Conservation of Cell Order in Desiccated Mesophyll of Selaginella lepidophylla ([Hook and Grev.] Spring)

Understanding of the basis of desiccation tolerance in matureplant tissues that survive extreme dehydration requires knowledgeof the degree of cellular order in the dry state. Generally,aqueous fixatives have been used in ultrastructural studiesof such material, and these are known to be inadequate in thepreservation of dry material. Cryopreservation provides a moreassured level of fixation fidelity than aqueous fixatives, particularlywith dry material. Using freeze substitution and electron microscopy,we examined the ultrastructure of dry mesophyll cells ofSelaginellalepidophylla ([Hook and Grev.] Spring). In this material thecells were condensed and had highly folded walls. The plasmalemmawas bounded on both sides by layers of granular material, andthe membrane was in close and continuous apposition to the walls.The conformation and position of organelles and their structureappeared to be influenced by being compacted within the shrunkencells, but the ultrastructural integrity of all organelles andcellular membranes, including mitochondria, chloroplasts andvacuoles, was maintained in the dry state. These cells had numeroussmall vacuoles clustered in aggregates, and the tonoplast membranesappeared to be coated on the internal side by a fine granularlayer. The vacuoles contained osmiophilic material of varyingdegrees of condensation and had embedment holes suggesting thepresence of salt crystals within the vacuoles. The general conclusionsfrom these studies are that a critical level of cell order ismaintained in the dry state in these desiccation-tolerant plants,and a high degree of effective packing and shape fitting ofcellular constituents with the compaction forces of dehydrationunderlies this conservation of cell order. Freeze substitution; Selaginella lepidophylla ([Hook and Grev.] Spring); ultrastructure; membrane structure; desiccation tolerance; resurrection plants     

Evaluation of fixative composition,fixative storage,and fixation duration on the fine structure and volume of root-cell nucleoli

Summary— The effect of various combinations of three fixative compositions (glutaraldehyde buffered in veronal acetate, cacodylate, and piperazine-N, N'-bis[2-ethanesulfonic acid]—PIPES], two fixative storage times (fresh vs 6 weeks), and two fixation durations (3 h vs 9 days) on nucleolar fine structure and nucleolar volume in three root cell-types of oat seedlings (Avena sativa L, cv Seger) were evaluated. All fixatives show overall good preservation of fine structure. Nucleolar components are distinct and well delineated in cells fixed in solutions buffered with either cacodylate or veronal acetate; the components are more condensed when preserved in fixative buffered with PIPES. Nucleolar volume is greatest in cells fixed in the cacodylate fixative, and smallest in those preserved in the PIPES fixative. Among the treatments tested, the PIPES fixative evidently best maintains nucleolar volume. Distracting particulate deposits are abundant on nuclei and nucleoli in cells preserved in the veronal-acetate fixative. Contrary to common assumptions, aging of buffered fixative at room temperature for 6 weeks seems to affect neither the general quality of cellular preservation nor the pH of the fixatives, although nucleolar volume is reduced by such treatment. Long-period fixation (9 days) results in destruction of membrane integrity (mitochondria, plastids, ER), and shrinkage of organelles from the cytoplasm. Nucleolar volume is reduced with prolonged fixation.     

INFLUENCE OF GLUTARALDEHYDE AND/OR OSMIUM TETROXIDE ON CELL VOLUME, ION CONTENT, MECHANICAL STABILITY, AND MEMBRANE PERMEABILITY OF EHRLICH ASCITES TUMOR CELLS

