A methodological study for the quantification and the control of the physico-chemical processes occurring during cell fixation. I. The development of a new technology.

Fixation in a traditional sense means the immersion of biological material into a chemical fluid. For permanent preservation the fixative is always "offered" (1) in excess of the cell sample, and the process of fixation is influenced by (2) chemical impurities of the fixative fluid. Both factors influence the succeeding dyeing of cells. In order to avoid these uncontrolled criteria, a new technology for controlled cell fixation has been developed, whereby freshly prepared formaldehyde and methanol gas in an "inert" gas-flow of helium was applied to thin membranes by aid of a capillary flow-in technique. The instrumental equipment consists of (1) an ultra-high vacuum flow-apparatus with a total-pressure measuring unit, (2) a gas-supply device, (3) a mass spectrometer including a pump system, and (4) a Teflon and/or glass-gas chamber for the treatment of synthetic (Hostaphan foils) or biological membranes (mesenterium) with formaldehyde as the fixative gas. The amount of "offered", adsorbed, absorbed, diffused, and desorbed fixative gas could be absolutely estimated after the saturation of the membranes with an "on-line" operating "inert" mass spectrometer of the Omegatron type. The gas treatment of the Hostaphan foils with formaldehyde showed that nearly all adsorbed gas molecules could be desorbed. In contrast to native membranes the greatest proportion of the gas molecules adhered to the biological surface, and only a small quantity were desorbable. Physisorption or physisorption and chemisorption occured depending on the adsorber surface property. A monolayer of formaldehyde of 5.10(14) to 1.10(15) molecules per 10(16) A2 surface area can be postulated on the basis of these preliminary results. This value corresponds to a mass of about 5.10(-8) g CH2O. It resulted in an area-coverage ratio of CH2O molecules per cell of 10(9):1. The membrane surface facing the gas side always amounted to 1 cm2. A fixative gas concentration of 10(6) molecules/cm3, and therefore a degree of coverage of less than 1/1000 monolayer can be estimated absolutely. For a precise determination of the degree of fixation, further experiments and the evaluation of additional physico-chemical parameters are necessary.     

A methodological study for the quantification and the control of the physico-chemical processes occurring during cell fixation

Summary Fixation in a traditional sense means the immersion of biological material into a chemical fluid. For permanent preservation the fixative is always offered (1) in excess of the cell sample, and the process of fixation is influenced by (2) chemical impurities of the fixative fluid.Both factors influence the succeeding dyeing of cells. In order to avoid these uncontrolled criteria, a new technology for controlled cell fixation has been developed, whereby freshly prepared formaldehyde and methanol gas in an inert gas-flow of helium was applied to thin membranes by aid of a capillary flow-in technique.The instrumental equipment consists of (1) an ultra-high vacuum flowapparatus with a total-pressure measuring unit, (2) a gas-supply device, (3) a mass spectrometer including a pump system, and (4) a Teflon and/or glass-gas chamber for the treatment of synthetic (Hostaphan foils) or biological membranes (mesenterium) with formaldehyde as the fixative gas.The amount of offered, adsorbed, absorbed, diffused, and desorbed fixative gas could be absolutely estimated after the saturation of the membranes with an on-line operating inert mass spectrometer of the Omegatron type.The gas treatment of the Hostaphan foils with formaldehyde showed that nearly all adsorbed gas molecules could be desorbed. In contrast to native membranes the greatest proportion of the gas molecules adhered to the biological surface, and only a small quantity were desorbable. Physisorption or physisorption and chemisorption occured depending on the adsorber surface property.A monolayer of formaldehyde of 5·10¹⁴ to 1·10¹⁵ molecules per 10¹⁶ Ų surface area can be postulated on the basis of these preliminary results. This value corresponds to a mass of about 5·10^–8g CH₂O. It resulted in an area-coverage ratio of CH₂O molecules per cell of 10⁹:1.The membrane surface facing the gas side always amounted to 1 cm². A fixative gas concentration of 10⁶ molecules/cm³, and therefore a degree of coverage of <1/1000 monolayer can be estimated absolutely. For a precise determination of the degree of fixation, further experiments and the evaluation of additional physico-chemical parameters are necessary.     

