Simultaneous fixation using glutaraldehyde and osmium tetroxide or potassium ferricyanide-reduced osmium for the preservation of monogenean flatworms: an assessment for Merizocotyle icopae

Simultaneous fixation was investigated for a marine organism: the monogenean flatworm ectoparasite Merizocotyle icopae. Four protocols for primary fixation were compared: 3% glutaraldehyde alone in 0.1M cacodylate buffer for a minimum of 2 hours; 1% glutaraldehyde in combination with 1% osmium tetroxide, both in 0.1M cacodylate buffer, until tissues darkened (5-20 minutes); 1% glutaraldehyde in 0.1M cacodylate buffer in combination with 0.5% potassium ferricyanide-reduced osmium until tissues darkened (5-20 minutes); 1% glutaraldehyde in combination with 1% osmium tetroxide, both in 0.1M cacodylate buffer, for 30 minutes. The study confirms that the standard method for transmission electron microscopic fixation (first listed protocol) routinely applied to platyhelminths is optimal for ultrastructural preservation, but some simultaneous fixation methods (second and third listed protocols) are acceptable when rapid immobilization is needed. Scanning electron microscopic preparations may be improved using simultaneous primary fixation.     

Effects of fixation on electrophysiology and structure of human jejunal villi

The villi of human jejunum vary in size and shape during different functional conditions. In the base the lamina propria is isotonic with blood, in the tip hyperosmotic. Here we study electrophysiological and morphological effects of incubation in hypotonic, isotonic, or hypertonic solutions, and to test various isotonic fixatives for microscopy. Samples of jejunal mucosae, obtained during surgery in obese patients, were studied in Ussing chambers where electrical parameters were registered during incubation in Krebs solution at various osmolarities, and during fixation in formaldehyde, glutaraldehyde, or osmium tetroxide (OsO₄). The same fixatives were used for other jejunal specimens that were fixed directly for light microscopy. Morphometry was carried out to determine size and height of villi, proportion of lamina propria, and surface enlargement due to villi. Ussing chamber incubation in fluids with low osmolarity resulted in increased electrical resistance and epithelial swelling. Opposite results were obtained at high osmolality. Fixation was faster in formaldehyde than in glutaraldehyde or OsO₄. In biopsies processed directly for light microscopy the proportions of lamina propria of the mucosa, and of lamina propria of villi, were significantly larger in biopsies fixed in formaldehyde than after fixation in glutaraldehyde or OsO₄. The villus tips sometimes ended with a bleb with prominent spaces between the epithelial cells. In summary, jejunal villi swell in vitro when exposed to hypotonic solutions, and shrink in hypertonic solutions. Much of the morphological changes occurring during fixation can be related to the physiological hyperosmolar milieu in villus tips.     

Ultrastructural morphology and allergen detection in birch pollen after aqueous, anhydrous-liquid, and vapor fixation techniques.

In order to find a good compromise between preservation of ultrastructural morphology and retention of antigenicity, birch pollen grains were chemically fixed in aqueous p-formaldehyde or glutaraldehyde, in p-formaldehyde or glutaraldehyde dissolved in anhydrous glycerol, and in p-formaldehyde or glutaraldehyde vapor. Representative cytoplasmic areas were inspected for the preservation of ultrastructural morphology and for their capacity to bind a monoclonal antibody against Bet v I, the major birch pollen allergen. The experiments showed that cytoplasmic morphology was best preserved after vapor fixation in p-formaldehyde. This fixation also led to the highest degree of specific antibody binding.     

Effect of sodium azide on the ultrastructural preservation of tissues.

