Effects of glutaraldehyde fixative osmolarities on smooth muscle cell volume,and osmotic reactivity of the cells after fixation

The contribution of glutaraldehyde (GA) to the effective osmolarity of GA fixatives, the osmotic reactivity of the cells after fixation in GA, and also the duration of fixation in GA on cell volume, were investigated using cultured smooth muscle cells (SMC) and spiral aortic strips. Four fixation procedures were studied. We found that GA contributes to the total effective osmolarity of the fixatives, and that the type of buffers used for the fixatives can also affect the cell volume differently during GA fixation. After GA fixation, the cells were still osmotically reactive, regardless of the buffer types for making up the GA fixatives, so that the osmolarity of the wash buffer after GA fixation is important. However, OsO₄ eliminates osmotic responses, thus the osmolarity of OsO₄ fixative and wash buffer have negligible influence on the cell volume. Longer fixation time up to 4 h had no effect on the cell volume.     

Atomic force microscopy of BHK-21 cells: an investigation of cell fixation techniques

The atomic force microscope (AFM) has been used to image a wide variety of biological samples, including cultured cells, in air. Whilst cultured cells have been prepared for AFM analysis using a variety of matrices and fixatives, a definitive study of sample preparation and its effects on cell morphology has not, as far as the authors are aware, previously been reported. Although a considerable number of cell fixatives exist, no single fixative is ideal for all investigations. Prior to the performance of specialised techniques, such as atomic force microscopy of cultured cells in air, the cell fixation method must be investigated and optimised. The fixative abilities of 2% paraformaldehyde-lysine-periodate, 0.25% glutaraldehyde, paraformaldehyde-glutaraldehyde, 4% phosphate-buffered formal saline, 1% formaldehyde, methanol:acetone, formal saline, 4% paraformaldehyde and ethanol:acetic acid were assessed in this study. A qualitative assessment system was used to evaluate the efficacy of the above fixatives using conventional fixation criteria (i.e. the presence of fibroblastic morphology consistent with optical microscopy and the absence of fixation artifacts). The optimal fixative was identified as 4% paraformaldehyde, which was capable of providing optically consistent images of BHK-21 (fibroblastic) cells, whose heights remained within the measurement capability of the AFM instrument used in this study.     

Cytochrome oxidase activity and confocal laser scanning microscopic analysis of the hamster submandibular gland using microwave irradiated fixation

Submandibular glands of the hamster were irradiated in 2% paraformaldehyde (pFA)-0.5% pure glutaraldehyde (PGA) with a microwave (MW) processor at temperatures of 10 degrees and 37 degrees C. Electron microscopy showed that cytochrome oxidase activity was taking place in the mitochondrial intermembrane-intracristal space of the granular duct cell when the temperature of the MW-irradiated fixatives was at 10 degrees C. However, a decrease of this activity was observed when we took care to keep the temperature of the MW-irradiated fixatives at 37 degrees C. The distinct reduction of cytochrome oxidase activity allowed by MW irradiation seems to be due the thermal affects of fixatives. Of course, the possibility cannot be excluded that MW irradiation caused other undetectable membrane damage. Then, we used confocal laser scanning microscopy for the preservation check of the mitochondrial membrane for cytochemistry with MW-irradiated fixation. The fluorescence of rhodamine 123 was observed in the inner spaces of the mitochondria at temperatures of 10 degrees and 37 degrees C. When the same tissues were fixed with 2% pFA using an MW processor as the sole fixative at 10 degrees C, no mitochondrial fluorescence was observed. Cytochrome oxidase activity, by contrast, could be seen in the mitochondrial intermembrane-intracristal spaces in the same condition. Formaldehyde is not the best aldehyde for the purpose of ultrastructural preservation. On the other hand, light and electron microscopy showed that the endogenous peroxidase activity was localized in the nuclear envelope, endoplasmic reticulum, secretory granules, and Golgi apparatus of the hamster submandibular gland using 2% pFA-0.5% PGA fixative with and without MW irradiations at temperatures of 10 degrees and 37 degrees C. Some of the same cells were fixed with only 2% pFA under MW irradiation at 10 degrees C; however, marked diffuseness of the peroxidase activity was observed. Therefore, these results indicated that cytochrome oxidase activity was sensitive to heat with MW-irradiated fixation. Peroxidase activity was very resistant to heat with MW-irradiated fixation but not with pFA solo fixation, therefore, PGA had to be used.     