ULTRASTRUCTURE OF THE PRAWN NERVE SHEATHS : Role of Fixative and Osmotic Pressure in Vesiculation of Thin Cytoplasmic Laminae

The sheaths from freshly teased nerve fibers of the prawn exhibit a positive radial birefringence, consistent with their EM appearance as highly organized laminated structures composed of numerous thin cytoplasmic sheets or laminae bordered by unit membranes and arranged concentrically around the axon. The closely apposed membranes in these sheaths are fragile and often break down into rows of vesicles during fixation. Desmosome-like attachment zones occur in many regions of the sheath. The membranes within these zones resist vesiculation and thereby provide a "control" region for relating the type of vesicles formed in the fragile portions of the sheaths to the specific fixation conditions. It is proposed that during fixation the production of artifactual vesicles is governed by an interplay of three factors: (a) direct chemical action of the fixative on the polar strata of adjacent unit membranes, (b) osmotic forces applied to membranes during fixation, and (c) the pre-existing natural relations between adjacent membranes. It is found that permanganate best preserves the continuity of the membranes but will still produce vesicles if the fixative exerts severe osmotic forces. These results support other reports (19) of the importance of comparing tissues fixed by complementary procedures so that systematic artifacts will not be described as characteristic of the natural state.     

The influence of fixation on the relative amount of cytoplasmic ribosomes in mouse epidermal basal keratinocytes. A morphometric study of so-called "dark cells" and their putative role in epidermal carcinogenesis

The nature and significance of so-called dark keratinocytes in the epidermis during chemical carcinogenesis is still a matter of concern and debate. Based on ultrastructural observations it has been suggested that dark cells most often are shrunken cells. Reports on skin carcinogenesis, however, claim that dark cells are a sign of ongoing tumor promotion and represent those stem cells in the epidermis from which the tumors originate. It is therefore important to find out whether these cells are simply injured and shrunken cells, or vital cells of great importance for carcinogenesis. Dark cells are assumed to be rich in ribosomes. There is evidence, however, that the observed number of dark cells is highly dependent on tissue fixation. In the present ultrastructural study, morphometric methods were used to compare the effects of two different fixation procedures on the amount of cytoplasmic ribosomes in dark cells from both untreated and carcinogen-treated hairless mouse epidermis. The results show that the ultrastructural features of both dark and clear cells vary considerably with different fixation procedures. In acetone-treated controls typical dark cells are only observed when the fixative has a lower osmotic activity than the plasma. With iso-osmolal fixation typical dark cells are not observed. After an abortive two-stage carcinogenesis treatment, in which a single application of 9,10-dimethyl-1,2-benzanthracene (DMBA) in acetone was followed by a single application of 12-O-tetradecanoyl-13-acetate (TPA) in acetone, signs of cell injury could be found after both fixation procedures. With DMBA/TPA and hypo-osmolal fixation the number of dark cells seemed to increase, whereas only signs of cell injury with occurrence of some heavily altered "clear cells" dominated the picture with iso-osmolal fixation. Morphometry showed that both the numerical and the volumetric densities of cytoplasmic ribosomes in basal keratinocytes varied most significantly with the fixation procedure used. The cytoplasmic volumes did not vary in a way that could explain these differences. One might therefore assume that the number of ribosomes depends on the fixative. Large swelling artifacts occurred when a fixative with low osmotic activity was used, leading to compression of neighboring cells. Hence, an increased ribosomal density reported previously in dark cells is probably related to such cell volume artifacts and does not reflect an actually increased quantity of ribosomes.(ABSTRACT TRUNCATED AT 400 WORDS)     

A fixation method for improved antibody penetration in electron microscopical immunoperoxidase studies.

A fixation method for electron microscopical immunoperoxidase staining has been developed, which (a) allows penetration of antibodies through cell membranes to intracellular antigen sites, (b) provides a reasonable cell preservation and (c) does not alter the antigenic structure in too great an extent. Penetration of the antibodies has been achieved by using saponin as a cell membrane attacking agent. The best results could be obtained after pretreatment of cell monolayers with a mixture of 0.05% saponin, 0.0125%-0.05% glutaraldehyde and 1% paraformaldehyde for 5 min at 4 degrees C, and postfixing them with the corresponding fixative without saponin for 45 min at 4 degrees C.     