Effects of fixation with glutaraldehyde (GA), glutaraldehyde-osmium tetroxide (GA-OsO₄), and osmium tetroxide (OsO₄) on ion and ATP content, cell volume, vital dye staining, and stability to mechanical and thermal stress were studied in Ehrlich ascites tumor cells (EATC). Among variables investigated were fixation time, fixative concentration, temperature, osmolality of the fixative agent and buffer, total osmolality of the fixative solution, osmolality of the postfixation buffer, and time of postfixation treatment in buffer (Sutherland, R. M., et al. 1967. J. Cell Physiol. 69:185.). Rapid loss of potassium, exchangeable magnesium, and ATP, and increase of vital dye uptake and electrical conductivity occurred with all fixatives studied. These changes were virtually immediate with GA-OsO₄ or OsO₄ but slower with GA (in the latter case they were dependent on fixative temperature and concentration) (Foot, N. C. 1950. In McClung's Handbook of Microscopical Technique. 3rd edition. 564.). Total fixative osmolality had a marked effect on cell volume with OsO₄ but little or no effect with GA or GA-OsO₄. Osmolality of the buffer had a marked effect on cell volume with OsO₄, whereas with GA or GA-OsO₄ it was only significant at very hypotonic buffer osmolalities. Concentration of GA had no effect on cell volume. Osmolality of the postfixation buffer had little effect on cell volume, and duration of fixation or postfixation treatment had no effect with all fixatives. Freezing and thawing or centrifugal stress (up to 100,000 g) had little or no effect on cell volume after all fixatives studied. Mechanical stress obtained by sonication showed that OsO₄ alone produced poor stabilization and that GA fixation alone produced the greatest stabilization. The results indicate that rapid membrane permeability changes of EATC follow fixative action. The results are consistent with known greater stabilizing effects of GA on model protein systems since cells were also rendered relatively stable to osmotic stress during fixation, an effect not noted with OsO₄. After fixation with GA and/or OsO₄ cells were stable to osmotic, thermal, or mechanical stress; this is inconsistent with several earlier reports that GA-fixed cells retain their osmotic properties.     

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.     

A comparison of fixatives for the estimation of abundance and biovolume of marine planktonic ciliate populations

The effects of five treatments with four commonly used fixativeson the abundance and cell volume of marine planktonic ciliateswere investigated on a natural community from Plymouth Sound.The fixative treatments were 5% and 9% Bouin's solution, 0.4%acid Lugol's iodine, 1% buffered formaldehyde and 1% glutaraldehyde.The abundance of the aloricate ciliate community varied accordingto fixative treatment, with Lugol's maintaining the greatestcell numbers, followed by Bouin's, glutaraldehyde and formaldehyde.The effects of the fixatives on the abundance of the two mostcommon aloricate taxa, Balanion sp. and Strombidium epidemumwere similar to, and components of, those for the aloricatepopulation as a whole. However, there was little differencebetween the effects of different fixatives on the abundanceof the tintinnid community, or on the abundance of the mostcommon tintinnid, Tintinnopsis nana. Mean cell volumes of Balanionsp., S.epidemum and T.nana were greatest in samples fixed informaldehyde, followed by glutaraldehyde, Lugol's and Bouin's.The mean population volume of the aloricate and tintinnid populationsgenerally reflected this trend with greatest values recordedin formaldehyde- and glutaraldehyde-fixed samples, followedby Lugol's and Bouin's; however, the differential effects ofthe fixatives were not as great. Lugol's therefore appears tobe the most effective fixative tested for the estimation ofciliate abundance and population volume, the latter being afunction of abundance and cell volume. ³Present address: British Antarctic Survey, High Cross, MadingleyRoad, Cambridge CB3 OET, UK     

On the influence of fixations on the normal hydration of rabbit cornea and the total amount of acid mucopolysaccharides in the stroma