An electron microscopic study was carried out to examine the quality of ultrastructural preservation of parenchymatous and mesenchymatous tissues and isolated cells fixed in glutaraldehyde with sodium azide (NaN3) as an additive. The dense tissues fixed with conventional glutaraldehyde containing calcium chloride demonstrated only a narrow zone of good tissue preservation on the surface of the specimens. Addition of azide at a concentration of 0.1% greatly improved the cellular preservation in the deeper region of tissues, in particular with respect to the mitochondrial morphology. There was no adverse effect on other cell organelles. The improvement in mitochondrial preservation and the enhancement of penetration of the fixative is presumably due to selective and instantaneous inhibition of mitochondrial metabolic activity by the azide, thus retarding anoxic degenerative effects on cellular structures until permanent fixation is completed by the comparatively slow-acting aldehyde. However, the addition of azide offers no significant improvement in the ultrastructural preservation of isolated lymphocytes and liver cells, or fibroblasts maintained in culture.     

Penetration rate of glutaraldehyde in various buffers into plant tissue and gelatin gels

The choice of buffer vehicle during fixation with glutaraldehyde influences not only the rate of crosslinking in a bovine serum albumin model system, but also the penetration rate of the glutaraldehyde into plant tissue and gelatin gels. The rate of penetration into plant tissue and the crosslinking rate of bovine serum albumin by glutaraldehyde are independent of each other in any one buffer. Buffer penetration into gelatin gels is not as fast as glutaraldehyde penetration into the same gels. The highest rate of crosslinking of bovine serum albumin by glutaraldehyde is obtained with a buffer vehicle consisting of Na₂HPO₄ and NaH₂PO₄. Glutarldehyde concentrations of 2–3% are advised for routine fixation of plant material.     

Ultrastructural localization of nucleic acids in plant tissues following the use of malachite green or neutral red in the fixative solution

Malachite green and neutral red, when added to glutaraldehyde for fixation of various tissues, yielded high-contrast images of cell ultrastructure. Malachite green, in acid conditions, appeared to increase contrast of heterochromatin material in the nucleus whereas neutral red gave greater clarity to the nucleolus and to cytoplasmic ribosomes. Control tissue fixed under acid conditions showed little damage but there were ‘crystalline’ areas at the periphery of the nucleolus. RNase did not digest cytoplasmic ribosomes from tissue after neutral red glutaraldehyde fixation. These results suggested that neutral red became bound to RNA in the tissues. Fixation with malachite green, at a pH below 6, did not affect the digestion of RNA by RNase but did protect chromatin against the bleaching action of the chelating agent EDTA. The addition of malachite green (pH < 6) or neutral red to glutaraldehyde are useful techniques for the investigation of the ultrastructure of nuclear material and cytoplasmic ribosomes.     

Lanthanum probing of cell membrane permeability in the rat heart: Pathological versus artefactual alterations

The influence of fixation on membrane permeability has been examined in the isolated rat heart using lanthanum as a permeability probe. Normal and ischaemic hearts were probed at various stages during a conventional fixation programme with either ionic or colloidal lanthanum and compared with lanthanum saline administered prior to fixation. Fixation of the myocardium coincident with or followed by lanthanum probing resulted in an influx of the probe into most myocytes in normal tissue. Alterations in permeability after ischaemic episodes could not be distinguished from this artefact. However, lanthanum saline prior to fixation showed exclusion of the probe from normal tissue, while the increased permeability demonstrated after ischaemia was associated with declining myocardial performance during subsequent reperfusion. These results illustrate the need for caution in the application and evaluation of methods determining permeability in fixed tissue. Probes of differing size and charge permeated fixed tissue to varying degrees thereby implicating the formation of specific lesions during chemical fixation.     

Use of a pressure-sensitive radiotelemetering capsule to study the canine gastric interdigestive complex

An inexpensive pressure-sensitive radiotelemetering capsule, transmitting at 100 MHz, was used to study gastric interdigestive complexes. The oscillator was frequency modulated; pressure changes on a rubber diaphragm caused displacements of a ferromagnetic core altering the frequency of oscillation by modifying the inductance in the circuit. The system was linear for applied pressures up to 40 mm of Hg; for 40 mm Hg the frequency decreased by 22 kHz. Three fasted dogs were used; an encapsulated radio pill picked up the presence fluctuations associated with gastric contractions and transmitted these signals as radio waves. An FM receiver intercepted, amplified, and relayed the signals to a chart recorder, which produced a permanent record. During the first part of each 24-hour recording period, cyclical interdigestive patterns consisting of a series of high-amplitude contractions followed by long-lasting quiescence were recorded. Regular outbursts showed mean durations ranging from 11.6 to 17.6 minutes, mean periods from 27 to 51 minutes, and mean amplitudes from 9.9 to 11.1 mm Hg. Noncyclical, irregular recordings were obtained during the last part of each recording period. These results are similar to ones obtained using force transducers.     

