What Factors Affect The Presence of Microorganisms In Cryotanks? - A Culture-Independent Approach To Assess Potential Microbial Colonization of Liquid Nitrogen Storage Tanks

AbstractThe availability of bioresources is a precondition for life science research, medical applications, and diagnostics, but requires a dedicated quality management to guarantee reliable and safe storage. Anecdotal reports of bacterial isolates and sample contamination indicate that organisms may persist in liquid nitrogen (LN) storage tanks. To evaluate the safety status of cryocollections, we systematically screened organisms in the LN phase and in ice layers covering inner surfaces of storage tanks maintained in different biobanking facilities. We applied a culture-independent approach combining cell detection by epifluorescence microscopy with the amplification of group-specific marker genes and high-throughput sequencing of bacterial ribosomal genes. In the LN phase, neither cells nor bacterial 16S rRNA gene copy numbers were detectable (detection limit, 102 cells per ml, 103 gene copies per ml). In several cases, small numbers of bacteria of up to 104 cells per ml and up to 106 gene copies per ml, as well as Mycoplasma, or fungi were detected in the ice phase formed underneath the lids or accumulated at the bottom. The bacteria most likely originated from the stored materials themselves (Elizabethingia, Janthibacterium), the technical environment (Pseudomonas, Acinetobacter, Methylobacterium), or the human microbiome (Bacteroides, Streptococcus, Staphylococcus). In single cases, bacteria, Mycoplasma, fungi, and human cells were detected in the debris at the bottom of the storage tanks. In conclusion, the limited microbial load of the ice phase and in the debris of storage tanks can be effectively avoided by minimizing ice formation and by employing hermetically sealed sample containers.

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Liquid nitrogen storage of yeast cultures. II. Stability of characteristics of stored strains

Antonie van Leeuwenhoek ◽

10.1007/bf00399850 ◽

1983 ◽

Vol 49 (6) ◽

pp. 571-578 ◽

Cited By ~ 6

Author(s):

Anna Kockov�-Kratochv�lov� ◽

Z. Hub�lek

Keyword(s):

Liquid Nitrogen ◽

Nitrogen Storage ◽

Yeast Cultures

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Liquid Nitrogen Storage of Fungi Sealed In A Polyester Film

Mycologia ◽

10.1080/00275514.1968.12018607 ◽

1968 ◽

Vol 60 (3) ◽

pp. 591-954 ◽

Cited By ~ 1

Author(s):

John Tuite

Keyword(s):

Liquid Nitrogen ◽

Nitrogen Storage ◽

Polyester Film

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Experimental and Numerical Investigation of Stratification and Self pressurization in a High Pressure Liquid Nitrogen Storage Tank

Energy Sources Part A Recovery Utilization and Environmental Effects ◽

10.1080/15567036.2019.1651424 ◽

2019 ◽

pp. 1-15

Author(s):

Vishnu S B ◽

Soumyajit Bhowmick ◽

Biju T. Kuzhiveli

Keyword(s):

High Pressure ◽

Numerical Investigation ◽

Liquid Nitrogen ◽

Storage Tank ◽

Nitrogen Storage

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A Study on the Weld Part Fracture Toughness of Austenite Type Stainless Steel for Cryogenic Liquid Nitrogen Storage Tank

Journal of the Korean Society of Marine Engineering ◽

10.5916/jkosme.2011.35.6.802 ◽

2011 ◽

Vol 35 (6) ◽

pp. 802-808

Author(s):

Young-Deuk Kim ◽

Dong-Jun Choi ◽

Hyung-Wook Park ◽

Jong-Rae Cho ◽

Won-Byoung Bae

Keyword(s):

Fracture Toughness ◽

Stainless Steel ◽

Liquid Nitrogen ◽

Storage Tank ◽

Cryogenic Liquid ◽

Nitrogen Storage ◽

Type Stainless Steel

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The Impact of Freezing Temperature and Pretreatment Protocol on Solid Phase HR-MAS-MRS Metabolomes of Colorectal Cancer Tissue

10.21203/rs.3.rs-753667/v1 ◽

2021 ◽

Author(s):

Hui Liu ◽

Yu Wang ◽

Yue-qiang Han ◽

Guang-yu Yang ◽

Lu Wang ◽

...

