Dose tolerance at helium and nitrogen temperatures for whole cell electron tomography

Electron tomography is currently the only method that allows the direct three-dimensional visualization of macromolecules in an unperturbed cellular context. In principle, tomography should enable the identification and localization of the major macromolecular complexes within intact bacteria, embedded in amorphous ice. In an effort to optimize conditions for recording data that would bring us close to the theoretical limits, we present here a comparison of the dose tolerance of Caulobacter crescentus cells embedded in amorphous ice at liquid helium versus liquid nitrogen temperature. The inner and outer cell membranes, and the periodic structure of the S-layer of this Gram-negative bacterium provide ideal features to monitor changes in contrast and order as a function of dose. The loss of order in the S-layer occurs at comparable doses at helium and nitrogen temperatures. Macroscopic bubbling within the cell and the plastic support develops at both temperatures, but more slowly at helium temperature. The texture of the bubbles is finer in initial stages at helium temperature, giving an impression of contrast reversal in some parts of the specimen. Bubbles evolve differently in different organelles, presumably a consequence of their different chemical composition and mechanical properties. Finally, the amorphous ice "flows" at helium temperature, causing changes in the relative positions of markers within the specimen and distorting the cells. We conclude that for cryo-electron tomography of whole cells liquid nitrogen temperature provides better overall data quality.     

Preparation of smears of isolated hepatocytes and the glycogen preservation in them after cryopreservation of the liver tissue

A method is proposed for preparation of smears of isolated hepatocytes from liver samples frozen in liquid nitrogen or dry ice. The thawing of liver samples and the preparation of smears of isolated hepatocytes were produced by a successive maintenance of the samples in a mixture of 0.067 M phosphate buffer and 5% sucrose (pH 8.0) at 20 degrees C, followed by placing in 0.067 M phosphate buffer (pH 7.4) at the same temperature. Then hepatocytes were fixed by methanol. The cytofluorometric analysis has shown that isolation of cells from the frozen and thawing liver tissue using the proposed method does not influence the level of glycogen preservation in the hepatocytes. The proposed method may be used in the clinical practice.     

SELDI-TOF MS of quadruplicate urine and serum samples to evaluate changes related to storage conditions

Proteomic profiling with SELDI-TOF MS has facilitated the discovery of disease-specific protein profiles. However, multicenter studies are often hindered by the logistics required for prompt deep-freezing of samples in liquid nitrogen or dry ice within the clinic setting prior to shipping. We report high concordance between MS profiles within sets of quadruplicate split urine and serum samples deep-frozen at 0, 2, 6, and 24 h after sample collection. Gage R&R results confirm that deep-freezing times are not a statistically significant source of SELDI-TOF MS variability for either blood or urine.     

Characterisation of cryoinjury in Euglena gracilis using flow-cytometry and cryomicroscopy

Flow-cytometry and cryomicroscopy elucidated that the unicellular algal protist Euglena gracilis was undamaged by cryoprotectant added at 0 degree C, and super-cooling in the absence of ice. Cryoinjuries were however induced by: osmotic shock resulting from excessive cryodehydration, intracellular ice, and fracturing of the frozen medium on thawing. Suboptimal cooling at -0.3 degrees C min(-1) to -60 degrees C and osmotic shock invariably resulted in damage to the organism's pellicle and osmoregulatory system causing, a significant (P > 0.005) increase in cell size. Cell damage was not repairable and led to death. The responses of E. gracilis to cryopreservation as visualised by flow-cytometry and cryomicroscopy assisted the development of an improved storage protocol. This comprised: cryoprotection with methanol [10%(v/v)] at 0 degree C, cooling at 0.5 degrees C min(-1) to -60 degrees C, isothermal hold for 30 min, and direct immersion in liquid nitrogen. Highest post-thaw viability (>60%) was obtained using two-step thawing, which involved initial slow warming to -130 degrees C followed by relatively rapid warming (approximately 90 degrees C min(-1)) to ambient temperature (ca. 25 degrees C).     