A method for preparing quick-frozen,freeze-substituted cells for transmission electron microscopy and immunocytochemistry

A quick-freeze, freeze-substitution method is described which employs glutaraldehyde as well as osmium tetroxide (OsO₄) in a ‘double-fixation’ protocol comparable to that used for conventional transmission electron microscopy. Cultured cells are quick-frozen in Freon 22 and freeze-substituted in an ethanolic solution of glutaraldehyde. Specimens destined for TEM are postfixed in OsO₄ in acetone, embedded in Epon-Araldite, and sectioned. This method yielded ultrastructural preservation which was comparable to that obtained from methods employing OsO₄ alone as a freeze-substitution fixative. However, if glutaraldehyde is used alone as a freeze-substitution fixative, specimens can be processed for immunocytochemistry without additional treatment with permeabilizing agents.     

The effects of osmium tetroxide post‐fixation and drying steps on leafy liverwort ultrastructure study by scanning electron microscopy

Leafy liverwort is one of the most abundant and diverse plants in Indonesia. Their high variation and beneficial secondary metabolites contained in the oil bodies have attracted researchers' attention. The ultrastructural analysis of leafy liverworts is important as a means of species identification and also for further exploration of their oil bodies. However, the optimization of the preparation steps for observing leafy liverworts by SEM is necessary to avoid sample destruction. Fixation and drying play important roles in maintaining a sample's structure as close to its natural state as possible. Thus, in this study, we evaluated the effect of 4% Osmium tetroxide (OsO₄) and drying on leafy liverworts ultrastructure. Microlejeunea, Acrolejeunea, and Frullania were fixed with 2.5% glutaraldehyde. Some samples were then post‐fixed with 4% OsO₄, while the rest were directly dehydrated with an ethanol series and then subjected to different drying methods, i.e. air drying, freeze drying, and drying with hexamethyldisilazane (HMDS). According to the data obtained, post‐fixation with 4% OsO₄ could better maintain the integrity of the samples and enhance the contrast of leafy liverwort SEM images. In addition, samples dried with HMDS showed more detailed structures compared to those that were air dried. Different ultrastructure were found among the different leafy liverworts observed by SEM. Our data suggested the advantages of SEM in providing ultrastructure information on leafy liverworts as well as the optimum conditions to observe them with less deformation. OsO₄ post‐fixation could enhance the contrast of leafy liverwort SEM images and maintain the structure of the samples. Drying with HMDS provided a convenient way for rapid SEM preparation with less structural distortion.     

Isolated heart myocytes: ultrastructural case study technique

We have developed a method for performing case studies of heart muscle cells enzymatically isolated from the ventricular walls of rats that is a simple and inexpensive adaptation of procedures developed for the examination of monolayers of attached, cultured cells. The technique represents a marked departure from published accounts of electron microscopic studies of pellets or monolayers from a population of potentially heterogeneous isolated myocytes. Here we report the method, which we have used under controlled conditions with 0 mmol and 1 mmol added CaCl₂, to correlate sarcomere length and electrical stimulatibility in the living state with ultrastructural features that include the relative disposition of myofilaments and the integrity of the cell coat. The degree of shrinkage during the preparative steps is less than 5%, as directly determined from photographs of striations in the living, fixed, and embedded states.     