Direct measurement of the osmotic effects of buffers and fixatives in Nitella flexilis

The pressure probe has been used to investigate the amount and time course of changes in turgor induced by agents used in fixation of biological material for electron microscopy. All buffers tested decreased the turgor pressure of internodal cells of the green alga Nitella flexilis in proportion to their osmotic concentration. With the exception of s-collidine, the buffers were impermeant, as shown by the stability of the reduced turgor. The fixatives formaldehyde and glutaraldehyde caused a rapid reduction in turgor followed by recovery of turgor as the aldehyde penetrated the cell. Plasmolysis of cells can be avoided by a procedure involving stepwise increase of fixative concentration.     

Metabolic state dependent preservation of cells by fixatives for electron microscopy

The preservation of mitochondria, cytoplasmic vacuoles and cytoplasm by various fixatives after various pretreatments of ethothelial heart cells from Xenopus laevis tadpoles in tissue culture was investigated. The study was based on phase contrast cinemicrographic recordings and on qualitative and quantitative observations with the electron microscope. Three fixatives were used: 3% glutaraldehyde in phosphate buffer, followed by 1% osmium tetroxide postfixation, fixation only with 1% osmium tetroxide in phosphate buffer and the fixing medium according to Dalton. Cells were either not treated or pretreated for 20 min: 10 microM FCCP (Carbonylcyanide-p-trifluoromethoxy-phenylhydrazone) or 4 mM KCN. The superiority of glutaraldehyde was exemplified by its very rapid action, good preservation of cytoplasm, vacuoles, and mitochondria. It was the only medium which maintained an electron density of the mithochondria matrix. In both of the other fixatives swelling of mitochondria and coagulated appearance of cytoplasm (in phase contrast) was more pronounced in cells pretreated with metabolic inhibitors than in controls. Observations with the light microscope have been confirmed by morphometry of electron micrographs of mitochondria. The relation of matrix space to intracristal space is changed in opposite directions after glutaraldehyde and after the Dalton-type fixation. The results indicate a higher sensitivity against fixation artifacts in cells under pathological conditions than normal cells.     

Cryofixation of vascular endothelium

Cryofixation refers to the immobilization of tissue components by the rapid removal of heat from the specimen, so that the structure is interred and stabilized in a natural embedding medium, namely, frozen (amorphous or microcrystalline) tissue water. Cryofixation is now often used as a complement to the more traditional fixation methods, especially when the cell structure is delicate or dynamic and may be inaccurately preserved by the slow selective action of chemical fixatives. Vascular endothelial cells are specialized for transcellular transport and for the regulation of blood flow and composition. The dynamic and labile subcellular organization of these cells, presumably reflecting these functional specializations, makes them ideal candidates for cryofixation. Several different types of endothelial cells were directly frozen at temperatures below 20 degrees Kelvin by pressing them against a liquid-helium-cooled block. These samples were subsequently processed for structural analysis by freeze-substitution. Detailed rationales, designs, and protocols are described for both freezing and freeze-substitution. Electron micrographs of cryofixed arterial and venous capillaries (rete mirabile of the American eel), iliac vein (rabbit), and cultured endothelium from the iliac vein (human) reveal that the organization of the characteristic intracellular membrane system of endothelial vesicles is qualitatively similar to that seen in chemically fixed endothelium, especially with regard to the interconnection of clusters of individual vesicles to form elaborate networks. The luminal and abluminal networks are not in communication, at least not in static images. Quantitatively, however, most directly frozen endothelial cells have far fewer vesicular profiles than comparable glutaraldehydefixed cells. The differences can be explained by presuming that the rapid action of cryofixation (approximately 1 msec) gives a more accurate picture of the vesicular network because it captures the transient structure of labile or dynamic membranes.     