Meeting the COVID challenge: Optimizing vCD34+ in cryopreserved HPC samples for implementation of an external QA Program

BackgroundThe COVID-19 pandemic has forced a fundamental change in the global procurement of allogeneic hematopoietic progenitor cells (HPCs) for transplantation. To better meet the emergent challenges of transporting cryopreserved allogeneic HPC during pandemics, there is an urgent need for External Quality Assurance (EQA) programs to evaluate reproducibility and harmonization of viable CD34⁺ cell (vCD34⁺) HPC enumeration, as the current EQA programs are unsuitable for analysis of vCD34⁺. The cost-effective distribution of HPC cryopreserved reference samples (CRSs) with acceptable reproducibility and specificity is key to the success of a vCD34⁺ EQA program.MethodsCryopreserved HPC samples (n = 11) were either stored on dry ice for 1 to 4 days or for 1 day followed by liquid nitrogen (LN) storage for 1 to 3 days to assess optimal conditions for vCD34⁺ EQA. Flow cytometric enumeration of vCD34⁺ HPCs was performed using a single platform assay combined with 7-AAD viability dye exclusion. The optimum transportation condition was validated in pilot and multicenter national studies (n = 12).ResultsA combination of 1 day on dry ice followed by LN storage stabilized viability compared with continuous storage on dry ice. This study demonstrates that dispatch of CRSs on dry ice to recipient centers across a distance of ≤4000 km within 26 h, followed by LN storage, resulted in reproducible intercenter vCD34⁺ enumeration. The estimated cost of safer and more convenient dry ice delivery is >20-fold lower than that of LN.ConclusionThis approach can form the basis for economically and scientifically acceptable distribution of CRSs for external vCD34⁺ EQA.     

Inhibiting ice recrystallization and optimization of cell viability after cryopreservation

The ice recrystallization inhibition activity of various mono- and disaccharides has been correlated with their ability to cryopreserve human cell lines at various concentrations. Cell viabilities after cryopreservation were compared with control experiments where cells were cryopreserved with dimethylsulfoxide (DMSO). The most potent inhibitors of ice recrystallization were 220?mM solutions of disaccharides; however, the best cell viability was obtained when a 200?mM d-galactose solution was utilized. This solution was minimally cytotoxic at physiological temperature and effectively preserved cells during freeze-thaw. In fact, this carbohydrate was just as effective as a 5% DMSO solution. Further studies indicated that the cryoprotective benefit of d-galactose was a result of its internalization and its ability to mitigate osmotic stress, prevent intracellular ice formation and/or inhibit ice recrystallization. This study supports the hypothesis that the ability of a cryoprotectant to inhibit ice recrystallization is an important property to enhance cell viability post-freeze-thaw. This cryoprotective benefit is observed in three different human cell lines. Furthermore, we demonstrated that the ability of a potential cryoprotectant to inhibit ice recrystallation may be used as a predictor of its ability to preserve cells at subzero temperatures.     

Recovery of viable cells from rabbit skin biopsies after storage at ?20°C for up to 10?days

Frozen animal tissues are thought to be appropriate for use as a donor for somatic cell nuclear transfer. This makes the freezing for long term storage a valuable tool for breeders needing to protect an animal population that is endangered by sanitary problems or for cryobanking of genetic resources. We report the successful cryopreservation of explants of skin derived from small biopsies from rabbit ear biopsies by using a protocol that can be easily performed by usual breeders, which are not equipped with cooling devices. By optimizing the procedure, we show that small biopsies can be kept at -20°C in a physiological solution containing 10% DMSO for up to 20 days before being deeply frozen in liquid nitrogen for long-term storage. After 10 days of storage at -20°C, the rate of viability of biopsies was similar to the control one (86 and 82% respectively). After 20 days of storage at -20°C, the rate of viability was dramatically lowered (39%), but it still allows to recover a significant population of viable cells from the preserved sample. Being appropriate to places lacking specific device, such a very simple technique may contribute to facilitate genome banking policies dedicated to the management of genetic resources in wild and domestic animals.     

