Microbiological analysis of cryopreserved human heart valves after storage: a survey of 3 banks in Spain

Several reports have shown liquid nitrogen containers as not being sterile. Microorganism transmission has been observed in different cells and tissues stored under this condition, but there is no data on contamination of stored human valves. We performed a survey on heart valve banking in Spain. Regarding the questionnaire, we have a complete microbiological analysis of 304 thawed tissues prior to implant. In six cases positive culture results were observed. Patient follow-up did not reveal any adverse effects. Although some other possibilities should be stated, contamination of heart valves during storage in liquid nitrogen should be considered as a risk element in tissue banking. Strategies to asses and prevent microbial transmission from liquid nitrogen to heart valve banking ought to be further developed.     

The origin, ultrastructure, and microbiology of the sediment accumulating in liquid nitrogen storage vessels

During long-term cryopreservation, ice sediment accumulates in storage Dewars and poses a risk of microbial contamination to stored samples. Ice accumulates in liquid nitrogen via two general processes: (1) ice forming in the atmosphere above an open Dewar falls into the vessel; and (2) ice forming on cold surfaces of the Dewar or inventory system enters the liquid nitrogen. These ice crystals aggregate and entrap other materials, such as bacteria, fungal spores, and general laboratory debris present within the liquid nitrogen. Measured changes in the ultrastructure of ice aggregates following long-term storage are consistent with transient warming events to temperatures of -100 degrees C. Bacteria were identified in all samples and filamentous fungi in 9 out of 10 samples. These micro-organisms are commonly found in the environment and would not be expected to have been derived from IVF samples. Some of the bacteria identified are associated with nosocomial infections in humans. The implications that the association of microbial contamination with ice crystals has on cryopreservation procedures are discussed.     

Non-transmission of bacterial and viral microbes to embryos and semen stored in the vapour phase of liquid nitrogen in dry shippers

Cryopreservation and storage of germplasm is an important factor in the prevention of disease transmission by embryo transfer and artificial insemination. Here we report the results of an investigation on transmission of selected bacterial and viral pathogens by the vapour phase of liquid nitrogen (VPLN) to embryos and semen in dewars designed for short-term storage and transportation of biological specimens. In this study transmission of Pseudomonas aeruginosa, Escherichia coli, Staphylococcus aureus, BVDV, and BHV-1 was examined from: (1) contaminated dry shippers to germplasm; (2) between contaminated and non-contaminated cryopreserved germplasm; and (3) between stock culture of pathogenic agents and germplasm. Contaminated and non-contaminated samples of embryos and semen were stored in proximity in the vapour phase LN in open containers for 7 days prior to testing for the presence of microbes. The results showed that there was no cross-contamination from either the contaminated dewars to germplasm or between contaminated and non-contaminated samples of embryos and semen during 7 days storage under LN vapours. The outcome of our investigation indicates that VPLN is a safe means for short-term storage of embryos and semen in dry shipper dewars commonly used for transportation of bovine germplasm.     

Frozen fungi: cryogenic storage is an effective method to store Fusarium cultures for the long‐term

Microbial culture collections provide a vast amount of genotypic and phenotypic information which are invaluable resources for future advancements in research. For most microbial strains, cryopreservation in the vapour phase above liquid nitrogen provides the most stable and long‐term storage method. However, in the case of fungal microbes, not all are suited for cryogenic storage and few studies have addressed the effectiveness of storage in the vapour phase above liquid nitrogen on a diverse collection of Fusarium species. In this work, a collection of 374 Fusarium strains from the Fungal Genetics Stock Center, including 24 unique species, were duplicated and sent to the National Laboratory for Genetic Resource Preservation for storage in the vapour phase above liquid nitrogen. After 5 years of storage the entire collection was tested for viability and phenotypic stability by using plating, cellular staining assays, assessing the number of viable cells and measuring the rate of growth of each isolate. Additionally, the rate of growth for ～10% of the isolates were compared with the same isolates which had been stored at ?80°C at the Fungal Genetics Stock Center over the same timeframe to determine if cryopreservation in liquid nitrogen vapour provided a comparable method of storage. All National Laboratory for Genetic Resources Preservation isolates grew after being stored at ?165°C for 5 years. In general, the isolates that were stored at ?165°C grew at a faster rate than the isolates stored at ?80°C for the same period. Of the isolates stored at ?165°C, most had greater than 80% cell viability, however, those isolates that had less than 50% cell viability generally also had fewer conidia germinate. These isolates may be at a greater risk for storage over longer times. In conclusion, storage at ?165°C liquid nitrogen provided reliable preservation of a diverse collection of Fusarium spp. over 5 years, and culture viability data indicates that they will remain viable during additional storage for longer periods.     

