Osmolarity of osmium tetroxide and glutaraldehyde fixatives

Synopsis The evidence available to date for the importance of fixative osmolarity is considered together with some observations on the volume changes of crab axons after fixation by osmium tetroxide and glutaraldehyde. The results obtained are compared with those obtained from crab axons and from amphioxus skin cells which had been processed and examined with the electron microscope after initial fixation in fixatives of different composition. It is concluded that the osmolarity of the fixative vehicle is of considerable importance when the fixing agent is glutaraldehyde but is of less importance when the fixing agent is osmium tetroxide or a mixture of the two agents.Preliminary observations upon crab axons fixed with glutaraldehyde in a vehicle approximating to the internal composition of the cells suggest that this approach to the design of fixative vehicles may be useful.     

Microwave-stimulated glutaraldehyde and osmium tetroxide fixation of plant tissue: ultrastructural preservation in seconds

Summary Microwave-enhanced fixation of animal tissues for electron microscopy has gained in interest in recent years. Attempts to use microwave irradiation for the preparation of plant tissues are rare. In this study, I report on microwave conditions which allow a high quality preservation of plant cell structure. Tissues used were: internodes of Chara vulgaris, leaves of Hordeum vulgare, root tips of Lepidium sativum. Microwave irradiation was done with a commercial microwave oven (Sharp R-5975). Fixatives used were: 2.5% glutaraldehyde in 0.1 M sodium cacodylate buffer, pH 7.2 and 1% osmium tetroxide in veronal/acetate buffer, pH 7.2. Conventional fixations with glutaraldehyde/osmium were compared with microwave fixations. Examinations of thin sections showed that microwave fixation (glutaraldehyde or sequential aldehyde/osmium) is an attractive and rapid alternative method for processing plant tissues for electron microscopy. The optimal conditions found were: microwave oven at power level 50 W, 6.5 ml of fixative solution, irradiation times between 32–34 s, final temperature between 40° C and 47° C.     

Microwave-stimulated glutaraldehyde and osmium tetroxide fixation of plant tissue: ultrastructural preservation in seconds.

Microwave-enhanced fixation of animal tissues for electron microscopy has gained in interest in recent years. Attempts to use microwave irradiation for the preparation of plant tissues are rare. In this study; I report on microwave conditions which allow a high quality preservation of plant cell structure. Tissues used were: internodes of Chara vulgaris, leaves of Hordeum vulgare, root tips of Lepidium sativum. Microwave irradiation was done with a commercial microwave oven (Sharp R-5975). Fixatives used were: 2.5% glutaraldehyde in 0.1 M sodium cacodylate buffer, pH 7.2 and 1% osmium tetroxide in veronal/acetate buffer, pH 7.2. Conventional fixations with glutaraldehyde/osmium were compared with microwave fixations. Examinations of thin sections showed that microwave fixation (glutaraldehyde or sequential aldehyde/osmium) is an attractive and rapid alternative method for processing plant tissues for electron microscopy. The optimal conditions found were: microwave oven at power level 50 W, 6.5 ml of fixative solution, irradiation times between 32-34 s, final temperature between 40 degrees C and 47 degrees C.     

Further studies on fixation with osmium tetroxide

Summary The effect of buffered media containing dextran, sucrose and different organic ions, on the volume of blood and ascitescells during fixation with osmium tetroxide has been studied. The findings are in agreement with similar studies ontissue pieces as reported earlier. The presence of osmium tetroxide causes a marked swelling of the cells as estimated by hematocrit techniques. The swelling can be balanced by an appropriate composition of the fixation vehicle, the significance of which is discussed.

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Zusammenfassung Es wurde die Wirkung von Pufferlösungen, die Dextran, Sucrose und verschiedene organische Ionen enthalten, auf das Volumen von Blut- und Asciteszellen während der Fixation mit Osmiumtetroxyd untersucht. Die Ergebnisse stimmen mit ähnlichen Befunden anGewebsstücken, über die früher berichtet wurde, überein. Die Gegenwart von Osmiumtetroxyd verursacht eine bemerkenswerte Zellschwellung, die mittels Hämatokrit-Technik bestimmt wurde. Die Schwellung kann durch eine angepaßte Zusammensetzung verschiedener Fixierungszusätze ausgeglichen werden. Über die Bedeutung dieser Zusätze wird diskutiert.

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With 2 Figures in the Text     

Ultrastructure of human leukocytes after simultaneous fixation with glutaraldehyde and osmium tetroxide and "postfixation" in uranyl acetate

Human leukocytes in suspension or in monolayer cultures have been processed for electron microscopy by fixation in a freshly made cold mixture of glutaraldehyde and osmium tetroxide and by "postfixation" in uranyl acetate. Simultaneous exposure to glutaraldehyde and osmium tetroxide eliminates many of the shortcomings seen when either of these agents is used alone as the initial fixative. Specimens are processed to the stage of dehydration as single cell suspensions or as very small clumps to assure rapid penetration of fixatives and efficient washing. The technique is rapid and reproducible. Electron micrographs presented in this report illustrate the ultrastructural features of human white cells prepared by this method.     

Tissue fixation and staining with osmium tetroxide: the role of phenolic compounds.