Impact of glutaraldehyde versus glutaraldehyde-formaldehyde fixative on cell organization in fish corneal epithelium

The purpose of this study was to examine the impact of a low osmolality glutaraldehyde fixative and a high osmolality glutaraldehyde-formaldehyde fixative on the structural organization of a tissue that could be exposed to low and high osmolality environments. The corneas of freshwater trout were prepared for transmission and scanning electron microscopy using either a fixative of 2% glutaraldehyde in 60 mM cacodylate buffer (pH 7.8, 260 mOsm/l) or a fixative prepared by adding 2.5% glutaraldehyde to a solution of 1% formaldehyde and buffering the solution with 0.1 M cacodylate (pH 7.6, 850 mOsm/l; Karnovsky-type fixative). The corneal epithelial cell layer thickness was greater after glutaraldehyde compared to glutaraldehyde-formaldehyde fixation (67 vs 55 mum), as was the thickness of the superficial cells (5.1 vs 3.4 mum) and basal cells (43 vs 38 mum). The intermediate (wing) cells of the epithelium were, however, less thick after glutaraldehyde fixation (15 vs 18 mum). The width of the squamous, intermediate and basal cells was greater following glutaraldehyde fixation with the effect being greatest in the superficial layers and insignificant at the level of the basal cells. The results show that chemical fixatives with extremes of osmolality cannot only produce different cell sizes in a tissue but also determine the overall organization of the cells in a positional-dependent fashion.     

The opposing physiological effects of high pressures and inert gases.

The physiological effects on mammals of elevated pressures (approximately 100 atmospheres) must be considered in the context of the inert gases breathed. The most striking effect of pressure per se is a central hyperexcitability manifest at first by trembling of the entremities and finally by convulsions. Paralysis and death occur at higher pressures. The primary effects of the inert gases breathed are inert gas narcosis and general anesthesia. The exciting effects of pressure per se and the depressive effects of the inert gases tend to oppose each other. Thus consciousness may be restored to anesthetized mice by raising the pressure, and conversely the threshold pressure that causes convulsions is elevated in the presence of anesthetics. These mutually antagonistic effects can be rationalized in terms of model which proposes that both anesthetics and pressure non-specifically perturb thelipid bilayer regions of neutral membranes. This model is termed the critical volume hypothesis. Anthesthetics dissolve in and expand these lipid bilayer regions, while pressure causes mechanical compression. Expansion leads to anesthesia and compression to convulsions if a critical degree of change is achieved. At elevated partial pressures of inert gas the gas-induced expansion is opposed by the compression of pressure per se. With very insoluble gases, such as helium, this expansion is so small that net compression results and the effects of helium differ little from those of pressure per se. With more soluble gases, such as nitrogen, net expansion results in inert gas narcosis and anesthesia. The critical volume hypothesis enables "safe" mixtures of "expanding" and "compressing" gases to be defined. These enable higher pressures to be better tolerated by mammals.     

Tannic acid effect on membrane of cell surface origin in guinea pig megakaryocytes and platelets.

Plasma membranes in isolated guinea pig megakaryocytes and washed platelets are poorly stained with the usual methods used to outline cell membranes. The addition of tannic acid and calcium to the initial fixative is useful to enhance electron density of all surface-derived membrane systems in these cells. The method described here shows that the increased electron denisty of membrane after fixation in the presence of tannic acid occurs both at the cell surface and along the invaginated membrane systems.     

The effect of primary fixation with standard postfixation and the duration of hydrolysis on nuclear features in image cytometry.

The effect of three primary fixation procedures, used in the preparation of routine cytological samples: air-drying, Delaunay, and Saccomanno fixation, with postfixation in modified B?hm-Sprenger fixative, on nuclear features as a function of hydrolysis time is reported. Three different cell types: lymphatic cells (tonsil), epithelial cells (buccal mucosa) and mesenchymal cells (uterine myometrium) were used for the study. Our findings show, that generally not all features have the same plateau times as the IOD (integrated optical density), and that many features show different values depending on cell type and fixation method. It is therefore recommended that for any primary fixative used in routine clinical work and for each cell type, the hydrolysis curve for all nuclear features to be used in sample analysis should be established.     

