Freezing of aqueous specimens: an X-ray diffraction study

The effects on water of two cooling methods, immersion in a liquid cryogen and high-pressure freezing, were studied by X-ray cryodiffraction on different sucrose solutions. The nature of the ice formed by each method depends on both the sucrose concentration and the specimen thickness. In order to compare the two methods, we mainly studied specimens having a thickness of 0.2 mm. Under these conditions, freezing by immersion gives rise to hexagonal (IH), cubic (IC) and amorphous (IV) ices when the sucrose concentration (weight/weight) has a value within the range 0–30%, 30–60%, 60% and higher, respectively. The temperature of the phase transitions IV–IC, IC–IH depends on the sucrose concentration. High-pressure freezing gives rise to two specific forms of ice: an amorphous and a crystalline ice (ice III). Ice III is observed when pure water samples are high-pressure frozen provided that the sample temperature does not rise above −150 °C. Above this temperature, ice III transforms into hexagonal ice. Amorphous ice is formed when the sucrose concentration is higher than 20%. The amorphous ice formed under high pressure has a similar, but not identical, X-ray diffraction pattern to that of amorphous ice formed at atmospheric pressure. While the X-ray diffraction pattern of amorphous ice formed at atmospheric pressure (IV) shows a broad ring at a position corresponding to 0.37 nm, that of high-pressure amorphous ice (IVHP) shows a broader ring, located at 0.35 nm. IVHP presents a phase transition (IVHP–IV) at temperatures that depend on the sucrose concentration. We also observed that some precautions have to be taken in order to minimize the alcohol contamination of high-pressure frozen samples. The ice-phase diagram presented in this paper should be taken into account in all methods dedicated to the structural study of frozen biological specimens.     

High-pressure freezing for the preservation of biological structure: Theory and practice

The two main advantages of cryofixation over chemical fixation methods are the simultaneous stabilization of all cellular components and the much faster rate of fixation. The main drawback pertains to the limited depth (<20 μm surface layer) to which samples can be well frozen when freezing is carried out under atmospheric conditions. High-pressure freezing increases the depth close to 0.6 mm to which samples can be frozen without the formation of structurally distorting ice crystals. This review discusses the theory of high-pressure freezing, the design of the first commercial high-pressure freezing apparatus (the Balzers HPM 010), the operation of this instrument, the quality of freezing, and novel structural observations made on high-pressure-frozen cells and tissues.     

A review of high-pressure freezing preparation techniques for correlative light and electron microscopy of the same cells and tissues

In this paper, we review some published studies using correlative light and electron microscopy methods. We further refined our criteria to include only those studies using live cells for light microscope and where high-pressure freezing was the method of specimen preparation for electron microscopy. High-pressure freezing is especially important for some difficult-to-fix samples, and for optimal preservation of ultrastructure in samples larger than a few micrometres. How the light microscope observations are done is completely sample dependent, but the choice of high-pressure freezer depends on the speed required to capture (freeze) the biological event of interest. For events requiring high time resolution (in the 4–5 s range) the Leica EM PACT2 with rapid transfer system works well. For correlative work on structures of interest that are either non-motile or moving slowly (minutes rather than seconds), any make of high-pressure freezer will work. We also report on some efforts to improve the capabilities of the Leica EM PACT2 rapid transfer system.     

High-pressure freezing of tissue obtained by fine-needle biopsy

High-pressure freezing (HPF) permits adequate cryoimmobilization (without detectable ice crystals after freeze-substitution) of biological tissue up to a thickness of about 200 μm. Until now the preparation of tissue prior to freezing has been unsatisfactory: sizing of the tissue to the required dimensions takes minutes, during which structural alterations must occur. We demonstrate that the use of a fine-needle biopsy technique minimizes tissue damage and guarantees sample dimensions close to the optimal thickness for HPF. The tissue cores can be cryoimmobilized within 40 s of excision.     

