1% OsO₄ at 0-4 C for 2 hr, and embedded in the same manner as the ones fixed directly in OsO₄. Representative electron micrographs of postganglionic sympathetic endings were studied for the morphology and frequency of granular vesicles. No consistent difference was shown between vesicles fixed in OsO₄ buffered by phosphate or by veronal-acetate, nor was there any effect caused by the different concentrations used for the glutaraldehyde solution; however, vesicles fixed by the glutaraldehyde-OsO₄ sequence showed an enhancement in the graininess of their membranes, were slightly larger, and had a much larger dense core than those fixed by OsO₄ alone. After glutaraldehyde-OsO₄, granular vesicles showed a frequency of 81%, whereas after direct fixation in OsO₄, only 40% without significant change their number per unit area. Therefore, glutaraldehyde-OsO₄ seems to be more effective than straight OsO₄ for the demonstration of granular vesicles in the autonomic nervous system.     

Improved Lipid Visualization with a Modified Osmium Tetroxide Method Using Ultrasonic Treatment and Intensification with Imidazole or Triazole

Formalin fixed autopsy tissue containing lipids were cut into 1-5 nun thick blocks, washed well, then postfixed in 2% OsO₄ in 0.03 M veronal acetate buffer for 30, 60, 90, 120, or 180 min with or without ultrasonic treatment. Tissues exposed to ultrasound for 90 min showed superior penetration of OsO₄ and well preserved histological architecture. Tissues also were immersed for 1 hr in veronal acetate buffer (pH 7.4) containing 0.5% imidazole or triazole and compared with untreated controls. Paraffin sections, 4 μm thick, were examined under a light microscope with an image analyzer. Both intensity and percentage area of osmium blackening were significantly higher in samples immersed in imidazole or triazole than in untreated controls. No difference was observed between imidazole- and triazole-immersed samples. The OsO₄ method, modified by ultrasound treatment and imidazole- or triazole-immersion, can be applied to routine formalin fixed autopsy materials for improved lipid visualization.     

An Oxidation-Distillation Procedure for Reclaiming Osmium Tetroxide from Used Fixative Solutions

A relatively simple method for recovering more than 80% of the osmium from used fixative solutions as OsO₄ is described. The solutions that we have worked with contained excess FeSO₄, which is added routinely to reduce the tetroxide to the dioxide and make them safe for disposal. The solutions also contained other materials such as cacodylic acid (dimethylarsinic acid), mono-sodium phosphate, sodium veronal (a buffer containing barbital and sodium acetate), NaCl, CaCl₂, various sugars, and such lipids as may have been extracted from animal tissue during fixation.     

Ruthenium Red Stain Able Surface Layer on Lung Alveolar Cells; Electron Microscopic Interpretation

Luft's ruthenium red (RR) method was applied to lung tissue. Small blocks of mouse lung were fixed for 1 hr with 1.2% glutaraldehyde at 0-4 C, buffered with 0.067 M cacodylate, pH 7.3 and containing RR, 1 mg/ml. Following fixation, lung blocks were immersed in 0.15 M cacodylate for 10 min and postfixed for 3 hr at room temperature with 2% OsO₄ buffered with 0.067 M cacodylate, pH 7.3, and containing RR, 1 mg/ml. Blocks were dehydrated with ethanol, embedded in Araldite, and ultrathin sections treated with uranyl acetate and lead citrate solutions to enhance contrast of cell structures. Electron micrographs revealed an electron-dense layer coating the exposed surfaces of alveolar cells. This layer corresponded in location and appearance to that observed by other investigators who used colloidal iron techniques.     

Ruthenium Red-Mediated Osmium Binding for Examining Uncoated Biological Material Under the Scanning Electron Microscope

A simple technique for examining uncoated soft biological material under the scanning electron microscope is described. Rat tissues were initially fixed in 2.5% glutaraldehyde either by intravascular perfusion or by immersion. The samples were placed in buffered 2.5% glutaraldehyde containing 0.05% ruthenium red and postfixed in buffered 1% osmium tetroxide containing 0.05% ruthenium red. The samples were alternately incubated 3 to 5 times in 1% O₃O₄ and 0.1% ruthenium red solutions with continuous shaking at room temperature. The specimens were dehydrated, critical point dried, mounted and examined under the scanning electron microscope. Contour details were clearly defined at both the external and cut surfaces of the tissues. The specimens could be observed for more than 30 minutes without excessive charging or glow effects and the material remained stable under the beam at 20-25 kV and at various magnifications.     

