活体肺癌组织玻璃化保存的研究

保存活体的肺癌组织将为肺癌发病基因筛查和靶向药物筛选等体外实验研究提供更完整的样本信息. 本文对活体肺癌组织的玻璃化保存方法进行研究，首先采用针浸法玻璃化保存单块肺癌组织，对所需低温保护剂的浓度和平衡时间进行了优化；其次采用冻存管对多块肺癌组织样本进行玻璃化保存，对低温保护剂溶液体积以及平衡时间进行了优化；最后对慢速冷冻、不加低温保护剂快速冷冻、玻璃化冷冻3种冷冻方法的冻存效果进行比较并通过低温显微分析其冰晶损伤机理.结果表明，20% EG+20% DMSO+0.5 mol/L海藻糖作为低温保护剂，在平衡溶液和玻璃化溶液分别加载3 min和1 min时，针浸法和0.25 ml冻存管内玻璃化冻存，复苏后组织活力最高，分别约为79.96%与80.44%. 免疫组化显示玻璃化保存肺癌组织经过复苏后，相比慢速冷冻和无保护剂快速冷冻，组织结构损伤较小，组织内细胞TUNEL阳性表达较少. 低温显微结果表明，玻璃化保存组织内部及周围只出现少量细小冰晶，而慢速冷冻、快速冷冻组织皆出现明显冰晶.     

Physiological Response of Neurospora Conidia to Freezing in the Dehydrated, Hydrated, or Germinated State

This study concerned the response to freezing of Neurospora crassa conidia in four different states: air-dry, hydrated in water, hydrated in Vogel medium lacking only sucrose, or hydrated in complete Vogel medium. All hydrated conidia were incubated in one of the above media for various times before freezing and were then washed and frozen in distilled water. Viability was estimated by three techniques, and the agreement among them was good. Hydration of air-dry conidia was found to be very rapid and, once hydrated, the conidia were much more sensitive to rapid freezing than they were before hydration. Rapidly cooled conidia survived freezing to a much higher extent when the warming rate was rapid than when it was slow; slowly cooled conidia showed little or no dependence on the warming rate. This sensitivity to rapid cooling and slow warming was attributed to the effects of intracellular ice. The sensitivity to freezing could be reversed by dehydrating the conidia in vacuo before freezing; thus, it was concluded that the presence or absence of water is the determining factor in the initial sensitivity due to freezing. In water, the sensitivity remained constant from 2 min to 15 days after hydration. Although conidia hydrated in growth medium lacking sucrose remained metabolically inactive, their sensitivity to rapid freezing decreased as a function of time in the medium before freezing. The reason for this decreased sensitivity is not understood. Conidia hydrated in complete growth medium (i.e., containing sucrose) became metabolically active and, after the initial sensitivity associated with hydration, became increasingly more sensitive to freezing as a function of their time in the medium. Drying itself was deleterious to metabolically active conidia, and those that survived dehydration did not exhibit a large absolute increase in resistance to subsequent freezing. The increase in sensitivity to freezing and to drying seems associated with the presence of metabolic activity; however, the precise cause of the sensitization remains obscure.     

Physiological response of Neurospora conidia to freezing in the dehydrated, hydrated, or germinated state.

This study concerned the response to freezing of Neurospora crassa conidia in four different states: air-dry, hydrated in water, hydrated in Vogel medium lacking only sucrose, or hydrated in complete Vogel medium. All hydrated conidia were incubated in one of the above media for various times before freezing and were then washed and frozen in distilled water. Viability was estimated by three techniques, and the agreement among them was good. Hydration of air-dry conidia was found to be very rapid and, once hydrated, the conidia were much more sensitive to rapid freezing than they were before hydration. Rapidly cooled conidia survived freezing to a much higher extent when the warming rate was rapid than when it was slow; slowly cooled conidia showed little or no dependence on the warming rate. This sensitivity to rapid cooling and slow warming was attributed to the effects of intracellular ice. The sensitivity to freezing could be reversed by dehydrating the conidia in vacuo before freezing; thus, it was concluded that the presence or absence of water is the determining factor in the initial sensitivity due to freezing. In water, the sensitivity remained constant from 2 min to 15 days after hydration. Although conidia hydrated in growth medium lacking sucrose remained metabolically inactive, their sensitivity to rapid freezing decreased as a function of time in the medium before freezing. The reason for this decreased sensitivity is not understood. Conidia hydrated in complete growth medium (i.e., containing sucrose) became metabolically active and, after the initial sensitivity associated with hydration, became increasingly more sensitive to freezing as a function of their time in the medium. Drying itself was deleterious to metabolically active conidia, and those that survived dehydration did not exhibit a large absolute increase in resistance to subsequent freezing. The increase in sensitivity to freezing and to drying seems associated with the presence of metabolic activity; however, the precise cause of the sensitization remains obscure.     