Electron microscopy of frozen biological objects: a study using cryosectioning and cryosubstitution

Freezing of bulk biological objects was investigated by X-ray cryodiffraction. Freezing at atmospheric pressure of most microscopic biological samples gives rise to large hexagonal crystals and leads to poor structural preservation of these specimens. High-pressure freezing induces the formation of different ices (hexagonal, cubic and a high-pressure form) consisting of crystals having sizes smaller than those formed at atmospheric pressure. With both freezing methods, a cryoprotectant has to be added to the biological object to avoid the formation of ice crystals. However, special cases can be encountered: some biological objects contain large amounts of natural cryoprotectant or have a low water content. In these cases, vitrification can be achieved, especially using high-pressure freezing. Cryo-sectioning can be performed on vitrified samples, and the sections studied by electron cryomicroscopy. Images and electron diffraction patterns having a resolution better than 2 and 0.2 nm, respectively, can be obtained with such sections. Because samples containing crystalline ices cannot be cryosectioned, their structure has to be studied using cryosubstitution and resin embedding. We show that bacteria, yeast, and ciliate and marine worm elytrum have cellular compartments with an organization that has not been described by classical techniques relying on chemical fixation of the tissues. A high-pressure artefact affecting the Paramecium trichocysts is described. Such artefacts are not general; for example, we show that 70% of high-pressure frozen yeast cells survive successive high-pressure freezing and thawing steps.     

Vitrification depth can be increased more than 10-fold by high-pressure freezing

Biological specimens prepared for cryoelectron microscopy seem to suffer less damage when they are frozen under 2 kbar pressure rather than under normal conditions. The volume that can be well preserved is larger. This fact has been illustrated in a number of publications on a number of different samples. However, there is a lack of quantitative data concerning the depth of this good specimen preservation. Catalase crystals in various sugar solutions have been used as test objects and vitrification, as determined by electron diffraction, has been used as the criterion for good freezing. Keeping all other conditions equal, the depth of vitrification is approximately 10 times larger with freezing at high, rather than normal, pressure. The high-pressure vitrification depth in a 15–20% sugar solution averages 200 μm. Fully vitrified specimens up to 700 μm in thickness are obtained. When crystalline water is observed it is frequently in the form of high-density ice II, III or IX. These results are probably also relevant for typical biological specimens. The advantage of high-pressure freezing must be balanced by the possible consequences of a considerably increased cooling time and by the damage that may be induced by the pressure.     

冰球结冰蓄冷过程的研究

采用摄动方法对冰球结冰蓄冷过程进行了计算;对冰于蓄冷时间、冰于外换热、冰球大小、壁厚和材料影响蓄冷过程的特性进行了分析,得到一些有益的结论,可以指导冰球的设计和系统的蓄冷控制。     

High-pressure freezing causes structural alterations in phospholipid model membranes

The influence of high-pressure freezing (HPF) on the lipid arrangement in phospholipid model membranes has been investigated. Liposomes consisting of pure dipalmitoylphosphatidylcholine (DPPC) and of DPPC mixed with a branched-chain phosphocholine (1,2-di(4-dodecyl-palmitoyl)-sn-glycero-3-phosphocholine) have been analysed by freeze-fracture electron microscopy. The liposomes were frozen either by plunging into liquid propane or by HPF. The characteristic macroripple-phase of the two-component liposome system is drastically changed in its morphology when frozen under high-pressure conditions. The influence of ethanol which acts as pressure transfer medium was ruled out by control experiments. In contrast, no high-pressure alterations of the pure DPPC bilayer membrane have been observed. We assume that the modification of the binary system is due to a pressure-induced relaxation of a stressed and unstable lipid molecule packing configuration. HPF was performed with a newly designed sample holder for using sandwiched copper platelets with the high-pressure freezing machine Balzers HPM010. The sandwich construction turned out to be superior to the original holder system with regard to freeze-fracturing of fluid samples. By inserting a spacer between the supports samples with a thickness of 20–100 μm can be high-pressure frozen. The sandwich holder is provided with a thermocouple to monitor cooling rates and allows exact sample temperature control. Despite a two-fold mass reduction compared to the original holder no HPF cooling rate improvement has been achieved (4000 °C s⁻¹). We conclude that the cooling process in high-pressure freezing is determined mainly by cryogen velocity.     