Freeze-fracture studies of the developing cell surface. II. Particle-free membrane blisters on glutaraldehyde-fixed corneal fibroblasts are artefacts.

We describe, in sections and by freeze-fracture, four classes of intramembrane particle (IMP)-free membrane blebs or "blisters" associated with glutaraldehyde-fixed embryonic corneal fibroblasts: (a) Single blisters attached to the cell membrane; (b) free (detached) vesicles; (c) myelin figures; (d) multivesicular protrusions which resemble the "mounds" described by others on nerve growth cones. The IMP-free, membrane-bounded blisters contain no ground cytoplasm or organelles, in contrast to blebs on trypsin-isolated fibroblasts, which we show here do contain cytoplasm and IMP-rich membranes. That the IMP-free membrane blisters in embryonic corneas are artefacts of fixation is demonstrated by (a) their absence in replicas of fibroblasts frozen and fractured without prior aldehyde fixation and (b) their absence in sections of fibroblasts fixed in a combination of glutaraldehyde and osmium tetroxide. We suggest that the addition of osmium prevents postfixation movement of membrane lipids, especially the negatively charged "fluid" lipids which others have shown are capable of considerable mobility after aldehyde fixation alone. Recent literature has implicated membrane blistering in secretory processes and in growth of nerves, but before the functional significance of such IMP-free blisters is assessed, membrane mobility of the type shown here should be taken into consideration.     

Phase-partition fixation and staining of Drosophila eggs.

Aqueous solutions of alcohol-acetic acid-formalin or glutaraldehyde-acrolein were shaken with heptane and heptane phase used for fixation. Phase-partition fixation is akin to fixation with vapor. The organic solvent, immiscible with water, penetrates hydrophobic membranes and carries the fixative in contact with water phase of the tissue. Only the fixative enters the tissue, without changing the ionic and water-soluble substance concentrations in the tissue. The quality of this fixation for optical or electron microscopy was as good as that of any conventional fixation method. Staining with basic fuchsin after 2 N HCl hydrolysis gave brilliant staining of nuclei, more intense than that with Feulgen reagent, while cytoplasm remained nearly colorless. Fixing and staining procedures for Drosophila eggs are given.     

The search for an optimal DNA, RNA, and protein detection by in situ hybridization, immunohistochemistry, and solution-based methods

Clinical trials and correlative laboratory research are increasingly reliant upon archived paraffin-embedded samples. Therefore, the proper processing of biological samples is an important step to sample preservation and for downstream analyses like the detection of a wide variety of targets including micro RNA, DNA and proteins. This paper analyzed the question whether routine fixation of cells and tissues in 10% buffered formalin is optimal for in situ and solution phase analyses by comparing this fixative to a variety of cross linking and alcohol (denaturing) fixatives. We examined the ability of nine commonly used fixative regimens to preserve cell morphology and DNA/RNA/protein quality for these applications. Epstein-Barr virus (EBV) and bovine papillomavirus (BPV)-infected tissues and cells were used as our model systems. Our evaluation showed that the optimal fixative in cell preparations for molecular hybridization techniques was "gentle" fixative with a cross-linker such as paraformaldehyde or a short incubation in 10% buffered formalin. The optimal fixatives for tissue were either paraformaldehyde or low concentration of formalin (5% of formalin). Methanol was the best of the non cross-linking fixatives for in situ hybridization and immunohistochemistry. For PCR-based detection of DNA or RNA, some denaturing fixatives like acetone and methanol as well as "gentle" cross-linking fixatives like paraformaldehyde out-performed other fixatives. Long term fixation was not proposed for DNA/RNA-based assays. The typical long-term fixation of cells and tissues in 10% buffered formalin is not optimal for combined analyses by in situ hybridization, immunohistochemistry, or--if one does not have unfixed tissues--solution phase PCR. Rather, we recommend short term less intense cross linking fixation if one wishes to use the same cells/tissue for in situ hybridization, immunohistochemistry, and solution phase PCR.     

Fixation variables in horseradish peroxidase neurohistochemistry. I. The effect of fixation time and perfusion procedures upon enzyme activity.