The avian erythrocyte: a study of fixation for electron microscopy.

The quality of ultrastructural preservation of the avian erythrocyte achieved using various fixation techniques is evaluated. Different combinations of initial fixatives, buffers and post-fixation procedures were tested as well as variations in fixative osmolarity, pH and temperature. Of the commonly used initial fixatives (glutaraldehyde, acrolein and formaldehyde), 2% glutaraldehyde, alone in a slightly hypertonic buffer containing divalent ions, produced optimum erythrocyte preservation. The osmolarity was balanced using a non-electrolyte such as a sucrose. The addition of 12% hexylene glycol to the buffer solutions also improves erythrocyte preservation, as evidenced by the increased stability of the marginal microtubules, microfilaments and proteinaceous material. The use of Spurr low-viscosity epoxy resin enables the cells to be collected using low gravitational centrifugation.     

Feasibility of high pressure freezing with freeze substitution after long‐term storage in chemical fixatives

Fixation of biological samples is an important process especially related to histological and ultrastructural studies. Chemical fixation was the primary method of fixing tissue for transmission electron microscopy for many years, as it provides adequate preservation of the morphology of cells and organelles. High pressure freezing (HPF) and freeze substitution (FS) is a newer alternative method that rapidly freezes non‐cryoprotected samples that are then slowly heated in the FS medium, allowing penetration of the tissue to insure adequate fixation. This study addresses several issues related to tissue preservation for electron microscopy. Using mice liver tissue as model the difference between samples fixed chemically or with HPF immediately after excision, or stored before chemical or HPF fixation were tested with specific focus on the nuclear membrane. Findings are that immediate HPF is the method of choice compared to chemical fixation. Of the chemical fixatives, immediate fixation with 2.5% glutaraldehyde (GA)/formaldehyde (FA) is the best in preserving membrane morphology, 2.5% GA can be used as alternative for stored and then chemically processed samples, with 10% formalin being suitable as a storage medium only if followed by HPF fixation. Overall, storage leads to lower ultrastructural preservation, but HPF with FS can minimize these artifacts relative to other processing protocols. Microsc. Res. Tech. 76:942–946, 2013. © 2013 Wiley Periodicals, Inc.     

Fixation induces differential polarized translocations of organelles in hyphae of Saprolegnia ferax

Saprolegnia hyphal tips were examined during fixation, and living or freeze-substituted tips were quantitatively compared with those fixed in commonly employed formulations of paraformaldehyde and glutaraldehyde. Treating hyphae with fixatives induced extensive longitudinal translocations of the cytoplasm and organelles, usually beginning with contractions toward the tip. These translocations were minimal in the extreme apex (~10 μm) and more extensive subapically. Hypertonic media or hypotonic buffers seldom or never induced translocations, respectively; in contrast, hypotonic buffers containing detergents or the Ca²⁺ -ionophore, A23187, frequently induced contractions. All fixations caused net nucleus movement away from the tip, with the amount of displacement depending on the pre-fixation distance from the tip. Similarly, all fixations moved the most-apical of saltatory vesicles away from the tip, but the total number in the apex increased or decreased depending on the fixative used. The patterns of these results suggest that nucleus and vesicle distribution controls may be related (with respect to most-apical organelles) but also at least partially independent (with respect to organelle populations in hyphal tips). Hyphal diameter was reduced by some, but not all fixations; this variability did not correlate with displacements of either organelle, nor with fixative osmotic pressure. Evidently fixative-induced changes are more complex and systematic in highly polarized tip-growing cells than previously reported in other, less polarized, cell types. These results also suggest that hyphae contain multiple and complex organelle distribution and hyphal diameter control systems which can be readily altered, often subtly, by fixation protocols commonly and uncritically employed in immunocytochemical and ultrastructural analyses, and that fixation can cause serious cellular reorganization.     

