Moving EM: the Rapid Transfer System as a new tool for correlative light and electron microscopy and high throughput for high-pressure freezing

In this paper, the Rapid Transfer System (RTS), an attachment to the Leica EMPACT2 high‐pressure freezer, is described as a new tool for special applications within the cryofixation field. The RTS is an automated system that allows for fast processing of samples (<5 s) that make it possible for the first time to use high‐pressure freezing in combination with high time resolution correlative light and electron microscopy. In addition, with a working cycle of 30 s this rapid turn over time allows one to acquire more samples of biopsy material before it deteriorates than with other HPF machines with longer cycle times. With the use of the RTS it was possible to obtain three samples each of four different tissues in 6 min. Together with the finding that 90% of samples of cells grown on sapphire discs were well frozen, the RTS was both fast and reliable. Most important, together with other newly developed accessories, the RTS made it possible to capture specific events occurring live in the cell as observed by light microscopy, to cryofix that sample/event within 4 s, and then to analyze that event at high resolution in the electron microscope with excellent preservation of ultra‐structure. These developments should give us the tools to unravel intracellular processes that can be observed by live cell imaging but are too rare or fast to be picked up by routine EM methods or where the history of a structure is necessary to be able to discern its nature.     

Study of potassium deficiency in cardiac muscle: quantitative X-ray microanalysis and cryotechniques

An imbalance of potassium in cardiac muscle causes an alteration of heart function. The distribution and concentration of potassium in rat papillary heart muscle was studied using cryofixation and X-ray microanalysis. Freeze-dried cryosections and sections of freeze-dried, embedded tissue were analysed. Bulk frozen specimens were freeze-dried either in a vacuum or by a new technique using liquid propane as a cryodehydration medium. These two methods of freeze-drying were tested for elemental retention in other specimens, with comparable results. A potassium concentration of 120 mmol/l was measured in normal myocytes of cardiac papillary muscle compared to 80 mmol/l in myocytes of animals stressed by a temperature of 45°C for 1 h. The presumed physiological significance of the findings is discussed.     

Fast cryofixation technique for X-ray microanalysis

The proposed cryofixation technique uses a tubule-shaped needle chilled in liquid propane for simultaneous excision and freezing of a tissue specimen. Due to this simultaneity, ionic shifts created by traumatic influences are avoided even in the outermost cells of the specimen. Moreover, it is shown here that stopping the blood flow for more than about 10 s results in notable ionic shifts between cells and extracellular space in rat heart and liver. Such preparative ischaemic injury is minimized by the Fast Cryofixation Technique because it can be easily performed on organs within the circulatory system, whilst the heart of the animal is still beating. Intracellular concentrations of the monovalent ions in rat heart and liver, obtained by this method, tally well with recent results from different independent techniques reported in the literature. As demonstrated by cross-sectioning and freeze-fracturing, the structural preservation of the freezing technique is sufficient for X-ray microanalytical work.     

Preparation of ultrathin amorphous ice films for cryo-electron microscopy

Electron microscopy of biological macromolecules embedded in vitrified ice films suffers from serious problems caused by excessive inelastic scattering, beam-induced movements of the specimen, deformation of the molecules by adsorption at the water-air interface and insufficient mechanical stability of the films. We have built an environmental chamber to control temperature and humidity independently in order to produce ultrathin water films (< 20 nm) spanning holes with diameters of 20 μm to 1 mm. The surface tension of the water films was reduced by adding lipid monolayers, thus prolonging the usable time for thinning of the film and avoiding adsorption artefacts in the embedded material. After cryofixation in ethane a carbon film was evaporated on each side of the specimen to stabilize the ultrathin ice—lipid film. Mechanical stability and charging effects could successfully be reduced by this preparation method. Collapsing water films could be cryofixed and the shape of the hole was analysed. By the eccentricity of the elliptical holes an estimation could be made of the burst velocity of the rim of the hole and of the cooling rate of the cryofixation process.     

Low-temperature scanning electron microscopy in biology

A review of low-temperature scanning electron microscopy (LTSEM) with regard to preparation protocols, specimen preservation, experimental approaches, and high-resolution studies, is provided. Preparative procedures are described and recent developments in methodologies highlighted. It is now well established that LTSEM, for most biological specimens, provides superior specimen preservation than does ambient-temperature SEM. This is because frozen-hydrated samples retain most or all of their water, are rapidly immobilized and stabilized by cryofixation, and are not exposed to chemical modification or solvent extraction. Nevertheless, artefacts in LTSEM are common and most arise because frozen-hydrated specimens contain water. LTSEM can be used as a powerful experimental tool. Advantages of employing LTSEM for this purpose and ways in which it can be used for novel experimentation are discussed. The most exciting development in recent years has been high-resolution LTSEM. The advantages, problems and requirements for this approach are defined.     