Vitrification of articular cartilage by high-pressure freezing

For more than 20 years, high-pressure freezing has been used to cryofix bulk biological specimens and reports are available in which the potential and limits of this method have been evaluated mostly based on morphological criteria. By evaluating the presence or absence of segregation patterns, it was postulated that biological samples of up to 600 μm in thickness could be vitrified by high-pressure freezing. The cooling rates necessary to achieve this result under high-pressure conditions were estimated to be of the order of several hundred degrees kelvin per second. Recent results suggest that the thickness of biological samples which can be vitrified may be much less than previously believed. It was the aim of this study to explore the potential and limits of high-pressure freezing using theoretical and experimental methods. A new high-pressure freezing apparatus (Lei?a EM HPF), which can generate higher cooling rates at the sample surface than previously possible, was used. Using bovine articular cartilage as a model tissue system, we were able to vitrify 150-μm-thick tissue samples. Vitrification was proven by subjecting frozen-hydrated cryosections to electron diffraction analysis and was found to be dependent on the proteoglycan concentration and water content of the cartilage. Only the lower radical zone (with a high proteoglycan concentration and a low water content compared to the other zones) could be fully vitrified. Our theoretical calculations indicated that applied surface cooling rates in excess of 5000 K/s can be propagated into specimen centres only if samples are relatively thin (<200 μm). These calculations, taken together with our zone-dependent attainment of vitrification in 150-μm-thick cartilage samples, suggest that the critical cooling rates necessary to achieve vitrification of biological samples under high-pressure freezing conditions are significantly higher (1000–100 000 K/s) than previously proposed, but are reduced by about a factor of 100 when compared to cooling rates necessary to vitrify biological samples at ambient pressure.     

Comparison of slam-freezing and high-pressure freezing effects on the DNA cholesteric liquid crystalline structure

Using in parallel electron microscopy of ultrathin frozen-hydrated sections and freeze-fracture replicas, we compare the ultrastructural consequences of two freezing techniques: slam-freezing at liquid helium temperature and high-pressure freezing, on a model system, the DNA cholesteric liquid crystalline phase. Both freezing techniques are able to vitrify DNA liquid crystalline solutions containing up to 85% water, but induce structural rearrangements of the molecular organization. The cholesteric structure is preserved by the slam-freezing method despite the formation of periodic distortions induced by the mechanical compressive stress. In contrast, high-pressure freezing does not preserve the structure of the liquid crystal: the long-range cholesteric stratification disappears, and the local continuous twist between molecules is modified. These results show that vitrification, though necessary, may not be a sufficient token of preservation of the native state of hydrated materials. We discuss the possible origins of the molecular rearrangements that have time to occur in the specimens as a result of the low freezing rate permitted by the high-pressure freezing process.     

OMRON CQM1 PLC在高压水射流去溢料机中的应用

介绍了OMRON CS1G系列PLC在高压水射流去溢料机中的应用，阐述了高压水射流去溢料机控制系统的组成和工作原理，叙述了OMRON CS1G系列PLC与触摸屏结合的控制方式，结合高压水射流去溢料机自动控制系统的特点，给出了系统的软硬件结构设计。该控制系统的控制精度和可靠运行等性能达到满意的效果。实际运行情况表明，系统运行稳定，能够满足生产的工艺要求。     

压缩机高压缸体失效分析与设计改进

高压压缩机高压缸阀座底部截面过度处裂纹,通过有限元应力分析,发现压缩机高压气缸阀腔底径厚度不够,阀腔底径偏小,由此对阀腔底径厚度和阀腔底径进行了设计改进,改进后的气缸未再开裂。     

海水淡化高压增压泵的设计与应用

介绍了反渗透海水淡化技术和高压增压泵的设计、选材和应用情况。解决了在进口高压下轴向力和密封问题。结果表明该泵国产化成功,是国内在反渗透海水淡化高压增压泵设计研发领域的进步。     

高压水射流清洗对基体去污效果及损伤的研究

利用高压水射流清洗技术对涂层及不同硬度工件进行冲击试验,利用白光干涉仪测定试验前后工件的涂层去除情况及表面粗糙度变化情况,并观察工件受冲击后表面产生的损伤微观形貌。结果表明,利用高压水射流清洗涂层时,选择具有涂层开放表面处入射可以快速使开放面扩张,涂层去除速度会呈直线增大;工件表面质量变化与初始表面质量无关,仅受水射流冲击环境影响;水射流冲击造成工件表面损伤,产生特殊形状孔洞,此种孔洞中部高度平缓,从中心沿径向向外逐步凹陷-突起-凹陷。     

柴油发动机高压共轨技术研究

介绍了柴油机高压共轨技术的发展现状,主要探讨柴油机高压共轨喷射系统的结构和原理,并对国外典型的高压共轨喷射系统进行研究和分析,最后总结国内各种高压共轨系统的最新进展,提出亟待解决的问题和研究目标。     

Self-pressurized rapid freezing (SPRF): a novel cryofixation method for specimen preparation in electron microscopy