Summary The authors studied the influence of fixations on the normal hydration of the rabbit cornea and the total amount of acid mucopolysaccharides (AMPS) in the stroma. The following fixatives were used: formol-calcium chloride at 19° C for 24 hours, formolcetylpyridinium chloride (CPC) at 19 and 28° C for 48 hours, Lillie's fixation at 19° C for 24 hours and Carnoy's fluid at 19° C for 30 minutes. The sections of the corneae were stained with Alcian blue, colloidal Fe³⁺ in the modification according to Rinehart and Abu'l Haj and with toluidine and methylene blue. The amount of AMPS was determined with the method of Rondle and Morgan and the total hydration of the stroma by weighing the corneae before and after using different fixative fluids and by calculation of obtained values on dry weight.The best results were obtained by using formol-CPC at 28° C. At the ordinary room temperature (±19° C) it was the poorest fixation, however, as the corneae in this solution became hydrated. Formol-calcium chloride was the second in the row and it was much better than Lillie's and Carnoy's fluid.The amount of AMPS in the stroma was not essentially changed by the effect of fixatives. Within 24–48 hours formol-CPC at 28° C retained the normal content and formol-calcium chloride caused the 11% decrease of AMPS maximally. The loss of AMPS after other fixatives was minimal.The intensity of staining with cationic dyes in paraffin sections was different after individual fixatives and after the kind of their application and was dependent chiefly on the state of hydration of the corneal stroma: It is impossible to interpret the results of staining reactions in terms of the quantity of AMPS as it was hitherto done.     

The influence of fixation on the morphology of mouse epidermis. A light and electron microscopical study with special reference to "dark cells" and epidermal carcinogenesis

Different opinions exist on the normal ultrastructure of the epidermis including the significance of so-called basal dark cells. Thus, the dark cells are still assumed to be key elements in experimental skin carcinogenesis. We therefore explored the effects of tissue fixation on the ultrastructure of the epidermis. Untreated normal hairless mouse skin was processed for transmission electron microscopy with two different sets of fixatives, applied either by perfusion-immersion or immersion fixation only. The morphology of both the basal and the lower suprabasal layers of the epidermis, including the extracellular space, the shape and volume of the cells, their electron density, and the organisation of some of the organelles, were profoundly affected by the choice of fixatives. The non-keratinocytes showed comparable changes, including the appearance of a dark phenotype. The incidence of small electron-dense keratinocytes (dark cells) and the nature of their ultrastructure changed markedly with the fixation procedure. We were not able to identify undifferentiated dark cells. The pattern of changes and the quality of the morphological picture were almost unaffected by the mode of fixation. The upper suprabasal and the cornified layers appeared to be more or less unaltered by the change in fixatives and the method of application. The vehicle osmolality of the primary fixative was found to be mainly responsible for the ultrastructural appearances. A low vehicle osmolality may be responsible for the occurrence of the dark cell phenomenon, by inducing swelling artefacts of many cells with compression of some neighbouring cells.     

Lysozyme antigenicity and tissue fixation.

The preservation of lysozyme (LZM) antigenicity was studied in paraffin embedded tissue blocks. The reactivity for LZM varied with the type of tissue studied, the fixative used, the osmolarity and pH of the fixative, fixation time and temperature, and the method of dehydration. In both rat and human tissues aqueous fixatives were superior to nonaqueous fixatives in retaining LZM antigenicity. Brief fixation in fixatives of low osmolarity enhanced LZM staining in the parenchymatous tissues but diminished staining in human cartilage; prolonged fixation in fixatives of high osmolarity gave opposite results. Least affected by fixation was the LZM antigenicity in the serous cells of the glands of the respiratory tract. These cells also stained most intensely for LZM of all autopsy material studied.     

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.     

Lysozyme antigenicity and tissue fixation

Summary The preservation of lysozyme (LZM) antigenicity was studied in paraffin embedded tissue blocks. The reactivity for LZM varied with the type of tissue studied, the fixative used, the osmolarity and pH of the fixative, fixation time and temperature, and the method of dehydration. In both rat and human tissues equeous fixatives were superior to nonaqueous fixatives in retaining LZM antigenicity. Brief fixation in fixatives of low osmolarity enhanced LZM staining in the parenchymatous tissues but diminished staining in human cartilage; prolonged fixation in fixatives of high osmolarity gave opposite results. Least affected by fixation was the LZM antigenicity in the serous cells of the glands of the respiratory tract. These cells also stained most intensely for LZM of all autopsy material studied.Studies supported by grants from the Sigrid Jusélius Foundation and Finska Läkaresällskapet     