Ultrastructure of the frog retina after high-pressure freezing and freeze substitution

In many types of tissue, high-pressure freezing (HPF), followed by freeze substitution, can produce excellent ultrastructural preservation at depths over 10 times that obtained by other cryofixation techniques. However, in the case of neural tissue, the benefits of HPF have not been realized. In the present study, isolated frog ( Rana pipiens) retina was sliced at a thickness of 150 or 350 μm, rapidly frozen in a Balzers HPM 010 high-pressure freezer, and freeze substituted with 1% OsO₄ and 0.1% tannic acid in acetone. Specially designed HPF chambers and specific freezing media (35% high-MW dextran for 150-μm slices or 15% low-MW dextran for 350-μm slices) were required for adequate freezing.
The quality of preservation after HPF was excellent throughout the retina in both the 150- and 350-μm slices, compared with chemically fixed slices. Specifically, HPF resulted in better preserved cellular, mitochondrial and nuclear membranes in all retinal layers.
This is the first study to successfully cryofix all of the layers of the retina. The increased depths of adequate freezing achieved by HPF should facilitate various ultrastructural studies of retina, as well as of other CNS tissues, where preservation approaching that of the 'native' state is required.     

Cryofixation methods for ion localization in cells by electron probe microanalysis: a review

Electron probe microanalysis data on the intracellular content and distribution of electrolyte ions depends critically on the functional state of the cells at the moment of cryofixation. Whereas tissue specimens often require special in-situ freezing techniques, isolated and cultured cells can be frozen within their environmental medium under physiologically controlled conditions. Thus, they represent a feasible system to study functional ion-related intracellular parameters such as the K/Na ratio. Specifically modified freezing devices allow the study of ion shifts related to dynamic processes in cells, for example, locomotion and exocytosis. The time resolution achieved by time-controlled cryofixation is approximately 1 ms.     

Structural changes in samples cryofixed by contact with a cold metal block

A common method of cryofixation is to bring a specimen rapidly in contact with a cold metal block. It is usually thought that during this process the surface of the specimen suffers little distortion since it freezes rapidly. Whether this is likely depends on the rate at which samples freeze compared with the speed at which the sample hits the cold block. There is some discrepancy between the published experimentally and theoretically determined freezing rates. As a contribution to this debate the distortion in cryofixed, freeze-substituted, striated muscle fibres has been investigated. In transverse sections, compression can be detected by deviations of the filament lattice from the hexagonal and used to estimate the time of freezing. Some specimens were frozen using a Gatan Cryosnapper, which freezes by catching the specimen between two nitrogen-cooled copper jaws. In addition, the speed with which the jaws close has also been determined. The results suggest that freezing of the well-preserved areas occurs in substantially less than 1 ms. This conclusion is supported by results obtained using metal-mirror apparatus in which the cushioned specimen was dropped onto a nitrogen- or helium-cooled copper block. All the specimens frozen against a cold block have a flat edge whereas muscle fibres are round. At the very edge there is evidence of structural damage as well as the more general lattice distortion.     

Controlled environment vitrification system: An improved sample preparation technique

The controlled environment vitrification system (CEVS) permits cryofixation of hydrated biological and colloidal dispersions and aggregates from a temperature- and saturation-controlled environment. Otherwise, specimens prepared in an uncontrolled laboratory atmosphere are subject to evaporation and heat transfer, which may introduce artifacts caused by concentration, pH, ionic strength, and temperature changes. Moreover, it is difficult to fix and examine the microstructure of systems at temperatures other than ambient (e.g., biological systems at in vivo conditions and colloidal systems above room temperature). A system has been developed that ensures that a liquid or partially liquid specimen is maintained in its original state while it is being prepared before vitrification and, once prepared, is vitrified with little alteration of its microstructure. A controlled environment is provided within a chamber where temperature and chemical activity of volatile components can be controlled while the specimen is being prepared. The specimen grid is mounted on a plunger, and a synchronous shutter is opened almost simultaneously with the release of the plunger, so that the specimen is propelled abruptly through the shutter opening into a cryogenic bath. We describe the system and its use and illustrate the value of the technique with TEM micrographs of surfactant microstructures in which specimen preparation artifacts were avoided. We also discuss applications to other instruments like SEM, to other techniques like freeze-fracture, and to novel “on the grid” experiments that make it possible to freeze successive instants of dynamic processes such as membrane fusion, chemical reactions, and phase transitions.     