Storage of seed in liquid nitrogen

Germination percentages of 24 species of seeds stored in liquid nitrogen for 600 days were compared with those stored at 5 °C in sealed containers. There were no obvious changes in germination caused either by the freezing and thawing process, or by the 600-day storage in liquid nitrogen. Ease of procedure, costs, and possible application to plant breeders and geneticists are discussed.     

Cancellous bone homograft storage with aluminium-polyethylene bags

In order to transport and cryopreserve human tissues, it is essential to have an easy-to-use recipient where tissues can be kept in sterile conditions. Here we show the results obtained by using Macopharma’s tissue freezing bags, an aluminium-polyethylene multilayer bag, in our tissue bank of the Centro Comunitario de Sangre y Tejidos de Asturias. Five hundred and twenty-seven cancellous bone homografts were obtained from hospitals located 120 km around our Bank. The homografts were submitted to bacteriological controls and sent to our bank in these bags. They were stored at −70 °C and sent in dry ice to about 50 hospitals, where the tissue was bacteriologically controlled and grafted. Furthermore, the behaviour of these bags at −140 °C (vapour nitrogen) or −196 °C (liquid nitrogen) was tested. Our results indicate that Macopharma aluminium-polyethylene bags are suitable for the transporting and cryopreserving of cancellous bone homografts. These bags could also be used for keeping tissues in nitrogen containers.     

Effects of temperature and desiccation on ex situ conservation of nongreen fern spores

? Premise of the study: Fern spores are unicellular and haploid, making them a potential model system to study factors that regulate lifespan and mechanisms of aging. Aging rates of nongreen spores were measured to compare longevity characteristics among diverse fern species and test for orthodox response to storage temperature and moisture. ? Methods: Aging of spores from 10 fern species was quantified by changes in germination and growth parameters. Storage temperature ranged from ambient room to -196°C (liquid nitrogen); spores were dried to ambient relative humidity (RH) or using silica gel. ? Key results: Survival of spores varied under ambient storage conditions, with one species dying within a year and two species having greater than 50% survival after 3 years. Few changes in germination or growth were observed in spores stored at either -80°C or -196°C over the same 3-yr study period. Spores stored at -25°C aged anomalously quickly, especially those dried to ambient RH or subjected to repeated freeze-thaw cycles. ? Conclusions: Spore longevity is comparable to orthodox seed longevity under ambient storage conditions, with wide variation among species and shelflife extended by drying or cooling. However, faster aging during freezer storage may indicate a similar syndrome of damage experienced by seeds categorized as "intermediate". The damage is avoided by storage at -80°C or liquid nitrogen temperatures, making cryoconservation an effective and broadly applicable tool to extend fern spore longevity. The study demonstrates that spore banks are a feasible approach for ex situ conservation of this important plant group.     

Polypropylene straw ampoules for the storage of microorganisms in liquid nitrogen

Liquid nitrogen storage systems are widely used for long term preservation of a range of microorganisms. Strains are stored in ampoules immersed in nitrogen or held in its evolving vapour. Immersion storage maximises the storage capacity of a vivostat but imposes limits on the type of ampoule that can be used. It is of vital importance that an ampoule can be sealed to prevent leakage of the nitrogen during storage. Several ampoule types are commercially avaailable but all have a number of disadvantages in use. They are costly, wasteful of space and difficult to seal reliably. An ampoule which can be simply made in the laboratory from polypropylene drinking straws has been described which is cheap, space saving and easy to seal. These ampoules have been in use for ten years without any problems and their use in the storage of over 2000 strains, predominantly fungi, is described. They have no detrimental effect on strain retrieval as shown by recovery rates after protracted storage. Straw ampoules provide a cheap and safe alternative to those ampoules that are commercially available and can be recommended for use in liquid nitrogen storage systems.     