Microvascular casting of the lung: Effects of various fixation protocols

Although techniques for preparing specimens for light and electron microscopy are well established, few studies have sought to establish methods for corrosion casting of the microscopic vessels of the lung. The effects of two concentrations of glutaraldehyde, formaldehyde, and no fixative (saline control) on the filling and structure of the microvascular casts of the lung were studied. All fixatives were infused 5 minutes before casting. Formaldehyde's fixation effects were intermediate between those of glutaraldehyde and no fixation. Leakage of casting material was increased in the animals that were fixed less. Digestion time was prolonged and more undigested tissue was found in the group receiving the concentrated glutaraldehyde, although the difference in neither of these features alone reached statistical significance. Circumferential bands occurred more frequently in the large vessel casts of the less fixed animals, which may account for the less filling microvasculature in these lungs. However, good quality casts were obtained with each method.     

Critical-point drying versus freeze drying for scanning electron microscopy: a quantitative and qualitative study on isolated hepatocytes

Critical-point drying and freeze drying were compared both quantitatively and qualitatively as preparative procedures for scanning electron microscopy. Isolated hepatocytes were used as model cells. Nomarski differential interference contrast microscopy was used for light microscopic measurements of the hepatocytes in the unfixed, the glutaraldehyde fixed, the glutaraldehyde + OsO₄ fixed, the critical-point dried and the freeze dried states. Critical-point dried hepatocytes were found to shrink to 38% of glutaraldehyde + OsO₄ fixed volume, whereas optimal freeze dried hepatocytes (frozen in water saturated with chloroform and freeze dried at 183 K for 84 h) were found to shrink to 51% of glutaraldehyde + OsO₄ fixed volume. Transmission and scanning electron micrographs of the critical-point dried cells showed well-preserved ultrastructure and surface structure. Micrographs of the freeze dried cells showed ultrastructure destroyed by internal ice crystals and surface structure destroyed by external ice crystals. Double-fixed isolated hepatocytes were shown to swell during storage in buffer and to shrink during storage after critical-point drying. For low magnification scanning electron microscopy (up to about 3000 times) both critical-point drying and freeze drying can be used. However, for high magnification scanning electron microscopy, critical-point drying is superior to freeze drying.     

Extraction of membrane lipids during fixation,dehydration and embedding of Acholeplasma laidlawii-cells for electron microscopy

The aim of the present investigation was to study the extent to which lipids are extracted from biological membranes during dehydration and embedding procedures carried out at high or low temperatures. Cells of Acholeplasma laidlawii were used as experimental material, since the lipids of this bacterium easily can be radioactively labelled without labelling the rest of the cell, and the lipids are almost entirely located in the cytoplasmic membrane. The cells were fixed at 277 K with glutaraldehyde, sequentially with this reagent and osmium tetroxide, or with glutaraldehyde, osmium tetroxide and uranyl acetate in that order. Loss of lipid during these procedures was negligible. When cells fixed with glutaraldehyde and osmium tetroxide were dehydrated with ethanol at room temperature and embedded in Epon at 333 K, i.e. subjected to a conventional treatment, about 90% of the lipid content of the cells was extracted. The loss was reduced to c. 20% when treatment with uranyl acetate was included in the procedure and the non-polar methacrylate resin Lowicryl HM20 was substituted for Epon. When cells fixed with glutaraldehyde and osmium tetroxide were dehydrated with ethanol at 238 K and embedded in Lowicryl HM20 at room temperature, practically no lipid was extracted. Substitution of the polar methacrylate-acrylate resin Lowicryl K4M for Lowicryl HM20 resulted in the loss of about half of the lipid content of the cells. The use of ethanediol as dehydrating agent instead of ethanol did not diminish the extraction. Cells fixed solely with glutaraldehyde lost about half of their lipid content, even when both dehydration and embedding was performed at 238 K. The lipid material extracted from glutaraldehyde-fixed cells contained slightly more saturated fatty acids than that remaining in the cells. The reverse was true for osmium tetroxide-fixed cells. With respect to lipid species, the extractions were generally rather unspecific.     