Review article fine structure of the exocrine cells of rat sublingual gland revealed by rapid freezing and freeze substitution method

The ultrastructure of mucous cells of rat sublingual gland processed by rapid freezing, followed by freeze substitution, was compared with that obtained by the standard chemical fixation technique. The rapid freezing method gave a very good preservation of membrane structure with round and discrete mucous droplets (granules) not showing any sign of coalescence. The cisterns of the Golgi apparatus and the trans Golgi network also were well preserved. Upon secretory stimulation by pilocarpine, mucous droplets were discharged by the usual mechanism of exocytosis. From all these findings it emerged that mucous cells had the same structural characteristics as serous cells. In the endpieces of rat sublingual gland prepared by the rapid freezing method, serous cells aligned with mucous cells around the central lumen, and no cap-like arrangement of serous cells (demilunes) was observed. Furthermore, computer reconstruction of stereo images from serial section light micrographs prepared by the rapid freezing method showed that, within a given endpiece, all serous cells had direct access to the lumen and that they were disseminated throughout it and not only in its fundus. From our observations it seems very likely that, at least in rat sublingual gland, serous demilunes are an artificial product caused by the compression exerted on serous cells by the mucous cells distended during the conventional fixation procedure.     

Pathology of structured water and associated cations in cells (ther tissue damage syndrome) and its medical treatment

Modern experimental evidence indicates that the cell should be regarded as analogous to an ion exchanger resin granule with structured water in the interstices and with potassium and sodium ions associated with fixed negative charges on the protein matrix. In tissues damaged by disease or trauma, a similar set of changes in properties of cell cations and water is to be expected, for which a similar set of therapies is appropriate. Tissue damage causes a configurational change of the protein matrix from the normal to the damaged state. This leads to loss of association preference for potassium vs. sodium ions and to loss of water structuring, resulting in replacement of cell potassium by sodium and abnormal uptake of water by the cell. Appropriate therapies for reestablishment of the normal configurational state of the proteins of the cell are reestablishment of normal cell ATP production, for which prostaglandin PGBx is the rational approach, plus diets or drugs that decrease sodium and/or increase potassium concentrations in the body. Partial normalization of cell protein configuration by digitalis compounds may also be possible.     

A rapid and reliable procedure for extraction of cellular polyamines and inorganic ions from plant tissues

A fast and reliable method for the extraction of cellular polyamines and major inorganic ions (Ca, Mg, Mn, K, and P) from several plant tissues is described. The method involves repeated freezing and thawing of samples instead of homogenization. The efficiency of extraction of both the polyamines and inorganic ions by these two methods was compared for 10 different tissues. In each case, the freeze-thaw procedure resulted in a precise and quantitatively equal, or greater, yield than homogenization. Freeze-thawing not only eliminates the need for various tissue homogenizers (such as polytrons, tissumizers, and mortars and pestles), but it is so simple that a large number of samples can be processed simultaneously. We routinely processed 50–80 samples for quantitation of polyamines and inorganic ions. Freeze-thawing was equally useful for the extraction of polyamines from liver, spleen, and kidney tissues of mice.New Hampshire Agricultural Experiment Station, scientific contribution no. 1845.     

Cooling rate influences cryoprotectant distribution and organ dehydration in freezing wood frogs.