Cooling rate and ice-crystal measurement in biological specimens plunged into liquid ethane,propane, and Freon 22

Specimens sandwiched between copper planchettes were plunged up to a depth of 430 mm into coolants used for cryofixation. Hydrated gelatin containing a miniature thermocouple was used to mimic the behaviour of tissue during freezing. Gelatin and red blood cells were used for ice-crystal analysis. Ethane produced the fastest cooling rates and the smallest ice-crystal profiles, and Freon 22 produced the slowest cooling rates and the largest crystal profiles. Smaller crystal profiles were often seen in the centre of the specimens than in subsurface zones. The results show that ethane, rather than propane, should be used for freezing metal-sandwiched freeze-fracture specimens by the plunging method, and probably also in the jet-cooling method. They further suggest that good cryofixation could occur at the centre of thin specimens rather than only at their surfaces. Comparison between theoretical and experimental ice-crystal sizes was satisfactory, indicating that where the experimental parameters can be defined then realistic predictions can be made regarding cryofixation results.     

A novel technique for flat-embedding cryofixed plant specimens in LR white resin

Acrylic LR White is used preferentially for many research applications because it possesses unique advantages over other commercially available resin types. LR White has low toxicity; its low viscosity and hydrophilic properties enable it to infiltrate specimens with comparative ease, and specimens embedded in LR White take up stains for light microscopy well and tend to retain superior antigenicity relative to other resins. These qualities make LR White a good choice for immunohistochemistry, light microscopy, and transmission electron microscopy. However, LR White does not heat-polymerize in the presence of oxygen, which precludes its use with many commercially available embedding molds. Furthermore, flat-embedding specimens in LR White is often an arduous task. Therefore, in this paper, we report on the development of novel flat-embedding chambers for use with LR White. Another goal of our studies was the rapid fixation of larger specimens. Chemical fixation was inadequate because of the time required for tissue infiltration, but cryofixation quickly and effectively immobilized intracellular organelles. Mean amyloplast positions differed in vertically oriented versus control specimens after chemical fixation, whereas no significant difference was observed after cryofixation. Furthermore, cryofixation provided acceptable preservation at the light microscopy level, even though our specimens were relatively larger. This underscores the utility of cryofixation for light microscopy determination of organelle positioning within plant cells.     

Cryofixation of monolayer cell cultures for freeze-fracturing without chemical pre-treatments

A cryofixation method is presented which gives excellent ultrastructural preservation of monolayer cell cultures without any chemical pretreatments. Rat hepatocytes in primary culture were used in this study. The equipment needed is inexpensive and easy to manufacture. Cells are grown on a usual tissue culture support material (Thermanox plastic sheets). For cryofixation, samples are prepared essentially by a combined sandwich-cryogen-jet technique. 3 mm large discs are punched out and sandwiched with Cu- or Au-object holders of little mass; a 15 μm spacer is put in between. The viability of the cells is not impaired by the manipulations before freezing. The sandwich sample is quickly frozen by shooting a propane jet from a simple pressure chamber on to the metal object holder. The relevant parameters were optimized by parallel freeze-fracture analyses of 5% glycerol as a model system and by thermocouple measurements. Sandwich samples are then mounted in an appropriate double replication specimen table for further analysis by freeze-fracturing. It is possible to obtain a certain selectivity of the fracture plane with regard to apical, lateral or basal aspects of the cell layer. Alternatively, disc samples can be processed by chemical fixation methods (including freeze substitution to determine the freeze-fracture plane), since the support material Thermanox is insensitive to organic solvents and easy to cut. In each case the cells remain attached to their substratum throughout the whole procedure. Thus, the ultrastructural data can be directly correlated with parallel functional analyses obtained from the same cell cultures.     

Long freeze-drying times are not necessary during the preparation of thin sections for X-ray microanalysis

The temperature profile that occurs when a brass block warms up in a vacuum evaporation unit was determined. Freshly drawn human blood was concentrated by centrifugation, and the pellet was cryofixed and cryosectioned. The cryosections were subject to different freeze-drying protocols, using a freeze-drier with a temperature-controlled stage, to determine the effect of freeze-drying time on element distribution. Spectra were collected by spot analyses at various distances across the interface between red cells and plasma. Concentrations of sodium were high and variable outside the cell and low in the cell interior, with potassium showing the reverse distribution. The number of counts under the iron peak closely followed the potassium distribution. The concentration of sodium was higher than expected at 40 nm inside the cell membrane. This was attributed to the formation of ice crystals at the interface between the cells and plasma during cryofixation and the use of a wide probe size.     

Embedding in Spurr's resin is a good choice for immunolabelling after freeze drying as shown with chemically unfixed dendritic cells

Immunocytochemical reactions on biological specimens depend on many factors, the most crucial one being the maintenance of antigenicity. Antigens are vulnerable at each stage during preparation for electron microscopy. One of the least traumatic methods of preparing biological tissues for post‐embedding immunolabelling includes the following steps: (1) physical stabilization of the native biological material by rapid freezing (cryofixation) and keeping the immobilized biological sample at low temperature, thereby avoiding any movements of water, ions and macromolecules; (2) dehydrating the frozen biological material by freeze‐drying at low temperature; (3) embedding of the dehydrated specimen. Here we show that embedding of chemically unfixed dendritic cells in Spurr's resin after cryofixation and freeze‐drying enables the conservation of fine ultrastructure without cell distortion or shrinkage. Furthermore, we demonstrate the feasibility of protein localization in ultrathin sections by immunolabelling of the major histocompatibility class II molecules.     