Atomic force microscopy: influence of air drying and fixation on the morphology and viscoelasticity of cultured cells

The influence of fixation, air-drying and liquid-imaging on the morphology as well as on the viscoelasticity of malignant mesothelioma cells was studied by atomic force microscopy. In this study, dehydrated cells were more easily scanned and offered faster data recording than hydrated cells. However, the influence of fixation strength was more noticeable. Strong fixation induced flattening of the cytoplasm and loss of nuclear structure, resulting in a clearly visible cytoskeleton which could be easily seen as fibres orientated in the direction of the cell growth. By contrast, the morphology of hydrated cells was influenced to a lesser degree on fixation and showed an overall 'rounding' of the surface with vague, ill-defined structures. Nuclear areas of these samples were difficult to image.
Viscoelasticity measurements also exhibited large differences. Dehydrated cells were much harder and showed a uniform indentation profile over the whole cell that was independent of fixation. Indentation on hydrated cells was large and depended on the height of the measuring spot, the submembranous structure and, to a lesser extent, on fixation. To calculate an overall 'cellular' viscoelasticity, different methods were tested on these samples. Indentations of multiple, randomly chosen points, covering the whole cell, were measured and averaged to yield a mean indentation score. We avoided the thin and shadowed areas since it was shown that these regions were less suited for measuring. Using this design, large viscoelasticity differences were found, on which the influence of the external parameters could be shown. In another set-up, layered imaging was tried. However, long data acquisition times caused cellular activation and rearrangement, making this scanning mode unsatisfactory.     

A specimen carrier, storage disc system for scanning electron microscopy (SEM): evaluation of stainless steel as a substratum for cell culture in vitro

A method of sample preparation for scanning electron microscopy (SEM) studies based on the use of stainless steel discs as a cell culture substratum is described in detail. A number of different cell lines were grown on stainless steel, and the growth patterns and biocompatibility of cells cultured on stainless steel were compared to identical cells cultured on aluminium, glass and plastic substrata. Stainless steel provides cells with an excellent growth surface which allows these cells to retain their normal growth characteristics and appearance. The non-toxic stainless steel discs can be manipulated through any combination of fixatives and organic solvents. The discs have been incorporated into a versatile system of sample preparation for SEM.     

Preparation of resin embedded unicellular organisms without the use of fixatives and dehydration media.

A method is presented for processing single cells for conventional ultrathin sectioning without the use of fixatives and dehydration media. The cells were fixed by a physical method--spray freezing--which provides extremely high cooling rates, needs no pretreatment with cryoprotective agents and is therefore assumed to maintain the in vivo morphology of the cell. Hitherto cells prepared in this way have been investigated exclusively by freeze etching. To combine the advantages of this method with those of conventional ultrathin sectioning we have processed spray frozen cells with widely varying water contents (spermatozoa and lymphocytes) by freeze drying at 188 K and vacuum embedding. When compared to conventional chemical fixation the differences found in ultrastructural preservation of spermatozoa using this kind of preparation were confined to the arrangement of spermhead membranes and middlepiece structures. Lymphocyte structure was much closer to that known from chemical preparation, the only differences being a denser cytoplasm, denser mitochondrial matrices and thicker plasma membranes. These differences are probably due to the absence of eluating and dissolving effects present in conventional chemical preparations. The ultrastructural preservation of spray frozen cells is not different after freeze etching or after freeze-drying and vacuum embedding. This indicates clearly that drying and resin embedding does not produce artefacts and that structural preservation is therefore limited by the quality of cryofixation. Therefore this method is considered a contribution to the problem of preservation of the in vivo assembly of cellular substructure. Furthermore it seems to be a potential basis for preparation of soluble or diffusible substances or cellular compounds which would be influenced by fixatives and dehydrating agents.     