Nonrandom RNAseq gene expression associated with RNAlater and flash freezing storage methods

RNA sequencing is a popular next‐generation sequencing technique for assaying genome‐wide gene expression profiles. Nonetheless, it is susceptible to biases that are introduced by sample handling prior gene expression measurements. Two of the most common methods for preserving samples in both field‐based and laboratory conditions are submersion in RNAlater and flash freezing in liquid nitrogen. Flash freezing in liquid nitrogen can be impractical, particularly for field collections. RNAlater is a solution for stabilizing tissue for longer‐term storage as it rapidly permeates tissue to protect cellular RNA. In this study, we assessed genome‐wide expression patterns in 30‐day‐old fry collected from the same brood at the same time point that were flash‐frozen in liquid nitrogen and stored at ?80°C or submerged and stored in RNAlater at room temperature, simulating conditions of fieldwork. We show that sample storage is a significant factor influencing observed differential gene expression. In particular, genes with elevated GC content exhibit higher observed expression levels in liquid nitrogen flash‐freezing relative to RNAlater storage. Further, genes with higher expression in RNAlater relative to liquid nitrogen experience disproportionate enrichment for functional categories, many of which are involved in RNA processing. This suggests that RNAlater may elicit a physiological response that has the potential to bias biological interpretations of expression studies. The biases introduced to observed gene expression arising from mimicking many field‐based studies are substantial and should not be ignored.     

Viral contamination of embryos cryopreserved in liquid nitrogen

Despite the worldwide application of embryo-freezing technology as the means of preserving germplasm of mammalian species, there is no information available on the possible transmission of infectious agents to cryopreserved embryos via contaminated liquid nitrogen (LN). Recently, it has been reported that new methods of cryopreservation which employ ultrarapid freezing or vitrification require direct contact between the freezing medium containing oocytes or embryos and liquid phase nitrogen (LPN). As models for human and animal viral pathogens three bovine viruses, bovine viral diarrhea virus (BVDV), bovine herpesvirus-1 (BHV), and bovine immunodeficiency virus (BIV), were employed to study the potential for their transmission by experimentally contaminated LN to embryos frozen and stored in open freezing containers. Bovine embryos in a mixture of 20% ethylene glycol, 20% ME(2)SO, and 0.6% sucrose were vitrified in either unsealed standard 0.25 ml or modified open pulled straws or in plastic cryovials and then plunged into contaminated LPN. After 3-5 weeks of storage in LN, embryos were thawed and sequentially washed and only those with intact ZP were pooled together and tested in batches of three for viral contamination. From this pool of 83 batches, 13 of 61 (21.3%) batches exposed to BVDV and BHV-1 tested positive for viral association while all 22 batches exposed to BIV in unsealed containers tested negative. All control embryos vitrified in sealed cryovials and straws were free from viral contamination.     

Experimental microbial contamination and disinfection of dry (vapour) shipper dewars designed for short-term storage and transportation of cryopreserved germplasm and other biological specimens