Storage of pathogenic leptospires in liquid nitrogen

The virulence and viability of various serovars of Leptospira interrogans were successfully preserved by storage in liquid nitrogen. Dimethyl sulphoxide at a final concentration of 2.5% (v/v) was added as cryoprotectant to a culture of leptospires grown in Ellinghausen-McCullough-Johnson-Harris medium. Ampoules were cooled at a controlled rate of 1 degree-3 degrees C/min to -70 degrees C, then transferred to the liquid phase of a liquid nitrogen storage unit. Glycerol was discounted as a cryoprotectant as it was found to be approximately 10 times more toxic than dimethyl sulphoxide to four of five serovars used in this study. The viability of nine strains has so far been observed over a period of 8-22 months storage in liquid nitrogen and full viability of all strains has been preserved over this period. Virulence of strains of serovars pomona and hardjo was well preserved, as demonstrated by challenge tests in guinea pigs and domestic pigs.     

Storage of pathogenic leptospires in liquid nitrogen

The virulence and viability of various serovars of Leptospira interrogans were successfully preserved by storage in liquid nitrogen. Dimethyl sulphoxide at a final concentration of 2.5% (v/v) was added as cryoprotectant to a culture of leptospires grown in Ellinghausen-McCullough-Johnson-Harris medium. Ampoules were cooled at a controlled rate of 1°–3°C/min to −70°C, then transferred to the liquid phase of a liquid nitrogen storage unit. Glycerol was discounted as a cryoprotectant as it was found to be approximately 10 times more toxic than dimethyl sulphoxide to four of five serovars used in this study. The viability of nine strains has so far been observed over a period of 8–22 months storage in liquid nitrogen and full viability of all strains has been preserved over this period. Virulence of strains of serovars pomona and hardjo was well preserved, as demonstrated by challenge tests in guinea pigs and domestic pigs.     

Preservation of viable cells in the undercooled state

Previous studies into the mechanisms governing the freezing of cells in the absence of extracellular ice have been extended to develop a method for the preservation of viable cells in the undercooled state. Deep undercooling of cells is achieved by suspending fine droplets of the cells in oil to make an emulsion, thus minimizing initiation of extracellular ice nucleation. Attempts to preserve yeast cells, cultured sainfoin cells, and dissected shoot-tips (pea and potato) in this way are described. The main findings are that yeast cells can be preserved undercooled at -20 degrees C for at least 16 weeks with no detectable loss of viability, showing that -20 degrees C is a low enough temperature for inhibition of significant biochemical deterioration and that the emulsions are stable over long periods. In preliminary experiments, sainfoin cells survived 24 hr at -10 degrees C, and shoot-tips survived 48 hr at -10 degrees C. Sainfoin cells, conditioned by growth in medium supplemented with sorbitol, showed enhanced survival after exposure to low temperatures and a lower intracellular freezing point than control cells. Possible reasons for this are discussed.     

Cryopreservation of Doritaenopsis suspension culture by vitrification

 Cells of a suspension culture of Doritaenopsis cv. New Toyohashi were placed in a mixture of 2 M glycerol and 0.4 M sucrose for 15 min at room temperature and then dehydrated with a vitrification solution (PVS2) for 1–3 h on ice and plunged into liquid nitrogen. The highest viability (64% by 2,3,5-triphenyltetrazolium chloride stainability) was obtained when the cells were precultured in liquid New Dogashima medium with 0.1 M sucrose and 1.0 mg/l abscisic acid for 1 week at 25  °C in the light. Dehydration by PVS2 was important for the cryopreservation of Doritaenopsis cells. Protocorm-like bodies were induced from cryopreserved cells without morphological variations. Received: 18 January 2000 / Revision received: 16 June 2000 / Accepted: 22 June 2000     

Millimeter wave absorption spectra of biological samples

A solid-state computer-controlled system has been used to make swept-frequency measurements of absorption of biological specimens from 26.5 to 90.0 GHz. A wide range of samples was used, including solutions of DNA and RNA, and suspensions of BHK-21/C13 cells, Candida albicans, C krusei, and Escherichia coli. Sharp spectra reported by other workers were not observed. The strong absorbance of water (10--30 dB/mm) caused the absorbance of all aqueous preparations that we examined to have a water-like dependence on frequency. Reduction of incident power (to below 1.0 microW), elimination of modulation, and control of temperature to assure cell viability were not found to significantly alter the water-dominated absorbance. Frozen samples of BHK-21/C13 cells tested at dry ice and liquid nitrogen temperatures were found to have average insertion loss reduced to 0.2 dB/cm but still showed no reproducible peaks that could be attributed to absorption spectra. It is concluded that the special resonances reported by others are likely to be in error.     