Freeze-substitution techniques for preparing nematodes for scanning electron microscopy

The effect of different substitution times, temperatures and the incorporation of fixatives on the preservation of three species of nematode for scanning electron microscopy by freeze substitution with methanol, followed by critical point drying, is investigated. Hammerschmidtiella diesingi adults and Trichostrongylus colubriformis infective juveniles were successfully preserved using methanol at 253 K as the substitution medium. Preservation deteriorated with long substitution times, suggesting the extraction of material and that substitution times should be kept as brief as possible. Panagrolaimus davidi was not successfully preserved using pure methanol, but preservation was improved by using fixatives in the substitution medium, the best results being obtained with 1% OsO₄/3% glutaraldehyde in methanol. A substitution temperature of 193 K did not give any improvement in preservation. The differences in the quality of preservation between the three species may be due to the relative ability of the cuticle to withstand collapse during critical point drying. Chemical fixation using cold fixative resulted in the retention of a natural posture but poor preservation, whereas hot fixatives resulted in good preservation but the loss of a natural posture. Freeze substitution in methanol may prove useful in the preparation of specimens possessing cuticles or cell walls which have sufficient strength to withstand the drying process (e.g. arthropods, plants, fungi, nematodes). More delicate specimens may require the incorporation of fixatives into the substitution medium or conventional fixation.     

Microwave techniques for diagnostic laboratories

Microwaves (MWs) were first introduced as a method of fixation just over 20 years ago. In recent years their use has extended far beyond that of a safe, clean, and rapid method of fixation of tissue blocks and large specimens, including brains. MWs accelerate the action of cross-linking fixatives and can greatly accelerate the various stages of tissue processing to produce a paraffin block in 30 min. An extensive range of ultrafast MW-stimulated special stains has been developed, and immunohistochemical procedures can be completed in 20 min by employing MWs. Cellular antigens are distinctly better preserved in tissues fixed by MWs than by conventional cross-linking fixatives. Also, the cytomorphology of cryostat sections irradiated in Wolman's solution is clearly improved. MWs can similarly be applied for fixation and staining of preparations for transmission and scanning electron microscopy, and they also greatly accelerate polymerisation of resins. In the current climate of cost containment, this wide range of applications makes the MW oven an invaluable addition to the diagnostic laboratory.     

Freeze substitution followed by low melting point wax embedding preserves histomorphology and allows protein and mRNA localization techniques

Fixation and embedding are major steps in tissue preservation for histological analysis. However, conventional fixatives like aldehyde‐based solutions usually mask tissular epitopes preventing their immunolocalization. Alternative fixation methods used to avoid this drawback, such as cryopreservation, alcohol‐ or zinc salts‐based fixatives do not efficiently preserve tissue and cell morphology. Likewise, paraffin and resin embedding, commonly used for thin sectioning, frequently damage epitopes due to the clearing agents and high temperatures needed along the embedding procedure. Alternatives like cryosectioning avoid the embedding steps but yield sections of poorer quality and are not suitable for all kinds of samples. To overcome these handicaps, we have developed a method that preserves histoarchitecture as well as tissue antigenic properties. This method, which we have named CryoWax, involves freeze substitution of the samples in isopentane and methanol, followed by embedding in low melting point polyester wax. CryoWax has proven efficient in obtaining thin sections of embryos and adult tissues from different species, including amphioxus, zebrafish, and mouse. CryoWax sections displayed optimal preservation of tissue morphology and were successfully immunostained for fixation‐ and temperature‐sensitive antigens. Furthermore, CryoWax has been tested for in situ hybridization application, obtaining positive results. Microsc. Res. Tech., 2011. © 2010 Wiley‐Liss, Inc.     

Cryofixing single cells and multicellular specimens enhances structure and immunocytochemistry for light microscopy