Cryopreservation, storage and transport of cryopreserved germplasm without the risk of disease transmission is of great concern to animal and human health authorities. Here we report on the efficacy of microbial decontamination of the liquid nitrogen (LN) dry (vapour) shippers used for short-term storage and transportation of germplasm and other biological specimens. Dry shippers containing either a hydrophobic or a non-hydrophobic LN absorbent were experimentally contaminated with high titers of cultures of Pseudomonas aeruginosa, Escherichia coli, Staphylococus aureus, bovine viral diarrhea virus (BVDV) and bovine herpesvirus-1 (BHV-1). Biocidals with broad spectrum antimicrobial activity and gas vapours of formalin and ethylene oxide were used for disinfection of the dewars. Among the biocidals used, treatment with sodium hypochlorite solution, the quaternary ammonium-based disinfectants and peracetic acid were the most effective and useful for dry shippers with a hydrophobic LN absorbent. None of the bacterial or viral microorganisms were detected in samples of semen and embryos stored in dry shippers following their disinfection with these biocides. An application of some other disinfectants, due to their foaming properties or to the permeability of the absorbent hydrophobic membrane (HM) was not effective or may have caused irreversible damage to the LN absorbent. Gas sterilization by ethylene oxide in contrast to formalin was fully effective for both types of dry shippers.     

Long-Term Storage of Infective Microsporidian Spores in Liquid Nitrogen

Thirty-one species of microsporidia, isolated from insects and stored in liquid nitrogen for up to 25 yr, were infectious when removed from liquid nitrogen. The natural hosts of all of these microsporidia were terrestrial insects, representing six different insect orders: Coleoptera, Diptera, Hemiptera, Hymenoptera, Lepidoptera, and Orthoptera. All microsporidia from terrestrial insects that were tested survived storage in liquid nitrogen, while Nosema algerae , a microsporidium from aquatic mosquito hosts did not survive freezing in liquid nitrogen. A Nosema species from the alfalfa weevil, Hypera postica , lost some infectivity in a water storage medium after 25 yr in liquid nitrogen. Liquid nitrogen storage of microsporidian spores in 50% and 100% glycerol media reduced loss of infectivity and is recommended for extended storage of microsporidia from terrestrial insect hosts.     

Virtual nitrogen tank to monitor frozen cell stocks

We developed a program to facilitate the monitoring of biological samples (cell lines, sera, etc.) that are stored in liquid nitrogen containers. The program consists of a "virtual" container in which scientists can store their samples and a program that records the location of each sample, cell characteristics, storage dates, names of the manipulators and much more. Additional comments and a photograph can be associated with each vial, allowing for reliable tracking of samples. Vials can then be identified according to any parameter of interest to the scientist, including associated comments. Once identified, the program visually presents the location of these vials, which simplifies retrieving them from the real container. The program records the thawing of vials, along with the date and the name of the operator. Any academic laboratory requesting this standalone program will be granted a free license for its use.     

Surface Sampling of Spores in Dry-Deposition Aerosols

The ability to reliably and reproducibly sample surfaces contaminated with a biological agent is a critical step in measuring the extent of contamination and determining if decontamination steps have been successful. The recovery operations following the 2001 attacks with Bacillus anthracis spores were complicated by the fact that no standard sample collection format or decontamination procedures were established. Recovery efficiencies traditionally have been calculated based upon biological agents which were applied to test surfaces in a liquid format and then allowed to dry prior to sampling tests, which may not be best suited for a real-world event with aerosolized biological agents. In order to ascertain if differences existed between air-dried liquid deposition and biological spores which were allowed to settle on a surface in a dried format, a study was undertaken to determine if differences existed in surface sampling recovery efficiencies for four representative surfaces. Studies were then undertaken to compare sampling efficiencies between liquid spore deposition and aerosolized spores which were allowed to gradually settle under gravity on four different test coupon types. Tests with both types of deposition compared efficiencies of four unique swabbing materials applied to four surfaces with various surface properties. Our studies demonstrate that recovery of liquid-deposited spores differs significantly from recovery of dry aerosol-deposited spores in most instances. Whether the recovery of liquid-deposited spores is overexaggerated or underrepresented with respect to that of aerosol-deposited spores depends upon the surface material being tested.     