Ice formation in the freeze-tolerant wood frog (Rana sylvatica) induces the production and distribution of the cryoprotectant, glucose. Concomitantly, organs undergo a beneficial dehydration which likely inhibits mechanical injury during freezing. Together, these physiological responses promote freezing survival when frogs are frozen under slow cooling regimes. Rapid cooling, however, is lethal. We tested the hypothesis that the injurious effects of rapid cooling stem from an inadequate distribution of glucose to tissues and an insufficient removal of water from tissues during freezing. Accordingly, we compared glucose and water contents of five organs (liver, heart, skeletal muscle, eye, brain) from wood frogs cooled slowly or rapidly during freezing to -2.5 degrees C. Glucose concentrations in organs from slowly cooled frogs were significantly elevated over unfrozen controls, but no significant increases occurred in rapidly cooled frogs. Organs from slowly cooled frogs contained significantly less water than did those from controls, whereas water contents from rapidly cooled frogs generally were unchanged. Rapid cooling therefore inhibited the production and distribution of cryoprotectant and organ dehydration during freezing. This inhibition may result from an accelerated, premature failure of the cardiovascular system.     

Smooth muscle adherens junctions associated proteins are stable at the cell periphery during relaxation and activation

This study was performed to determine the stability of the adherens junction (AJ)-associated proteins at the smooth muscle cell (SMC) plasma membrane during relaxing and activating conditions. Dog stomach, ileum, colon, and trachea tissues were stored in Ca²⁺-free PSS or regular PSS or were activated in 10 µM carbachol in PSS before rapid freezing. The tissues were subsequently sectioned and immunoreacted using antibodies for vinculin, talin, fibronectin, and caveolin to determine their cellular distribution in these tissues under these conditions. In all four tissues and under all three conditions, the distribution of these four proteins remained localized to the periphery of the cell. In transverse tissue sections, the AJ-associated proteins formed a distinct punctate pattern around the periphery of the SMCs at the plasma membrane. These domains alternated with the caveolae (as identified by the presence of caveolin). In longitudinal tissue sections, the AJ-associated proteins formed continuous tracks or staves, while the caveolae remained punctate in this dimension as well. Caveolin is not present in the tapered ends of the SMCs, where the AJ-associated proteins appear continuous around the periphery. Densitometry of the fluorophore distribution of these proteins showed no shift in their localization from the SMC periphery when the tissues were relaxed or when they were activated before freezing. These results suggest that under physiologically relaxing and activating conditions, AJ-associated proteins remain stably localized at the plasma membrane. vinculin; talin; fibronectin; caveolin; stomach; ileum; colon; trachea     

Ultrastructure of bovine embryos frozen and thawed by a two-step freezing method

An ultrastructural evaluation of a rapid tow-step freezing method, by which 6-7-day-old bovine embryos equilibrated in 1.4 M glycerol in Dulbecco's phosphate-buffered saline were frozen and thawed, was undertaken. In all non-frozen control embryos trophoblastic and embryonic cells formed a spherical structure enclosed by an intact zona pellucida. The spacial arrangement of the cells of the frozen embryos was less regular and the surrounding zona pellucida was damaged in approximately half of the cases. Some embryonic cells had increased electron density and lysosomal content showing reaction sites for acid phosphatase. In all frozen embryos, cytoplasmic defects appearing as non-membrane-bound 'empty spaces' were observed more frequently in the trophoblastic cells than in the embryonic cells. Culture of frozen embryos for 24 h revealed that cells appearing nondefective after culture may have the capability of organizing a viable embryonic structure. It was found that the most commonly used freezing method is associated with certain morphological changes. However, no additional cryoinjuries were observed in comparisons with the more complicated freezing procedures using dimethylsulfoxide as cryoprotectant.     