Cryofixation is widely held to be superior to chemical fixation for preserving cell structure; however, the use of cryofixation has been limited chiefly to electron microscopy. To see if cryofixation would improve sample structure or antigenicity as observed through the light microscope, we cryofixed Nicotiana alata and Lilium longiflorum pollen tubes and Tradescantia virginina stamen hairs by plunge freezing. After freeze-substitution, and embedding in butylmethylmethacrylate, we found using the light microscope that the superiority of cryofixation over chemical fixation was obvious. Cryofixation, unlike chemical fixation, did not distort cell morphology and preserved microtubule and actin arrays in a form closely resembling that of living cells.
Additionally, to test further the usefulness of cryofixation for light microscopy, we studied the appearance of cells and the retention of antigenicity in a plunge-frozen multicellular organ. Roots of Arabidopsis thaliana were either chemically fixed or plunge frozen, and then embedded in the removable methacrylate resin used above. We found that plunge freezing preserved cell morphology far better than did chemical fixation, and likewise improved the appearance of both actin and microtubule arrays. Plunge-frozen roots also had cells with more life-like cytoplasm than those of chemically fixed roots, as assessed with toluidine-blue staining or high-resolution Nomarski optics. Damage from ice crystal formation could not be resolved through the light microscope, even in the interior of the root, 40–75 μm from the surface. We suggest that plunge freezing would enhance many investigations at the light microscope level, including those of multicellular organs, where damage from ice crystals may be less severe than artefacts from chemical 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.     

Effect of fixative on chromatin structure and DNA detection

In this study, we analyzed the chromatin ultrastructure in interphase cells after different chemical fixations. In light of the fact that there is little information regarding the fixation of biological samples in combination with molecular biology methods (such as DNA extraction and in situ hybridization methods) we analyzed the ultrastructure of chromatin in interphase cells fixed with different fixatives and tested under the same conditions for both DNA extraction and in situ hybridization. The results showed that, among the different combinations and concentrations we analyzed, the solution of 4% paraformaldehyde/0.1% glutaraldehyde was the best compromise in order to achieve a well-preserved morphology, successful DNA extraction, and specific signaling of in situ hybridization, suggesting a low interference of this fixative with the chromatin organization.     

Comparing different preparation methods to study human fibrin fibers and platelets using TEM

For the study of cellular ultrastructure, the sample needs to be stabilized by fixation, with the ultimate aim to preserve the native tissue organization and to protect the tissue against later stages of preparation. Chemical and freezing fixation are most used, and chemical fixation employs agents that permeate tissues and cells by diffusion and covalently bind with their major biochemical constituents to fix them. Most widely used chemical fixatives are aldehydes, e.g., formaldehyde and glutaraldehyde, which are noncoagulating, crosslinking agents. Cryofixation methods for ultrastructural studies are also popular, and high-pressure freezing immobilizes all cell constituents and arrests biological activity by removing the thermal energy from the system. In the current research, we used platelet-rich plasma (PRP) to study expansive fibrin fibers and platelet ultrastructure to compare the two fixation techniques. We also used thrombin and calcium chloride as a clotting agent to determine the technique most suitable for the formation of extensive fibrin networks. Chemically fixated fibrin fibers were more compact and condensed and also showed a banding pattern on longitudinal sections. High-pressure frozen samples were more dispersed while platelets fixated showed better preserved cellular membranes and organelle structure. PRP coagulated by addition of CaCl(2) showed blood platelets that are noticeably more activated compared with PRP; however, with thrombin, a sharp ultrastructure was seen. We conclude that PRP mixed with thrombin, and freeze substituted, is the most suitable method for the study of extensive fibrin fibers as well as platelets.     

Changes of particle frequency in freeze-etched erythrocyte membranes after fixation

The frequency of particles on the membrane fracture faces of freeze-etched human erythrocytes was measured, and the effect of fixation procedures on the particle frequencies was studied. Fresh blood, buffer washed cells and cells fixed in one of the following ways were examined: glutaraldehyde, glutaraldehyde followed by osmium tetroxide, osmium tetroxide alone. Quantitative analyses showed that some treatments produced a significant reduction in the number of particles on the fracture faces as compared with the fresh cells. After both osmium tetroxide fixations, the loss of particles was greater from the outer fracture face (OFF) than the inner fracture face (IFF), whilst after the other treatments approximately the same number of particles were lost from both fracture faces. The results are discussed with respect to some current concepts of the molecular architecture of the erythrocyte membrane and the action of fixatives. The reduction of particle frequencies is thought to be due to both leaching of membrane proteins, and deviations of the usual fracture plane within the membrane. Glutaraldehyde alone was shown to have less effect on particle frequency than the other fixatives and it is therefore a suitable fixative for the preparation of freeze-etch specimens.