Development of cell line preservation method for research and industry producing useful metabolites by plant cell culture

The cell culture ofAngelica gigas Nakai producing decursin derivatives and immunostimulating polysaccharides was preserved in liquid nitrogen after pre-freezing in a deep freezer at −70°C for 480 min. The effects of the cryoprotectant and pretreatment before cooling were investigated to obtain the optimal procedure for cyropreservation. When compared to mannitol, sorbitol, or NaCl with a similar osmotic pressure, 0.7M sucrose was found to be the best osmoticum for the cryopreservation ofA. gigias cells. In the pre-culture medium, the cells in the exponential growth phase showed the best post-freezing survival after cryopre-servation. A mixture of sucrose, glycerol, and DMSO was found to be an effective cryoprotectant and a higher concentration of the cryoprotectant provided better cell viability. When compared with the vitrification, the optimum cryopreservation method proposed in this study would seem to be more effective for the long-term storage of suspension cells. The highest relative cell viability established with the optimal procedure was 89%.     

疫霉属菌种的液氮超低温保藏

对疫霉属的15个种68株菌和霜疫霉2株菌进行了液氮超低温的保藏试验并得到成功。比较了冷冻速度、保护剂和解冻速度对菌存活的影响。严格控制每分钟降温摄氏1度直到-40℃后再放入液氮罐中,对疫霉和霜疫霉来说都是非常必要的。这种降温程序可通过简单设备人工操作达到。而直接由室温降到-150℃以下会损伤菌种以致死亡。在所用的保护剂中,不论10％甘油还是5-15％二甲基亚砜都能起到保护作用。尚看不出对那种保护剂有特别的要求,似可任意选用。至于解冻条件,由液氮中取出放置在38℃水浴中快速融化与在20℃水浴中中等速度融化效果相等,对菌的成活都没有太大影响。我们的试验肯定了在有保护剂存在下,用慢速冷冻可以在液氮中保存疫霉和霜疫霉。     

Freeze-thaw-refreeze cycle to prepare lymphocytes for HLA antibody detection or tissue typing

Human lymphocytes stored in the frozen state may be thawed, placed on cytotoxicity plates, refrozen, rethawed and used for screening sera or tissue-typing of the cells. The simple procedure described uses only a ?90 °C refrigerator for both freezing and storage of the cells. The technique permits a laboratory to collect a variety of cells over a long period, so that a set of test plates with cells from 10 to 20 donors can be prepared when a convenient number of donor cells are available. Also, the refrozen cells in cytotoxicity test plates may be warmed to the temperature of dry ice for 24 hr, returned to the refrigerator set at a slightly lower temperature, and at a later time, these cells may be thawed and used for serum screening. In view of these results, it appears possible to ship the refrozen cells from one laboratory to another using simple dry ice storage during the transfer. Negative reactions due to soluble antigens in the suspending sera can be obviated by washing out these sera and replacing them with medium 199 or alternatively, fetal calf serum can be used to replace the human serum in the suspending media.     

A simple cell transport device keeps culture alive and functional during shipping

Transporting living complex cellular constructs through the mail while retaining their full viability and functionality is challenging. During this process, cells often suffer from exposure to suboptimal life‐sustaining conditions (e.g. temperature, pH), as well as damage due to shear stress. We have developed a transport device for shipping intact cell/tissue constructs from one facility to another that overcomes these obstacles. Our transport device maintained three different cell lines (Caco2, A549, and HepG2 C3A) individually on transwell membranes with high viability (above 97%) for 48 h under simulated shipping conditions without an incubator. The device was also tested by actual overnight shipping of blood brain barrier constructs consisting of human induced pluripotent brain microvascular endothelial cells and rat astrocytes on transwell membranes to a remote facility (approximately 1200 miles away). The blood brain barrier constructs arrived with high cell viability and were able to regain full barrier integrity after equilibrating in the incubator for 24 h; this was assessed by the presence of continuous tight junction networks and in vivo‐like values for trans‐endothelial electrical resistance (TEER). These results demonstrated that our cell transport device could be a useful tool for long‐distance transport of membrane‐bound cell cultures and functional tissue constructs. Studies that involve various cell and tissue constructs, such as the “Multi‐Organ‐on‐Chip” devices (where multiple microscale tissue constructs are integrated on a single microfluidic device) and studies that involve microenvironments where multiple tissue interactions are of interest, would benefit from the ability to transport or receive these constructs. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:1257–1266, 2017     