In a series of neurohistochemical experiments the effect of aldehyde fixation upon the detection of horseradish peroxidase (HRP) was examined. These experiments demonstrated that: a) Increments in fixation of as little as 1 hr significantly decreased the number of labeled neurons; 12-hr fixation abolished HRP activity in many neuronal populations and significantly reduced the apparent size of the injection site. b) This negative fixation effect was greatest where the HRP concentration was low (e.g. in small, lightly labeled neurons) but was still evident in areas of high concentration (e.g. large, heavily labeled neurons). c) This effect was also most prominent when a less sensitive diaminobenzidine histochemical procedure was employed but was still apparent with a more sensitive benzidine dihydrochloride procedure. d) Immersion of the brain in fixative after perfusion produced a greater attenuation of HRP activity in more superficial areas. e) Immersion of the brain in buffer to terminate fixation produced a prolonged and unpredictable gradient of fixation. f) Excess, unbound fixative inhibited the histochemical reaction per se and had to be removed from the tissue but prolonged washing did not resurrect enzyme activity which was lost by fixation. To obviate these problems and optimize HRP enzyme activity a new perfusion-fixation procedure was developed. It entails 30 min fixation by perfusion which is terminated by a subsequent 30 min perfusion with cold sucrose-fuller to wash out unbound fixative. This allows the tissue to be processed immediately, produces a uniform and morphologically adequate fixation, and minimizes the negative effects of fixation on HRP enzyme activity.     

Stable acid phosphatase: I. Demonstration and distribution

Summary After a pH-dependent reactivation a highly stable form of acid phosphatase (SAPhase) could be demonstrated in active cells of the macrophage/giant cell/osteoclast series and also in epiphyseal chondrocytes, in cells lining bone undergoing resorption and in hamster cosinophils. Because acid phosphatases of epithelial cells in rat, hamster and Macaca sp. tissues did not possess this stability, SAPhase served as a useful cell marker for the above mesenchymal cell types in paraffin and glycol-methacrylate sections even after rapid demineralization in acidic buffers. Conformational alterations appear to occur in the enzyme during formaldehyde fixation, embedding, and reactivation. The granular staining of SAPhase and the successful use of a non-aqueous fixative suggest an association of SAPhase with lysosomes and their membranes. Cells of mesenchymal origin that are actively engaged in intra- and/or extracellular digestion contain high levels of SAPhase. The distribution and properties of SAPhase indicate an interrelationship between mononuclear and mutinuclear cell types actively engaged in such digestive processes.Supported by the Medical Research Council of Great Britain     

A comparison of several fixative solutions for histochemical studies on human gastric mucosa

The effects of different fixative solutions on the staining of polyanions and Paneth cell granules and on alkaline phosphatase activity were evaluated in surgical specimens of human gastric mucosa with areas of intestinal metaplasia, which were dehydrated and embedded with routine procedures. Alcohol-formol proved to be particularly advisable for studies on the epithelial mucins, buffered formol with cetylpyridinium chloride for the connective tissue polyanions and the fluid of Mota et al. (1956) for the mast cells. In areas of complete intestinal metaplasia, the Paneth cell granules were destroyed by acidic fixative mixtures and 95% ethanol; in the same areas, alkaline phosphatase activity was well demonstrated after fixation with formol, alcohol-formol, or 95% ethanol.     

Fixation induces differential tip morphology and immunolocalization of the cytoskeleton in pollen tubes

The effects of chemical fixation on tip morphology and immunolocalization of the cytoskeleton in Tradescantia virginiana pollen tubes were evaluated using lour different fixation protocols differing in fixative type/concentration, fixation time, buffer system and additives. Apical regions were much more sensitive to fixation manipulations than more basipetal areas. The presence of the calcium chelator EGTA at 5 mM led to tip rupture and/or swelling in over 80% of germinated grains. However, low or no EGTA levels during fixation resulted in poor immunolocalizations, although lips had more normal morphology. Double fixation in which pollen tubes were first treated for a short period with higher fixative and lower EGTA (0.5 mM) concentrations, followed by lower fixative and higher EGTA (5.0 mM) concentrations, resulted in both improved preservation of pollen lube tip morphology and microfilament/microtubule localizations.     