It has been postulated that phenol-containing areas of plant and animal tissues were osmiophilic, but proof of direct interaction between osmium tetroxide and phenolic materials, or the nature of such reactions, has been lacking. We find that, under conditions similar to those of normal tissue fixation, osmium tetroxide reacts rapidly with those phenols containing o-dihydroxy groups (including such species found in plant tissues) to give very stable chelate complexes. We conclude that these complexes are responsible for the observed electron-density in phenol-containing areas of tissue treated with osmium tetroxide, so that such phenols are indeed osmiophilic.     

Penetration rates of osmium tetroxide with different fixation vehicles

Summary The presence of any substance other than OsO₄ in osmium tetroxide fixation mixtures causes a decrease in the penetration rate of the fixative. Fixation times should therefore be prolonged whenever a fixation mixture containing osmotically active substances is used.With I Figure in the Text     

Osmium tetroxide versus glutaraldehyde fixation in adrenomedullary tissue

Summary Osmium tetroxide and glutaraldehyde fixation of adrenomedullary tissue presents evidence that these two fixatives preserve the tissue in quite different manners. Not only is the type of fixative of importance, but also the osmolarity of the fixatives is a prime factor in producing an accurate pictorial account of catecholamines.Supported by United States Public Health Service Grants 5-Tl-GM-459, NB 05093-02, FR 0505-01, NB 00690-11 and National Science Foundation Grant GB 25 96.— With the technical assistance of John Yates, Earl Pitsinger and Brenda Ryker.     

Tissue fixation by osmium tetroxide. A possible role for proteins.

The osmiophilia, under the conditions of normal tissue fixation, of the histidine, lysine, tryptophan, cysteine and methionine side chain of proteins is suggested by in vitro studies on blocked amino acids representative of such protein side chains, and the chemical nature of the reaction products elucidated. The chemical feasibility of inter- or intramolecular cross-linking of protein by OsO4 at these and other sites is demonstrated, as in the cross-linking of protein with unsaturated lipids such as methyl oleate, methyl linoleate and linolenate, and cholesteryl acetate. The relevance of these results to the process of tissue fixation by OsO4 is discussed.     

The reactions between formaldehyde,glutaraldehyde and osmium tetroxide,and their fixation effects on bovine serum albumin and on tissue blocks

Summary The reactions between osmium tetroxide and glutaraldehyde and formaldehyde were investigated. It was found that they react together to form intermediate products which then break down to form osmium black. Glutaraldehyde reacts much more rapidly with osmium tetroxide than formaldehyde. The rates of the reactions are increased by increasing the glutaraldehyde concentration or adding bovine serum albumin to the reaction mixture. The reaction rates increase with temperature. The mixtures of fixatives were also tried on tissues and the results paralleled the model experiments. The crosslinking of bovine serum albumin by osmium tetroxide, formaldehyde and glutaraldehyde singly and in mixtures was quantitatively assessed by viscosimetry, gel filtration and disc electrophoresis coupled with densitometry. The crosslinking of bovine serum albumin by pairs of fixatives was less than that produced by the most effective of the pair. After 5 min reaction osmium tetroxide was the most effective crosslinking agent according to viscosimetric experiments, but after one hour's reaction with bovine serum albumin, glutaraldehyde was revealed as the most effective crosslinking agent by gel filtration and electrophoresis.     

The chemical nature of osmium tetroxide fixation and staining of membranes by X-ray photoelectron spectroscopy

X-ray photoelectron spectroscopy was used to determine the oxidation states of osmium compounds present in erythrocyte ghost preparations and related systems treated with osmium tetroxide. Osmium tetroxide and cholesterol, codeposited at ?100 °C, began to react at ?70 °C, and Os(VI) was formed. Similarly, Os(VI) was detected for the known cholesterol-osmate ester prepared and purified chemically. However, osmium tetroxide applied in phosphate buffer (pH 7.2) gave rise to large proportions of Os(IV) and Os(III) species in addition to Os(VI) compounds. Egg phosphatidylcholine likewise produced a mixture of Os(VI), Os(IV), and Os(III), but dipalmitoyl phosphatidylcholine failed to give significant amounts of osmium containing products under identical conditions. Glutaraldehyde gave a mixture of compounds with the same osmium oxidation states when allowed to react with aqueous osmium tetroxide. Unfixed and glutaraldehyde-fixed erythrocyte ghosts also produced mixtures of Os(VI), Os(IV) and Os(III) under conditions identical to those of normal tissue processing. Additionally, the mixture of adducts initially formed by treatment with osmium tetroxide was further reduced by dehydration of the tissue with ethanol, resulting in a final mixture which was 50–60% Os(III).The results support a scheme for the reaction of osmium tetroxide with tissues in which the initial reaction site is the double bonds of unsaturated lipids to form Os(VI) derivatives. Subsequent hydrolysis and further reduction yield complexes of Os(IV) and Os(III). A mixture of these three states is present in membrane specimens during microscopic observation. Os(VI) and Os(IV) could be present as osmate esters and osmium dioxide, respectively; Os(III) could be present as an oxo- or amino complex(es). The photoelectron spectrum of intact erythrocyte ghosts can be synthesized from the spectra of phospholipid and cholesterol only, suggesting the predominance of the reaction with lipids in the fixation process.