Using Unfixed,Frozen Tissues to Study Natural Mucin Distribution

Mucins are complex and heavily glycosylated O-linked glycoproteins, which contain more than 70% carbohydrate by weight^1-3. Secreted mucins, produced by goblet cells and the gastric mucosa, provide the scaffold for a micrometers-thick mucus layer that lines the epithelia of the gut and respiratory tract^3,4. In addition to mucins, mucus layers also contain antimicrobial peptides, cytokines, and immunoglobulins^5-9. The mucus layer is an important part of host innate immunity, and forms the first line of defense against invading microorganisms^8,10-12. As such, the mucus is subject to numerous interactions with microbes, both pathogens and symbionts, and secreted mucins form an important interface for these interactions. The study of such biological interactions usually involves histological methods for tissue collection and staining. The two most commonly used histological methods for tissue collection and preservation in the clinic and in research laboratories are: formalin fixation followed by paraffin embedding, and tissue freezing, followed by embedding in cryo-protectant media.Paraffin-embedded tissue samples produce sections with optimal qualities for histological visualization including clarity and well-defined morphology. However, during the paraffin embedding process a number of epitopes become altered and in order to study these epitopes, tissue sections have to be further processed with one of many epitope retrieval methods¹³. Secreted mucins and lipids are extracted from the tissue during the paraffin-embedding clearing step, which requires prolong incubation with organic solvents (xylene or Citrisolv). Therefore this approach is sub-optimal for studies focusing on the nature and distribution of mucins and mucus in vivo.In contrast, freezing tissues in Optimal Cutting Temperature (OCT) embedding medium avoids dehydration and clearing of the sample, and maintains the sample hydration. This allows for better preservation of the hydrated mucus layer, and thus permits the study of the numerous roles of mucins in epithelial biology. As this method requires minimal processing of the tissue, the tissue is preserved in a more natural state. Therefore frozen tissues sections do not require any additional processing prior to staining and can be readily analyzed using immunohistochemistry methods.We demonstrate the preservation of micrometers-thick secreted mucus layer in frozen colon samples. This layer is drastically reduced when the same tissues are embedded in paraffin. We also demonstrate immunofluorescence staining of glycan epitopes presented on mucins using plant lectins. The advantage of this approach is that it does not require the use of special fixatives and allows utilizing frozen tissues that may already be preserved in the laboratory.     

Determination of optimal rehydration,fixation and staining methods for histological and immunohistochemical analysis of mummified soft tissues

During an excavation headed by the German Institute for Archaeology, Cairo, at the tombs of the nobles in Thebes-West, Upper Egypt, three types of tissues from different mummies were sampled to compare 13 well known rehydration methods for mummified tissue with three newly developed methods. Furthermore, three fixatives were tested with each of the rehydration fluids. Meniscus (fibrocartilage), skin, and a placenta were used for this study. The rehydration and fixation procedures were uniform for all methods. The stains used were standard hematoxylin and eosin, elastica van Gieson, periodic acid-Schiff, and Grocott, and five commercially obtained immunohistochemical stains including pancytokeratin, vimentin, alpha-smooth-muscle-actin, basement membrane collagen type IV, and S-100 protein. The sections were examined by transmitted light microscopy. Our study showed that preservation of the tissue is dependent on the quality and effectiveness of the combination of the rehydration and fixation solutions, and that the quality of the histological and histochemical stains is dependent on the tissue quality. In addition, preservation of the antigens in the tissues is dependent on tissue quality, and fungal permeation had no influence on the tissue. Finally, the results are tissue specific. For placenta the best solution combination was Sandison and solution III (both fixed with formaldehyde) while results for skin were best with Ruffer I (using formaldehyde and Schaffer as fixatives), Grupe et al. (using formaldehyde as a fixative) and solution III (in combination with formaldehyde and Bouin fixatives). Ruffer II (using formaldehyde as a fixative) and solution III (in combination with Schaffer fixative) gave the best results for fibrocartilage.     