New red blood cell lysing fixative for use in fine needle aspiration and fluid cytology

OBJECTIVE: To describe a new red blood cell (RBC) lysing fixative, Devine's lysing solution (DLS), that increases the diagnostic utility of fine needle aspiration (FNA) and fluid cytology. STUDY DESIGN: Twenty bloody FNA cases were fixed with either DLS or 95% ethanol, and the ability to render a diagnosis on these materials was analyzed. DLS was compared to the red cell lysing fixative CytoRich Red (CRR) (TriPath Care Technologies, Burlington, North Carolina, U.S.A.) in its ability to lyse RBCs by mixing human RBCs with the U266 multiple myeloma cell line. DLS was compared to CRR in its ability to suitably preserve materials for Papanicolaou and immunocytochemical analysis. RESULTS: Comparison of DLS with 95% ethanol fixation in 20 bloody FNA cases prepared in duplicate showed that DLS reduced from 17 to 3 the number of cases that had RBCs obscuring > or = 25% of the diagnostic material. In 3 cases, DLS enabled the rendering of a definitive diagnosis of malignancy, which could not be made on the ethanol-fixed material. DLS was compared to CRR, and both fixatives were similarly effective at lysing RBCs, preserving the cellular morphology of diagnostic cells in FNA and fluid cytology, and preserving cells for use in immunocytochemistry. CONCLUSIONS: DLS increases the visualization of diagnostic cellular material when compared to ethanol fixation. DLS is comparable to CRR in RBC lysing ability, diagnostic cell preservation and preservation of materials for immunocytochemistry.     

Enhanced preservation of endosecretory granules in PP-cells of the canine pancreas

Standard fixation techniques commonly used for light and electron microscopic studies have resulted in reported differences in the ultrastructural appearance of endosecretory granules of the pancreatic polypeptide (PP) cell. To clarify these differences, canine pancreatic tissues of intact and cultured pseudoislets were studied using a variety of ingredients, additives and fixatives in an effort to better preserve the endosecretory granules of PP cells. Results show that preservation of PP granules is enhanced by addition in zinc chloride (0.5%) to a glutaraldehyde-paraformaldehyde fixative in 0.1 M cacodylate buffer, followed by osmium tetroxide fixation. This fixative is recommended for all light and electron microscopic studies of the pancreatic polypeptide cell.     

Cryo-section immunolabelling of difficult to preserve specimens: advantages of cryofixation, freeze-substitution and rehydration.

BACKGROUND INFORMATION: Electron microscopic immunolabelling of ultrathin thawed cryo-sections, according to the method of Tokuyasu, is widely used as a very sensitive high-resolution localization technique. Its main advantages are that antigens remain in a hydrated environment prior to immunolabelling, and that antigen accessibility is improved compared with resin section labelling. However, the quality of structural appearance and antigenicity depends highly on the limitations of the initial conventional chemical fixation step, such as slow diffusion and selective reaction/cross-linking of fixative molecules. RESULTS AND CONCLUSIONS: Cryofixation, instead of conventional chemical fixation, followed by freeze-substitution/chemical fixation, rehydration and further processing for Tokuyasu cryo-sectioning leads to an improved preservation of both ultrastructure and antigenicity. This is especially true for tissues which are difficult to preserve by conventional chemical fixation at ambient temperatures, such as plant material, Drosophila embryos or nematode tissue. In particular labile and highly dynamic structures (for example, microtubules and Golgi apparatus) are remarkably better preserved. These improvements are also valid for light microscopic applications.     

The effects of various fixatives on subsequent lectin binding to tissue sections

Summary The effects of ten fixation protocols on the subsequent binding of eight lectins to various mouse tissue sites have been systematically evaluated. The fixatives used were neutral and buffered formalin—saline, Bouin's fluid, 95% ethanol, Carnoy's fluid, calcium acetate—paraformaldehyde, and mercuric chloride both before and after removal of mercury pigment. These were compared with frozen sections of unfixed tissue and frozen sections post fixed in paraformaldehyde. Lectins used were PNA, DBA, SBA, BPA, UEA 1, GS I, GS II and MPA. Ethanol was found to be the superior fixative, closely followed by mercuric chloride. Paraformaldehyde was a poor fixative of both paraffin and frozen sections. It is recommended that, where a choice is possible, the fixation protocol appropriate to the particular lectin and tissue binding site is selected. Within certain limitations, formalin—saline proved an adequate fixative for the study of routine paraffin-processed tissue sections.