Osmium dependent argentaffin staining of lysosomes

Summary Lysosomes stain with the argentaffin reaction after fixation with glutaraldehyde followed by osmium tetroxide. The reaction works well both at the level of the light and electron microscope. Control experiments show that this argentaffinity is caused by reduced osmium tetroxide. No staining could be observed in freeze-dried material, in tissues fixed only with glutaraldehyde, or after bleaching of the sections with hydrogen peroxide solutions. In the electron microscope, the population of lysosomes appears heterogeneous as related to the density of silver deposits over the organelles. No correlation is found between size and argentaffinity of lysosomes. X-ray microanalysis of sections from glutaraldehyde/osmium tetroxide fixed material reveals significantly higher amounts of osmium in lysosomes, as compared to other cell organelles (e.g. peroxisomes or mitochondria). A significant peak for silver is observed in lysosomes after treatment of the sections with ammoniacal silver solution, whereas the signal for osmium is reduced. Amounts of sulphur are too low to be detected in lysosomes. It is concluded that argentaffin staining of lysosomes is an osmium dependent reaction.Parts of these results have been presented as a poster during the 20th Congress of Electron Microscopy, joint session of the Austrian Society of Electron Microscopy and the German Society of Electron Microscopy, August 23–28, 1981, Innsbruck, Austria     

Ultrastructural localization of calcium in prothoracic gland cells of Galleria mellonella L. (Insecta,Lepidoptera) in relation to secretory activity

Summary Localization of intracellular calcium was demonstrated by precipitation with potassium hexahydroxoantimonate in the fixation medium containing osmium tetroxide or osmium tetroxide and glutaraldehyde. The presence of calcium in the precipitates was confirmed by X-ray microanalysis. Cells from active prothoracic glands contain more calcium deposits than inactive glands. The calcium precipitates are mainly localized in the nucleus, in the smooth endoplasmic reticulum, in the hyaloplasm and to a lesser degree in the mitochondria. These findings are consistent with the proposed role of calcium in the stimulation of steroidogenesis.     

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.     

Pituitary Secretory Granule Topography: Influence of Different Electron Microscopic Preparation Procedures on the Surface of Epon Sections

Human, rat and mouse pituitary tissues have been examined electron microscopically in transmission (TEM), scanning-transmission (STEM) and scanning (SEM) modes for the surface appearance of the secretory granules in tissue sections. Cryofixed and cryosectioned tissue showed only slightly protruding granule profiles which had a smooth surface. Cryofixed, freeze-dried and Epon embedded pituitaries, on the other hand, demonstrated swollen and furrowed surfaces over the granules after contact with water. This topography could also be seen after glutaraldehyde fixation but less after post-fixation in OsO₄. The surface alterations in the sections of pituitary secretory granules are thought to be due to differences in the homogeneity of the resin infiltration, leaving resin-free openings where water can enter. It also seems probable that the Epon resin is more influenced by water than has been previously assumed, based on the findings of efficient elimination of osmium from the granules after incubation of tissue sections in water for only 10 min.     

The Use of Osmium Tetroxide-Potassium Ferrocyanide as an Extracellular Tracer in Electron Microscopy

Secondary treatment of glutaraldehyde fixed liver samples with long term stored solutions of osmium tetroxide and potassium ferrocyanide (Os-Fe) results in tracing of the extracellular spaces of the tissue with an electron opaque substance. This substance does not diffuse across cell membranes, its formation probably being related to the progressive reduction of the O_sO₄ molecule by potassium ferrocyanide. The application of the present method in electron microscopy may be useful in overcoming the artifacts often induced by other tracing techniques such as vascular perfusion with peroxidase or immersion in lanthanum. Although the period of storage of the Os-Fe solution is a clear disadvantage of the method, it seems plausible to anticipate that further studies on the chemical interaction between osmium tetroxide and potassium ferrocyanide will provide us with a Os-Fe mixture having an immediate tracer effect.     