Sperm cryostorage in a dry tank: An accurate alternative

This prospective study aimed to determine the effects of dry nitrogen cryostorage on human sperm characteristics in comparison with liquid nitrogen cryostorage. For this purpose, 42 men undergoing routine semen analysis (21 normozoospermia and 21 with altered semen parameters) were analyzed. After slow freezing, half of the straws of each sample were randomly stored in liquid and dry tanks, at the top and bottom levels of the latter. After 6 months storage, thawed samples were treated by density gradient centrifugation and sperm characteristics were compared. There was no difference in sperm progressive motility (15.1% ± 14.2% vs. 15.1% ± 12.7%; p = 0.76), sperm vitality (25.5% ± 17.7% vs. 26.2% ± 19%; p = 0.71), percentages of acrosome-reacted spermatozoa (38% ± 8.5% vs. 38.5% ± 7.4%; p = 0.53) and DNA fragmentation spermatozoa (27.3% ± 12.4% vs. 28.5% ± 12.9%, p = 0.47) after cryostorage in the dry or the liquid nitrogen tank. Moreover, we did not observe differences between either cryostorage system for normal and altered sperm samples. This lack of difference was also observed whatever the floor level of cryostorage in the dry tank. The temperature measurement of the dry tank showed a stable temperature at −194 °C throughout storage whatever the storage floor level, guaranteeing the stability of the low temperatures suitable for human sperm storage. Because of its greater safety, dry storage without contact with the liquid phase should be preferred and can be a useful alternative for the cryostorage of human sperm samples.     

Do-It-Yourself device for recovery of cryopreserved samples accidentally dropped into cryogenic storage tanks

Liquid nitrogen is colorless, odorless, extremely cold (-196 °C) liquid kept under pressure. It is commonly used as a cryogenic fluid for long term storage of biological materials such as blood, cells and tissues (1,2). The cryogenic nature of liquid nitrogen, while ideal for sample preservation, can cause rapid freezing of live tissues on contact - known as 'cryogenic burn' (2), which may lead to severe frostbite in persons closely involved in storage and retrieval of samples from Dewars. Additionally, as liquid nitrogen evaporates it reduces the oxygen concentration in the air and might cause asphyxia, especially in confined spaces (2). In laboratories, biological samples are often stored in cryovials or cryoboxes stacked in stainless steel racks within the Dewar tanks (1). These storage racks are provided with a long shaft to prevent boxes from slipping out from the racks and into the bottom of Dewars during routine handling. All too often, however, boxes or vials with precious samples slip out and sink to the bottom of liquid nitrogen filled tank. In such cases, samples could be tediously retrieved after transferring the liquid nitrogen into a spare container or discarding it. The boxes and vials can then be relatively safely recovered from emptied Dewar. However, the cryogenic nature of liquid nitrogen and its expansion rate makes sunken sample retrieval hazardous. It is commonly recommended by Safety Offices that sample retrieval be never carried out by a single person. Another alternative is to use commercially available cool grabbers or tongs to pull out the vials (3). However, limited visibility within the dark liquid filled Dewars poses a major limitation in their use. In this article, we describe the construction of a Cryotolerant DIY retrieval device, which makes sample retrieval from Dewar containing cryogenic fluids both safe and easy.     

Proceedings: Preservation and storage of microorganisms in the gas phase of liquid nitrogen

Methods are described which permit the rapid preparation and retrieval of suspensions of microorganisms stored in the gas space of a liquid nitrogen refrigerator.Inocula are currently used for assay plates, turbidimetric assays, bioautograph plates, and various fermentation processes. The most suitable suspending agents, 10% glycerol with 5% of either lactose, maltose, or raffinose, were devised by determining viabilities from alternate freezing and thawing of cell suspensions.Four milliliters each of concentrated cell suspensions were pipetted into cotton-plugged or plastic-capped glass tubes (13 × 100 mm). After rapid noncontrolled freezing in the nitrogen gas phase, the tubes were stored horizontally either in test-tube racks or in bulk containers.Frozen suspensions of vegetative cells of some algae, many genera of bacteria, as well as spores, vegetative cells, and fragmented mycelia of streptomycetes and fungi have been conveniently prepared from either agar or broth cultures. Sufficient inocula have been prepared to be used for periods of a few weeks to several years.     

Influence of the glass packing on the contamination of pharmaceutical products by aluminium. Part I: salts, glucose, heparin and albumin.