Determination of optimal rehydration, fixation and staining methods for histological and immunohistochemical analysis of mummified soft tissues.

During an excavation headed by the German Institute for Archaeology, Cairo, at the tombs of the nobles in Thebes-West, Upper Egypt, three types of tissues from different mummies were sampled to compare 13 well known rehydration methods for mummified tissue with three newly developed methods. Furthermore, three fixatives were tested with each of the rehydration fluids. Meniscus (fibrocartilage), skin, and a placenta were used for this study. The rehydration and fixation procedures were uniform for all methods. The stains used were standard hematoxylin and eosin, elastica van Gieson, periodic acid-Schiff, and Grocott, and five commercially obtained immunohistochemical stains including pancytokeratin, vimentin, alpha-smooth-muscle-actin, basement membrane collagen type IV, and S-100 protein. The sections were examined by transmitted light microscopy. Our study showed that preservation of the tissue is dependent on the quality and effectiveness of the combination of the rehydration and fixation solutions, and that the quality of the histological and histochemical stains is dependent on the tissue quality. In addition, preservation of the antigens in the tissues is dependent on tissue quality, and fungal permeation had no influence on the tissue. Finally, the results are tissue specific. For placenta the best solution combination was Sandison and solution III (both fixed with formaldehyde) while results for skin were best with Ruffer I (using formaldehyde and Schaffer as fixatives), Grupe et al. (using formaldehyde as a fixative) and solution III (in combination with formaldehyde and Bouin fixatives). Ruffer II (using formaldehyde as a fixative) and solution III (in combination with Schaffer fixative) gave the best results for fibrocartilage.     

Improved utilization of tissue blocks for electron microscopy. Effect of various concentrations of formaldehyde and glutaraldehyde.

Liver tissue from miniature pig fetuses was immersion-fixed in fixative mixtures with various concentrations of formaldehyde and glutaraldehyde. The preservation quality of hepatocytes was evaluated ultrastructurally in a peripheral zone (30--130 micron below the surface) and a central zone (500 micron below the surface). In the peripheral zone the best preservation was obtained with a fixative mixture containing 2% formaldehyde and 2% glutaraldehyde and in the central zone with a fixative mixture containing 8% formaldehyde and 8% glutaraldehyde. It is concluded that a better utilization of fairly large tissue blocks for ultrastructural investigation can be obtained by division of the block and subsequent fixation in fixatives containing various concentrations of formaldehyde and glutaraldehyde.     

Mucilage in Cacti: Its Apoplastic Capacitance, Associated Solutes, and Influence on Tissue 5

Mucilage content in the stems of four sympatric cactus speciesvaried from none for Ferocactus acanthodes, 19% by dry weightfor Opuntia basilaris, 26% for Opuntia acanthocarpa, and 35%for Echinocereus engelmannii. Although the mucilage differedchemically among the species (the arabinose content ranged from17% to 51% of the sugar monomers), its relative capacitance(change in relative water content per unit change in water potential)remained about 15 Mpa^–1. The relative capacitance of thewater-storage parenchyma averaged 1·04 Mpa^–1 andwas consistent with the mucilage content, being lowest for F.acanthodes and highest for E. engelmannii. Mucilage isolatedfrom hydrated tissue was accompanied by solutes with an osmoticpressure of about 0·2 MPa. Such associated solutes influencethe water-release characteristics of mucilage and hence itsrole as an apoplastic capacitor. In particular, extracellularsolutes can facilitate the release of appreciable mucilage-boundwater to the cells at tissue water potentials occurring duringthe initial phases of drought. Key words: Echinocereus engelmannii, Ferocactus acanthodes, Opuntia acanthocarpa, Opuntia basilaris, water potential isotherms     