Ultrastructure of dyads in muscle fibers of Ascaris lumbricoides

The dyads of Ascaris body muscle cells consist of flattened intracellular cisternae applied to the sarcolemma at the cell surface and along the length of T-tubules. In specimens prepared by conventional methods (glutaraldehyde fixation, osmium tetroxide postfixation, double staining of sections with uranyl acetate and lead hydroxide), both the sarcolemma and the limiting membrane of the cisterna exhibit unit membrane structure and the space between them is occupied by a layer of peg-shaped densities which is referred to as the subsarcolemmal lamina. The lumen of the cisterna contains a serrated layer of dense material referred to as the intracisternal lamina. In specimens fixed in glutaraldehyde, dehydrated, and then postfixed in phosphotungstic acid, with no exposure to osmium tetroxide or heavy metal stains, the membranous components of the dyads appear only as negative images, but the subsarcolemmal and intracisternal laminae still appear dense. Except for the lack of density in membranes and in glycogen deposits, the picture produced by the latter method is very much like that of tissue prepared by conventional methods.     

Immunocytochemical demonstration of LH-RH, somatostatin, and ACTH-like peptide in osmium-postfixed, resin-embedded median eminence

In guinea pig median eminences that were fixed with a glutaraldehyde paraformaldehyde mixtures, postfixed with osmium tetroxide, and embedded in araldite, immunocytochemical stainings for luteinizing hormone-releasing hormone (LH-RH), somatostatin, and alpha 17-39 ACTH have been obtained on semithin sections. These positive reactions were obtained after araldite was removed with sodium methoxide and after treatment with hydrogen peroxide. These data suggest that osmium tetraoxide postfixation can be used for the detection of low molecular weight peptides such as LH-RH, somatostatin, and ACTH-like-peptides not only in the median eminence but also in the hypothalamus.     

Influence of fixation procedures on the microanalysis of lead-induced intranuclear inclusions in rat kidney

Using Laser Microprobe Mass Analysis (LAMMA), we studied the chemical composition of lead-induced intranuclear inclusions in rat kidney tissue prepared by three different wet chemical fixation procedures for transmission electron microscopy. Fixation with glutaraldehyde-Na2S gave the same results as fixation with glutaraldehyde only: a high lead concentration could be detected. Therefore, for lead strongly bound to proteins, precipitation procedures are not essential. Post-fixation with osmium tetroxide drastically changed the composition of the inclusions: the lead concentration decreased substantially, while sodium, calcium, and barium were introduced. The osmium tetroxide fixative was found to be the source of the contamination. It also contained aluminum, and we suggest that other proteins (e.g., in neurofibrillary tangles) might be able to take up Al out of solution and that care must be exercised in interpreting the microanalytical results of osmium-fixed material. For the microanalysis of the lead inclusions, fixation with glutaraldehyde only provides a good compromise between preservation of the ultrastructure and maintenance of the element distribution.     

Assessment of Demyelination in Glycol Methacrylate Sections: A New Protocol for Cresyl Fast Violet Staining

A simple staining technique for nervous tissue is described. Tissue perfused with glutaraldehyde and formaldehyde and postfixed with osmium tetroxide is embedded in glycol methacrylate. One-micrometer sections are stained with 0.05% cresyl fast violet aqueous solution at 60 C for 5 min, washed with tap water and air dried. With this method the details of all nervous tissue elements are clearly demonstrated. The technique is particularly useful for assessing demyelination because the staining of axoplasm allows demyelinated axons to be well visualized.     

Assessment of demyelination in glycol methacrylate sections: a new protocol for cresyl fast violet staining

A simple staining technique for nervous tissue is described. Tissue perfused with glutaraldehyde and formaldehyde and postfixed with osmium tetroxide is embedded in glycol methacrylate. One-micrometer sections are stained with 0.05% cresyl fast violet aqueous solution at 60 C for 5 min, washed with tap water and air dried. With this method the details of all nervous tissue elements are clearly demonstrated. The technique is particularly useful for assessing demyelination because the staining of axoplasm allows demyelinated axons to be well visualized.     

Intensification of Osmium Staining by p-Phenylenediamine: Paraffin and Epon Embedding; Lipid Granules in Renal Medulla

Tissue which had been fixed in 4% glutaraldehyde and postfixed in 2% OsO₄ was subsequently treated with p-phenylenediamine, either in the block prior to embedding in paraffin or Epon or, in the case of Epon-embedded material, after sectioning for light microscopy. The p-phenylenediamine was best used as a 0.8-1% solution in 70% alcohol. The p-phenylenediamine caused a very considerable intensification of staining of any cell components; this intensification of staining was particularly marked in the case of the lipid granules of renal medulla.