Particle segregation in chromaffin granule membranes by forced physical contact

Bovine chromaffin granules were exposed to different isotonic non-ionic and ionic solutions (sucrose; Ca²⁺ - and Mg²⁺-free phosphate-buffered saline; $\text{Tris-HCl + NaCl}$; Ca²⁺- and Mg²⁺-free phosphate-buffered $\text{saline + sucrose; Tris-HCl + sucrose}$) at pH 7 and then frozen either in suspension or as firm pellets. Freezing was performed without prefixation or antifreeze treatments either by ‘standard’ techniques (approx. 1 mm³ suspended or pelleted material on gold specimen supports dipped into liquid Freon) or with increased cooling rates by spraying suspensions into liquid propane (‘spray-freezing’). Regardless of the freezing method, membrane-intercalated particles were always randomly distributed when chromaffin granules were frozen in suspension. In contrast, forced physical contact between granules produced by centrifugation ($\text{12 000 × g, 25}\text{min}$) provoked dispersal of membrane-intercalated particles, but only in the presence of ions. Sucrose or EDTA in an ionic environment had no inhibitory effect. The following conclusions are derived: (1) Even below the reported phase transition region particle clustering is possible. (2) Chromaffin granule membranes are not liable to thermotropic segregation of membrane-intercalated particles. (3) Although the low freezing rates of ‘standard’ freezing techniques produce large-scale segregation artefacts (by which suspended chromaffin granules are pushed together within the segregated solute) this does not result in intramembraneous particle segregation. (4) Forced physical contact produces a Ca²⁺-independent particle segregation, but only when repulsive electrostatic forces of membrane components are partially screened in an ionic environment. (5) This does not invalidate results obtained by others, showing Ca²⁺-mediated chromaffin granule agglomeration and segregation of membrane-intercalated particles, but it might indicate the occurrence of another, not directly Ca²⁺-dependent particle segregation mechanism in a prefusional stage of close membrane-to-membrane contact during exocytosis.     

Mechanisms of intracellular ice formation.

The phenomenon of intracellular freezing in cells was investigated by designing experiments with cultured mouse fibroblasts on a cryomicroscope to critically assess the current hypotheses describing the genesis of intracellular ice: (a) intracellular freezing is a result of critical undercooling; (b) the cytoplasm is nucleated through aqueous pores in the plasma membrane; and (c) intracellular freezing is a result of membrane damage caused by electrical transients at the ice interface. The experimental data did not support any of these theories, but was consistent with the hypothesis that the plasma membrane is damaged at a critical gradient in osmotic pressure across the membrane, and intracellular freezing occurs as a result of this damage. An implication of this hypothesis is that mathematical models can be used to design protocols to avoid damaging gradients in osmotic pressure, allowing new approaches to the preservation of cells, tissues, and organs by rapid cooling.     

Intracellular freezing, viability, and composition of fat body cells from freeze-intolerant larvae of Sarcophaga crassipalpis.

Although it is often assumed that survival of freezing requires that ice formation must be restricted to extracellular compartments, fat body cells from freeze-tolerant larvae of the gall fly, Eurosta solidaginis (Diptera, Tephritidae) survive intracellular freezing. Furthermore, these cells are highly susceptible to inoculative freezing by external ice, undergo extensive lipid coalescence upon thawing, and survive freezing better when glycerol is added to the suspension medium. To determine whether these traits are required for intracellular freeze tolerance or whether they are incidental and possessed by fat body cells in general, we investigated the capacity of fat body cells from nondiapause-destined and diapause-destined (i.e., cold-hardy) larvae of the freeze-intolerant flesh fly Sarcophaga crassipalpis (Diptera, Sarcophagidae) to survive intracellular freezing. Fat body cells from both types of larvae were highly susceptible to inoculative freezing; all cells froze between -3.7 to -6.2 degrees C. The highest rates for survival of intracellular freezing occurred at -5 degrees C. The addition of glycerol to the media markedly increased survival rates. Upon thawing, the fat body cells showed little or no lipid coalescence. Fat body cells from E. solidaginis had a water content of only 35% compared to cells from S. crassipalpis larvae that had 52-55%; cells with less water may be less likely to be damaged by mechanical forces during intracellular freezing.     