High subzero cryofixation: A technique for observing ice within tissues

While various fixation techniques for observing ice within tissues stored at high sub-zero temperatures currently exist, these techniques require either different fixative solution compositions when assessing different storage temperatures or alteration of the sample temperature to enable alcohol-water substitution. Therefore, high-subzero cryofixation (HSC), was developed to facilitate fixation at any temperature above −80 °C without sample temperature alteration. Rat liver sections (1 cm²) were frozen at a rate of −1 °C/min to −20 °C, stored for 1 h at −20 °C, and processed using classical freeze-substitution (FS) or HSC. FS samples were plunged in liquid nitrogen and held for 1 h before transfer to −80 °C methanol. After 1, 3, or 5 days of −80 °C storage, samples were placed in 3% glutaraldehyde on dry ice and allowed to sublimate. HSC samples were stored in HSC fixative at −20 °C for 1, 3, or 5 days prior to transfer to 4 °C. Tissue sections were paraffin embedded, sliced, and stained prior to quantification of ice size. HSC fixative permeation was linear with time and could be mathematically modelled to determine duration of fixation required for a given tissue depth. Ice grain size within the inner regions of 5 d samples was consistent between HSC and FS processing (p = 0.76); however, FS processing resulted in greater ice grains in the outer region of tissue. This differed significantly from HSC outer regions (p = 0.016) and FS inner regions (p = 0.038). No difference in ice size was observed between HSC inner and outer regions (p = 0.42). This work demonstrates that HSC can be utilized to observe ice formed within liver tissue stored at −20 °C. Unlike isothermal freeze fixation and freeze substitution alternatives, the low melting point of the HSC fixative enables its use at a variety of temperatures without alteration of sample temperature or fixative composition.     

Graft Transmission of Longday-induced Leaf Senescence in Kleinia articulata

Kulkarni, V. J. and Schwabe, W. W. 1985 Graft transmission oflongday-induced leaf senescence in Kleinia articulata.—J.exp. Bot. 36: 1620–1633. Senescence of attached and detached rooted leaves in Kleiniaarticulata can be regulated by daylength, accelerated by longphotoperiods LD (> 16 h) and retarded by short days SD (8h). Using detached, rooted leaves as stocks in leaf to leafgrafts, senescence was readily transmitted from a LD donor leafto a SD receptor leaf even if the receptor was retained in SD(D8).However, no transfer could be detected where it had to passthrough any stem tissue. Senescence was reversible up to a certain stage, beyond whichgrafts senesced, pointing to an accumulation of the graft transmissiblefactor to a threshold level that causes irreversible death. Key words: Kleinia, leaf senescence, senescence factor, daylength, graft transmission     

Ultrastructural observations on tissues processed by a quick-freezing,rapid-drying method: Comparison with conventional specimen preparation

A quick-freeze, rapid-dry method for processing unfixed tissue for electron microscopy has been developed. The technique employs freezing on a cryogenchilled metal surface and drying in a cryosorption vacuum apparatus that allows osmium-vapor fixation and epoxy-resin embedment under high vacuum. Liver, kidney, bone marrow, and monolayer cultures of ventricular myocytes were selected as tissue specimens representing a wide range of physical properties, to demonstrate the practical aspects of achieving good ultrastructural morphology by freeze drying. A comparison was made between freeze drying and conventional processing using aldehyde fixation and alcohol dehydration. The preservation of cellular ultrastructure achieved by freeze drying allowed the identification of specific cell types within each specimen. Membranous organelles were well preserved, surrounded by cytoplasmic ground substance devoid of ice crystal damage. Electron-dense material was observed within the rough endoplasmic reticulum and Golgi cisternae and vesicles of frozen-dried, but not conventionally processed cells. This suggests the preservation by freeze drying of cytoplasmic components otherwise extracted from the cell by solvent exposure.