The presence of aluminium (Al) in pharmaceutical products used parenterally as sodium and potassium chlorides, glucose, heparin and albumin were investigated with respect to their storage in glass containers. As glasses can have aluminium in their composition, the aluminium may be released from the glass into the solution. The action of the substances above mentioned were investigated storing their solutions in glass and plastic containers, and measuring the aluminium in solution at determined time intervals. The aluminium present in the commercial pharmaceutical products, stored in both plastic and glass containers were also measured. All glass containers were analysed to determine their aluminium content. The aluminium determinations were done by atomic absorption spectrometry. The resuLts showed that aluminium is present in all analysed glasses in a percentage of 0.6 to 3%. Although all substances already have a residual aluminium contamination, the major contribution comes from the glass containers in which their solutions were stored. The contamination arising from glass depends too much on the nature of the substance. While the salts extracted about 400 microg Al/l in 60 days, glucose extracted 150 microg Al/l, and albumin and heparin about 500 microg Al/l in the same time interval. Commercial solutions of glucose contain about 10 microg Al/l when stored in polyethylene and from 350 to 1,000 microg Al/l when in glass ampules. Considering all commercial products, solutions stored in plastic containers contained no more than 20 microg Al/l whereas in glass the aluminium contamination reached 1,000 microg/l, and in all of them the aluminium increases with the age of the product.     

Photo-oxidation modulates green fern spore longevity during dry storage

Desiccation tolerance and longevity of plant propagules in the dry state have significant implications for biotechnological applications. In this study fern spores were used as a unicellular model to characterize some of the mechanisms of ageing during dry storage of plant propagules (at relative humidity ca. 15%). More specifically, we compared the potential relationships among indicators of photo-oxidative stress and spore viability during dry storage between green (chlorophyllous) spores of Todea barbara and non-green spores of Christella dentata. Green spores stored under the light aged faster than those stored in the dark, and faster than light- and dark-stored non-green spores of C. dentata. This rapid ageing in light-stored green spores was associated with significantly lower antioxidant activity (relative to time zero and dark-stored spores) during storage, and a burst of hydrogen peroxide during the latter stages of storage, which was not a feature of dark-stored spores. We attribute these signs of enhanced oxidative-stress mediated ageing in light-stored spores to photo-oxidative processes, similar to those described in other homoiochlorophyllous organisms. Additionally, high antioxidant activity and low levels of reactive oxygen species in green spores compared with non-green spores suggests differing mechanisms of coping with life in the dry state.     

Composite Sampling Approaches for Bacillus anthracis Surrogate Extracted from Soil

Any release of anthrax spores in the U.S. would require action to decontaminate the site and restore its use and operations as rapidly as possible. The remediation activity would require environmental sampling, both initially to determine the extent of contamination (hazard mapping) and post-decon to determine that the site is free of contamination (clearance sampling). Whether the spore contamination is within a building or outdoors, collecting and analyzing what could be thousands of samples can become the factor that limits the pace of restoring operations. To address this sampling and analysis bottleneck and decrease the time needed to recover from an anthrax contamination event, this study investigates the use of composite sampling. Pooling or compositing of samples is an established technique to reduce the number of analyses required, and its use for anthrax spore sampling has recently been investigated. However, use of composite sampling in an anthrax spore remediation event will require well-documented and accepted methods. In particular, previous composite sampling studies have focused on sampling from hard surfaces; data on soil sampling are required to extend the procedure to outdoor use. Further, we must consider whether combining liquid samples, thus increasing the volume, lowers the sensitivity of detection and produces false negatives. In this study, methods to composite bacterial spore samples from soil are demonstrated. B. subtilis spore suspensions were used as a surrogate for anthrax spores. Two soils (Arizona Test Dust and sterilized potting soil) were contaminated and spore recovery with composites was shown to match individual sample performance. Results show that dilution can be overcome by concentrating bacterial spores using standard filtration methods. This study shows that composite sampling can be a viable method of pooling samples to reduce the number of analysis that must be performed during anthrax spore remediation.