Immunocytochemical localization of nerve growth factor: effects of fixation

The fixation dependence of immunocytochemically demonstrable nerve growth factor (NGF) was investigated. Several commonly used fixation methods have been employed, including buffered formaldehyde, Bouin's fluid, and chloroform-methanol, as well as freezing and cryostat sectioning. The immunostaining technique was an immunoenzyme bridge procedure on either paraffin sections or frozen sections. Of those methods tested, fixation for 1 hr in a buffered formaldehyde appeared to provide optimal preservation and localization of immunoreactive material. Using this method, reaction product was localized in granules of the granular tubule cells of the male mouse submandibular gland. Prolonged fixation in buffered formaldehyde resulted in a diffuse background staining and loss of granule immunoreactivity. In frozen sections and in tissues fixed with either Bouin's solution, chloroform-methanol, or buffered paraformaldehyde-glutaraldehyde increased cytoplasmic background staining and loss of granule immunoreactivity were observed. It was concluded that, for the localization of NGF at the light microscopic level, a brief (1 hr) buffered formaldehyde fixation is optimal.     

The effects of rapid cooling (cold shock) of ram semen, photoperiod, and egg yolk in diluents on the survival of spermatozoa before and after freezing

The effects of rapid cooling of semen (cold shock) from 30 degrees C to various temperatures above 0 degrees C on survival of ram spermatozoa suspended in diluents with or without egg yolk were assessed before and after freezing. Rapid cooling of extended semen from 30 to 15 degrees C had little or no effect on spermatozoa survival before or after freezing. Rapid cooling of extended semen from 30 degrees C to 10, 5, or 0 degrees C was accompanied by a progressive decrease in percentage of motile spermatozoa and percentage of intact acrosomes before freezing and a decrease in percentage of motile spermatozoa and after freezing. The ability of spermatozoa motile after cold shock to survive freezing and thawing, evaluated as cryosurvival, was not significantly (P greater than 0.05) affected by the temperature to which semen was cooled. The addition of egg yolk to the initial extender had a beneficial effect on percentage of motile spermatozoa particularly after rapid cooling of semen to 10 and 5 degrees C. Although egg yolk had little effect before freezing on semen rapidly cooled to temperatures above 15 degrees C and therefore not actually cold shocked, it substantially improved the subsequent survival of spermatozoa after freezing and thawing. Percentage of motile spermatozoa after cooling and after freezing was generally higher when the semen was collected during a decreasing photoperiod than during an increasing photoperiod.     

A comparative study of the effects of freezing and frozen storage on intact and demembranated bull spermatozoa

The damage caused to bull sperm by freezing and thawing them without cryoprotectants was assessed in both intact and membrane-extracted cells. Preparations of membrane-extracted cells were produced by treating the sperm with 0.1% Triton X-100 and motility was restored with exogenously applied ATP and Mg²⁺. Motile demembranated sperm showed no detectable reduction in motility after freezing and thawing. In contrast, when intact cells where subjected to freezing and thawing they lost all motility. These damaged cells were also restored to motility when exogenous ATP and Mg²⁺ were added to the sperm mixture. Apparently freezing and thawing sperm cells causes damage to the plasma membrane which permits ATP and Mg²⁺ to freely enter or leave the cells, but does not damage the components of the sperm cell which generate motility.The effects of storage temperature on frozen demembranated sperm were also explored. Sperm held at ?20 °C showed marked structural changes and progressively decreased motility after prolonged storage. When sperm were frozen at ?20 °C the mitochondrial structures were completely lost after 48 to 72 hr and ATP caused the disintegration of the flagellum rather than initiating motility. Sperm which were frozen at ?76 °C retained motility after short periods of storage, but showed a significant decline in motility when thawed after 8 days. Demembranated sperm which were kept frozen at ?196 °C showed no significant loss of motility when thawed after 1 year of storage.     

Evaluation of two approaches to the quantitative histochemical localization of sucrose-P synthase in leaves

Summary Two methods for determining the quantitative localization of sucrose-P synthase in plant tissues were evaluated. The single-cell method (rapid freezing, freeze-drying, microdissection, micro-analysis) was validated in several ways, including comparative biochemistry, comparative histochemistry, and kinetics. In contrast, bulk isolation of cells by protoplast-forming methods resulted in loss of sucrose-P synthase activity. This latter approach is widely used and, as far as we are aware, can be successfully used for measurement of other enzymes. Thus, our observations form the basis for a specific caution against the use of protoplast-forming methods in an assay protocol for sucrose-P synthase.     