Keyword(s):

Colorectal Cancer ◽

Liquid Nitrogen ◽

Solid Phase ◽

Phospholipid Metabolism ◽

The Other ◽

Cancer Tissue ◽

Nitrogen Storage ◽

Tissue Samples ◽

Colorectal Cancer Tissue ◽

Choline Phospholipid

Abstract Background: To explore the best pretreatment method of colorectal cancer tissue samples for metabolomics research based on solid-phase nuclear magnetic resonance. Method: Taking mucosal tissues of colorectal cancer and divide it into 5 groups of 0.2cm*0.2cm*0.2cm. Pretreatment was performed as follows: I. Liquid nitrogen storage; II. Transfer to the -80℃ refrigerator after storing in liquid nitrogen for 10 minutes; III. Transfer to the -80℃ refrigerator after storing in liquid nitrogen for 20 minutes; IV. Transfer to the -80℃ refrigerator after storing in liquid nitrogen for 30 minutes; V. -80℃ refrigerator storage. The interval between tumor sample separation to pretreatment is less than 30 minutes. The tissue sample testing process is carried out on Bruker AVII-600 Spectrometer equipped with a high-resolution probe having a 1H/13C magical angle rotation. The tissue samples were put into the NMR which run at a speed of 5000Hz for 10 minutes. NMR signals were collected and analyzed by Fourier transform, partial least squares discrimination analysis (PLS-DA). Corresponding metabolites and metabolic pathways were found in Human Metabolome Database (HMDB) according to the ppms with variable importance of projection (VIP) ＞1. Results: The content of pelargonic acid, stearic acid, D-Ribose, heptadecanoic acid, pyruvic acid, succinate, sarcosine, glycine, creatine, and L-lactate in liquid nitrogen storage group were significantly lower than the other groups (P<0.05), the content of glycerophosphocholine in liquid nitrogen storage group was lower than the other groups (P=0.055). Pyruvic, succinate and L-lactate are participating in glucose metabolism. Glycerophosphocholine, sarcosine, glycine and creatine are participating in choline phospholipid metabolism. This indicated that the glucose and choline phospholipid metabolism levels of the liquid nitrogen group were significantly lower than those of the other 4 groups. Conclusion: Liquid nitrogen storage can slow down the glucose and choline phospholipid metabolism process of colorectal cancer tissue samples in vitro; liquid nitrogen can preserve tissue sample’s metabolic state in the body. It is therefore the better way to store tissue sample than the other methods. clinical trial registry website: http://www.chictr.org.cn/index.aspx. Trial number: ChiCTR1900024640

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Microbial occurrence in liquid nitrogen storage tanks: a challenge for cryobanking?

Applied Microbiology and Biotechnology ◽

10.1007/s00253-021-11531-4 ◽

2021 ◽

Author(s):

Felizitas Bajerski ◽

Manuela Nagel ◽

Joerg Overmann

Keyword(s):

Risk Assessment ◽

Quality Management ◽

Liquid Nitrogen ◽

Potential Risk ◽

Biological Materials ◽

Cross Contamination ◽

Storage Tanks ◽

Long Term Storage ◽

Term Storage

Abstract Modern biobanks maintain valuable living materials for medical diagnostics, reproduction medicine, and conservation purposes. To guarantee high quality during long-term storage and to avoid metabolic activities, cryostorage is often conducted in the N2 vapour phase or in liquid nitrogen (LN) at temperatures below − 150 °C. One potential risk of cryostorage is microbial cross contamination in the LN storage tanks. The current review summarises data on the occurrence of microorganisms that may compromise the safety and quality of biological materials during long-term storage. We assess the potential for the microbial contamination of LN in storage tanks holding different biological materials based on the detection by culture-based and molecular approaches. The samples themselves, the LN, the human microbiome, and the surrounding environment are possible routes of contamination and can cause cross contaminations via the LN phase. In general, the results showed that LN is typically not the source of major contaminations and only a few studies provided evidence for a risk of microbial cross contamination. So far, culture-based and culture-independent techniques detected only low amounts of microbial cells, indicating that cross contamination may occur at a very low frequency. To further minimise the potential risk of microbial cross contaminations, we recommend reducing the formation of ice crystals in cryotanks that can entrap environmental microorganisms and using sealed or second sample packing. A short survey demonstrated the awareness for microbial contaminations of storage containers among different culture collections. Although most participants consider the risk of cross contaminations in LN storage tanks as low, they prevent potential contaminations by using sealed devices and − 150 °C freezers. It is concluded that the overall risk for cross contaminations in biobanks is relatively low when following standard operating procedures (SOPs). We evaluated the potential sources in detail and summarised our results in a risk assessment spreadsheet which can be used for the quality management of biobanks. Key points • Identification of potential contaminants and their sources in LN storage tanks. • Recommendations to reduce this risk of LN storage tank contamination. • Development of a risk assessment spreadsheet to support quality management.

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