玻璃化冷藏条件对连香树定芽细胞存活率及微结构的影响

选择6种保护剂、2种玻璃化方式和2种低温处理方式对连香树定芽的冷藏条件进行筛选,用TTC还原法测定冷藏定芽的细胞存活率,并用电子显微镜观察定芽细胞冷冻时的受损情况,以优选连香树定芽的冷藏技术条件。结果表明:(1)保护剂、玻璃化方式、冷藏温度均对莲香树定芽的细胞存活率具有显著影响,不同冷藏处理的定芽组织细胞内冰晶形状、数量不同,细胞破裂数也不同。(2)连香树定芽的最佳冷藏条件为:用含甘油35.0mL、乙烯乙二醇20.0mL、DMSO 15.0mL、甘氨酸1.0mg和3%蔗糖脱氨MS液体培养基组成的100mL保护剂于真空下浸泡30min,再经-20℃预冻处理6h后,于液氮中玻璃化和冷藏60d,其定芽细胞的存活率最高,相对存活率达95%。(3)细胞微结构观察显示,在该优选条件下明显抑制了连香树定芽细胞内冰晶体的形成,消除了冰晶对细胞的涨破和刺伤,其细胞结构完整无损伤。     

Survival of Suspension-cultured Sycamore Cells Cooled to the Temperature of Liquid Nitrogen

Suspension-cultured cells of sycamore (Acer pseudoplatanus L.) which were immersed in liquid nitrogen after prefreezing to the temperatures from −30 to −50 C in the presence of dimethylsulfoxide and glucose as cryoprotective additive could proliferate vigorously when rewarmed rapidly in water at 40 C. For maintaining high viability of the cells after immersion in liquid nitrogen, it seems to be essential to use the cells at the later lag phase or the early cell division phase. This study provides a possibility for long term preservation in liquid nitrogen of plant-cultured lines.     

Stabilization of frozen Lactobacillus delbrueckii subsp. bulgaricus in glycerol suspensions: Freezing kinetics and storage temperature effects

The interactions between freezing kinetics and subsequent storage temperatures and their effects on the biological activity of lactic acid bacteria have not been examined in studies to date. This paper investigates the effects of three freezing protocols and two storage temperatures on the viability and acidification activity of Lactobacillus delbrueckii subsp. bulgaricus CFL1 in the presence of glycerol. Samples were examined at -196 degrees C and -20 degrees C by freeze fracture and freeze substitution electron microscopy. Differential scanning calorimetry was used to measure proportions of ice and glass transition temperatures for each freezing condition tested. Following storage at low temperatures (-196 degrees C and -80 degrees C), the viability and acidification activity of L. delbrueckii subsp. bulgaricus decreased after freezing and were strongly dependent on freezing kinetics. High cooling rates obtained by direct immersion in liquid nitrogen resulted in the minimum loss of acidification activity and viability. The amount of ice formed in the freeze-concentrated matrix was determined by the freezing protocol, but no intracellular ice was observed in cells suspended in glycerol at any cooling rate. For samples stored at -20 degrees C, the maximum loss of viability and acidification activity was observed with rapidly cooled cells. By scanning electron microscopy, these cells were not observed to contain intracellular ice, and they were observed to be plasmolyzed. It is suggested that the cell damage which occurs in rapidly cooled cells during storage at high subzero temperatures is caused by an osmotic imbalance during warming, not the formation of intracellular ice.     

Viability of Bacillus popilliae after Lyophilization of Liquid Nitrogen Frozen Cells

The per cent viability of Bacillus popilliae after lyophilization of liquid nitrogen frozen cells was determined. Lyophilization of 9- to 12-hr cells which had been suspended in 5% sodium glutamate plus 0.5% gum tragacanth, frozen in liquid nitrogen vapor, and dried 4 to 5 hr with the ampoules exposed to room temperature resulted in survival of 64.6% of the original cells. After storage of these lyophilized preparations for 6 months at room temperature, 10.5% of the original cells were still viable.