Equilibrium,quasi-equilibrium,and nonequilibrium freezing of mammalian embryos

The first successful freezing of early embryos to −196°C in 1972 required that they be cooled slowly at ∼1°C/min to about −70°C. Subsequent observations and physical/chemical analyses indicate that embryos cooled at that rate dehydrate sufficiently to maintain the chemical potential of their intracellular water close to that of the water in the partly frozen extracellular solution. Consequently, such slow freezing is referred to as equilibrium freezing. In 1972 and since, a number of investigators have studied the responses of embryos to departures from equilibrium freezing. When disequilibrium is achieved by the use of higher constant cooling rates to −70°C, the result is usually intracellular ice formation and embryo death. That result is quantitatively in accord with the predictions of the physical/chemical analysis of the kinetics of water loss as a function of cooling rate. However, other procedures involving rapid nonequilibrium cooling do not result in high mortality. One common element in these other nonequilibrium procedures is that, before the temperature has dropped to a level that permits intracellular ice formation, the embryo water content is reduced to the point at which the subsequent rapid nonequilibrium cooling results in either the formation of small innocuous intracellular ice crystals or the conversion of the intracellular solution into a glass. In both cases, high survival requires that subsequent warming be rapid, to prevent recrystallization or devitrification. The physical/ chemical analysis developed for initially nondehydrated cells appears generally applicable to these other nonequilibrium procedures as well.     

RAPID RELEASE OF THE ZYMOGEN GRANULE PROTEIN BY OSMIUM TETROXIDE AND ITS RETENTION DURING FIXATION BY GLUTARALDEHYDE

Fixation by osmium tetroxide and glutaraldehyde of zymogen granules isolated from rat parotid and pancreas was investigated. Protein determinations showed that osmium tetroxide caused rapid release of most of the soluble protein of the granule during fixation in buffered isotonic sucrose. Such granules when examined in the electron microscope after shadow casting appeared quite flat, indicating that most of the contents had indeed been removed. Numerous damaged membranes of the granules were also observed. In contrast, zymogen granules fixed by glutaraldehyde and shadow cast essentially retained the spherical shape and the protein contents. The application of the shadow-casting technique in quantitative studies on the protein content of zymogen granules is discussed.     

Manifestations of cell damage after freezing and thawing

The nature of the primary lesions suffered by cells during freezing and thawing is unclear, although the plasma membrane is often considered the primary site for freezing injury. This study was designed to investigate the nature of damage immediately after thawing, by monitoring several functional tests of the cell and the plasma membrane. Hamster fibroblasts, human lymphocytes, and human granulocytes were subjected to a graded freeze-thaw stress in the absence of cryoprotective compound by cooling at -1 degree C/min to a temperature between -10 and -40 degrees C, and then were either warmed directly in water at 37 degrees C or cooled rapidly to -196 degrees C before rapid warming. Mitochondrial function in the cells was then assessed using 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyl-tetrazolium bromide (MTT), fluorescein diacetate (FDA), colony growth, and osmometric response in a hypertonic solution. Cells behaved as osmometers after cooling at -1 degree C/min to low temperatures at which there were no responses measured by other assays, indicating that the plasma membrane is not a primary site for injury sustained during slow cooling. These results also indicate that the FDA test does not measure membrane integrity, but reflects the permeability of the channels through which fluorescein leaves the cells. Fewer cells could respond osmotically after cooling under conditions where intracellular freezing was likely, implying that the plasma membrane is directly damaged by the conditions leading to intracellular freezing. A general model of freezing injury to nucleated mammalian cells is proposed in which disruption of the lysosomes constitutes the primary lesion in cells cooled under conditions where the cells are dehydrated at low temperatures.     

The cryopreservation of fish thymocytes and its potential application for immunological reconstitution experiments

Fish thymocytes were cryopreserved by two methods, a programmed freezing method by a direct control system and a mechanical freezing method. There was no loss of viability or ability to respond to Concanavalin A compared to control thymocytes, up to 5 months after cryopreservation, and no difference between the two methods.