A method is described for the cryofixation of biological specimens for ultrastructural analysis and immunocytochemical detection studies. The method employs plunge freezing of specimens in a sealed capillary tube into a cryogen such as liquid propane or liquid nitrogen. Using this method a number of single-cell test specimens were well preserved. Also multicellular organisms, such as Caenorhabditis elegans , could be frozen adequately in low ionic strength media or even in water. The preservation of these unprotected specimens is comparable to that achieved with high-pressure freezing in the presence of cryoprotectant. The results are explained by the fact that cooling of water in a confined space below the melting point gives rise to pressure build-up, which may originate from the conversion of a fraction of the water content into low-density hexagonal ice and/or expansion of water during supercooling. Calculations indicate the pressure may be similar in magnitude to that applied in high-pressure freezing. Because the specimens are plunge cooled, suitable cryogens are not limited to liquid nitrogen. It is shown that a range of cryogens and cryogen temperatures can be used successfully. Because the pressure is generated inside the specimen holders as a result of the cooling rather than applied from an external source as in high-pressure freezing, the technique has been referred to as self-pressurized rapid freezing.     

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.     

干冰升华式天然气水合物孔底冷冻取样器的研制

针对天然气水合物的赋存特点,研制天然气水合物孔底冷冻取样器。取样器是以干冰为冷冻剂,酒精为助冷催化剂和载冷剂的冷冻方式来实现孔底冷冻岩样。介绍了取样器的技术参数、冷冻方式原理、工作原理和结构特点。     

Heptane and isooctane as embedding fluids for high-pressure freezing of Petunia ovules followed by freeze-substitution

In comparison with other fixation methods, high-pressure freezing and freeze-substitution of Petunia ovules lead to improved ultrastructural preservation of all tissues. Crucial for adequate high-pressure freezing is the absence of air in the specimen sandwich; air has to be replaced by an embedding fluid. Frequently, 1-hexadecene is used for this purpose. Using 1-hexadecene as an embedding fluid resulted in only 5–10% of Petunia ovules being preserved without disturbance of the ultrastructure due to ice-crystal damage. Since 1-hexadecene is not soluble in acetone at − 90 °C, freeze-substitution is hindered when ovules remained completely surrounded by it; this results in recrystallization when the temperature is raised. We tested and compared the suitability of heptane and isooctane as embedding fluids for high-pressure freezing and freeze-substitution, reasoning that because of their low melting points and low relative densities, phase separation during freeze-substitution would result in complete exposure of the ovules to the substitution medium, leading to adequate freeze-substitution. Using either heptane or isooctane as an embedding fluid yielded up to 90% ice-crystal-free ovules. Both compounds, however, have some damaging effects on the outer one or two cell layers of the ovule, but not on the inner tissues.     

High-pressure freezing for immunocytochemistry

Ultrastructural immunocytochemistry requires that minimal damage to antigens is imposed by the processing methods. Immersion fixation in cross-linking fixatives with their potential to damage antigens is not an ideal approach and rapid freezing as an alternative sample-stabilization step has a number of advantages. Rapid freezing at ambient pressure restricts the thickness of well-frozen material obtainable to ≈ 15 μm or less. In contrast, high-pressure freezing has been demonstrated to provide ice-crystal-artefact-free freezing of samples up to 200 μm in thickness. There have been few reports of high-pressure freezing for immunocytochemical studies and there is no consensus on the choice of post-freezing sample preparation. A range of freeze-substitution time and temperature protocols were compared with improved tissue architecture as the primary goal, but also to compare ease of resin-embedding, polymerization and immunocytochemical labelling. Freeze-substitution in acetone containing 2% osmium tetroxide followed by epoxy-resin embedding at room temperature gave optimum morphology. Freeze-substitution in methanol was completed within 18 h and in tetrahydrofuran within 48 h but the cellular morphology of the Lowicryl-embedded samples was not as good as when samples were substituted in pure acetone. Acetone freeze-substitution was slow, taking at least 6 days to complete, and gave blocks which were difficult to embed in Lowicryl HM20. Careful handling of frozen samples avoiding rapid temperature changes reduced apparent ice-crystal damage in sections of embedded material. Thus a slow warm-up to freeze-substitution temperature and a long substitution time in acetone gave the best results in terms of freezing quality and cellular morphology. No clear differences emerged between the different freeze-substitution media from immunocytochemical labelling experiments.