Resolution limits in the surface scanning electron microscope

An approximate theory is developed for estimating the limiting topographical resolution of the scanning electron microscope operating under certain idealized conditions. Limitations imposed by electron beam shot noise and electron diffusion effects within the specimen are considered for the case of an instrument incorporating a field emission source and in which there is ideal collection of the secondary electron signal. The specimen is assumed to be an homogeneous, isotropic solid with the beam incident normally to its surface. It is estimated that, under these ideal conditions, the limiting resolution for a metallic specimen lies in the region of 1 nm. The possibilities of realizing a resolution of this order in a practical instrument are discussed.     

The relative efficiency of cryogenic fluids used in the rapid quench cooling of biological samples

The heat transfer characteristics of various cryogenic fluids used in the rapid quench cooling of biological samples are examined. It is concluded that cryofixation should be achieved during the initial plunge stage of the cooling. Liquid nitrogen maintained near its melting point of 63·1 K at a pressure in excess of the critical value of 33·5 atm will produce the quickest cooling. Nitrogen could also provide the best ultrastructure at atmospheric pressure if the minimum plunge depth and velocity criteria are satisfied. Plunging bare thermocouples into cryogenic fluids will lead to erroneous conclusions about the relative cooling efficiencies of various liquids for cryofixation. A qualitative explanation for the results obtained by Silvester et al. (1982) during the rapid cooling of water drops in various fluids is proposed.     

A method for correcting the effect of specimen drift on coherent diffractive imaging

Coherent diffractive imaging involves the inversion of a diffraction pattern to find the wave function at the exit-surface plane of the specimen. It is a promising technique for imaging, for example, nanoparticles with electrons and biological molecules with X-rays. If the illumination is not a plane wave of infinite extent, then a relative drift between the illumination and the object introduces errors into the diffraction pattern; an issue which is often overlooked. This may be of particular importance for applications with electron microscopes which use nanoscale probes. Here we show that beams which are uniform over a sufficiently large region can be used to pose a phase retrieval problem that is immune from specimen drift, provided suitable analysis of the diffraction data is undertaken. The method only applies to objects contained within a support that is smaller than a uniform region of the beam.     

Freeze-fracture electron microscopic and low temperature X-ray scattering studies of the effect of cryofixation upon serum low density lipoprotein structure

We report here a correlated X-ray diffraction and freeze-fracture electron microscope study of the effects of several cryofixation procedures upon human serum low density lipoprotein (LDL₂) structure. Only when the LDL₂ solutions contained 75%, by weight, glycerol were the room temperature and post cryofixation low temperature LDL₂ X-ray scattering curves indistinguishable from one another. Other cryofixation procedures, slow or rapid, with or without glycerol, resulted in differences between the room temperature and low temperature LDL₂ X-ray scattering curves, in part due to the effect of quenching upon the solvent. Freezeetching electron microscopy of the slowly cryofixed LDL₂ showed marked aggregation of the particles and an unusual morphological appearance. In contrast, after rapid cryofixation or cryofixation in the presence of glycerol, freeze-etch electron microscopy revealed well-isolated particles which had a knobby morphology. The results demonstrate that under certain conditions (in the presence of 75% glycerol) cryofixation results in minimal, if any, structural alteration of, at least, the LDL₂ lipid moiety. Further, this study underlines the more general conclusion that any high resolution structural study employing a cryofixation step must be interpreted with caution and the effect of cryofixation upon the sample structure need be evaluated by independent means.     

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.     

An improved specimen loader for cryo-scanning electron microscopy

Cryo-electron microscopy of cryofixed samples is a well-established and accepted technique for imaging liquid-containing specimens without removing water and other volatile components. There are many steps between cryofixation and cryo-observation in the microscope, during which the sample and sample holder need to be handled. One such major step is the loading of the specimen onto the sample holder and the fixing of the sample holder onto the transfer mechanism. During this handling, the specimen is often exposed (mostly inadvertently) to moisture in the atmosphere, which results in frost deposition. The new specimen loader described here is designed to overcome the traditional tedious handling and to achieve ease in specimen loading. The modifications made are mainly towards allowing movement of the liquid freon cup, eliminating the need for a lock-screw and improving the shape of the stage holder, which makes the mounting of the specimen holder easy, thereby permitting smooth specimen loading without too much handling and with consequent reduced frost deposition.