Coated abrasive machining of 1018 steel, 1095 steel and 304 stainless steel at moderate to high rates of stock removal using a buffered tri-potassium phosphate solution

A coated abrasive machining method that results in moderate to high metal removal rates was used in evaluating a 10% aqueous solution of K₃PO₄ as a grinding aid. The K₃PO₄ solution was buffered with NaH₂PO₄ to reduce its caustic nature and to add additional phosphate ions to increase the grinding aid effect. Tests run on 1018 steel, 1095 steel and 304 stainless steel at three rates of metal removal show that the phosphate solution increases the amount of metal that can be removed with an abrasive belt over that removed in dry grinding or with some commonly used watersoluble commercial lubricants. By reducing the rate of mineral wear on the belt, the K₃PO₄ solution both increases belt efficiency and reduces thermal surface damage to the workpiece.     

Nitric oxide averts hypoxia-induced damage during reoxygenation in rat heart

Nitric oxide (NO), synthesized by the hemoproteins NO synthases (NOS), is known to play important roles in physiological and pathological conditions in the heart, including hypoxia/reoxygenation (H/R). This work investigates the role that endogenous NO plays in the cardiac H/R-induced injury. A follow-up study was conducted in Wistar rats subjected to 30 min of hypoxia, with or without prior treatment using the nonselective NOS inhibitor L-NAME (1.5 mM). The rats were studied at 0 h, 12 h, and 5 days of reoxygenation, analysing parameters of cell, and tissue damage (lipid peroxidation, apoptosis, and protein nitration), as well as in situ NOS activity and NO production (NOx). The results showed that after L-NAME administration, in situ NOS activity was almost completely eliminated in all the experimental groups, and consequently, NOx levels fell. Contrarily, the lipid peroxidation level and the percentage of apoptotic cells rose throughout the reoxygenation period. These results reveal that NOS inhibition exacerbates the peroxidative and apoptotic damage observed before the treatment with L-NAME in the hypoxic heart, pointing to a cardioprotective role of NOS-derived NO against H/R-induced injury. These findings could open the possibility of future studies to design new therapies for H/R-dysfunctions based on NO-pharmacology.     

An X-ray microscopy perspective on the effect of glutaraldehyde fixation on cells

X-ray microscopy (XRM) is the only microscopy technique that can provide high-resolution (30 nm) imaging of biological specimens without the need to fix, stain or section them. We aim to determine the effect, if any, of glutaraldehyde fixation on algae cells from the XRM perspective and thus provide beneficial information for both X-ray and electron microscopists on artefacts induced by glutaraldehyde fixation. Three species of microalgae, Microcystis aeruginosa, Anabaena spiroides and Chlorella vulgaris, were used in this study. XRM images were obtained from unfixed and glutaraldehyde-fixed cells and cell diameter and percentage X-ray absorbency were measured. The mean diameter of cells from fixed preparations was smaller than from unfixed preparations; the mean diameter of M. aeruginosa cells was significantly reduced from 3.92 µm in unfixed cells to 3.43 µm in fixed cells (P < 0.05); in C. vulgaris the diameter of cells was also significantly reduced from 3.50 µm in unfixed to 2.98 µm in fixed samples (P < 0.05); whereas there was no significant reduction in the diameter of A. spiroides cells (4.04–3.90 µm). The protein crosslinking mechanism of glutaraldehyde probably generated free water molecules, which play an important role in radiation damage induced by X-rays. This was seen as mass loss and cell shrinkage, which in the present study occurred more frequently in fixed cells than in unfixed cells. In addition, we demonstrated that the uptake of glutaraldehyde by cells makes all protein constituents in the cell organize into a closely packed configuration, thus causing a rise in the percentage of X-ray absorbency. In fixed cells, this rise was approximately by a factor of two compared with unfixed samples in which protein constituents inside the cell are arranged in their native form.     

Quantitative assessment of chemical fixation,including the use of malachite green,for electron microscopy of vacuolate mesophyll cells from leaves of a grass

Various chemical fixation regimes were studied using leaves of the grass Lolium multiflorum Lam. as a test system. To evaluate the quality of fixation for electron microscopy two parameters were chosen; the extent of cell damage to mesophyll cells and damage and change in size of chloroplasts. Reducing the concentration of glutaraldehyde from 3% to 1% resulted in extensive cell damage. The addition of paraformaldehyde to 1% glutaraldehyde did not totally eliminate cell damage and resulted in dilation of thylakoids within the chloroplasts. In tissue fixed and washed in solutions matched to the total osmolality of the primary fixative solution there was little cell damage but the chloroplasts were larger, diameters 4.5times2.9 μm, than when only the buffer vehicle osmolality was maintained during subsequent washings, diameters 3.5times1.6 μm. Malachite green added to the primary fixative solution abolished cell damage regardless of buffer concentration and resulted in the appearance of osmiophilic droplets on the surface of and within the chloroplasts which were not present in the absence of malachite green. It is suggested that malachite green stabilizes cell membranes during primary fixation.     

Volume changes during preparation of mouse embryonic tissue for scanning electron microscopy

This paper describes the results of experiments in which the volume changes in mouse embryo limb samples were followed more or less continuously after fixation through dehydration and critical point drying, with in some instances data relating to post critical point drying shrinkage. 14 and 15 day p. c. mouse embryos were fixed in 3 % glutaraldehyde in cacodylate buffer and stored in this fixative until use. Single specimens were studied using a Quantimet image analysing computer to record the changes in projected area of the unmounted specimens as they were passed through the usual series of reagents according to various commonly used dehydration schedules. The area changes were converted to volume changes for the purposes of presentation in this paper. The Quantimet system could not be used to follow volume changes in the CPD bomb so that most experiments detail the volume in the intermediate fluid before CPD and the size of the specimen immediately after it was removed from the CPD bomb. A few experiments were conducted in which the specimens were measured whilst they were in the CPD bomb. The measurements relating to dehydration and CPD procedures were compared with measurements of air dried and freeze dried specimens. All three drying methods cause considerable shrinkage: freeze drying to 85 % of the glutaraldehyde fixed tissue volume; critical point drying to 41% (after 24 h); and air drying from a volatile solvent to about 18% of the fixed tissue volume. Air drying from water caused a shrinkage to about 12% of the original volume. There was no significant difference between the various commonly used CPD schedules or between GA only and GA + Os O₄ fixed tissue. CPD via cellosolve and CO₂ caused substantially more shrinkage than other methods. Dimensional changes during specimen preparation are probably associated with changes in shape and in relative relationships between organelles, cells and tissues having different compositions. This should be borne in mind by all those interpreting scanning electron micrographs of dried animal soft tissue specimens.     

Ultrastructural and immunohistochemical study of early repair of alveolar sockets after the extraction of molars from alendronate‐treated rats

The aim of the present research was to analyze ultrastructural and immunohistochemical aspects of the alveolar repair after the extraction of molars of alendronate (ALN)‐treated rats. Wistar rats received 2.5mg/kg body wt/day of ALN during 14 days previously and 7, 14 and 21 days after the extraction of the second mandibular molar. Specimens were fixed in 2% glutaraldehyde + 2.5% formaldehyde under microwave irradiation, decalcified in 4.13% EDTA and paraffin embedded for TRAP histochemistry and immunohistochemistry for OPN, BSP and endoglin, or embedded in Spurr epoxy resin for TEM analysis. Additional specimens had their soft tissues removed and were processed for scanning electron microscopy. The ALN group presented latent TRAP‐positive osteoclasts and nonresorbed alveolar crests with bacterial infection. Mild bone necrosis signs were observed at all time points studied. Ultrastructurally, empty osteocyte lacunae were observed and bone trabeculae surface presented hyalinized aspect. A significant delay in alveolar repair occurred, as well as decreased angiogenesis. ALN treatment provoked mild signs of bone necrosis, despite the high dose employed. The present findings add new information about the ultrastructural aspect of the early repair of rats under ALN treatment and highlight for giving attention when oral surgeries are performed in patients using this drug. Microsc. Res. Tech. 76:633–640, 2013. © 2013 Wiley Periodicals, Inc.