Cryopreservation: An Overview of Principles and Cell-Specific Considerations

The origins of low-temperature tissue storage research date back to the late 1800s. Over half a century later, osmotic stress was revealed to be a main contributor to cell death during cryopreservation. Consequently, the addition of cryoprotective agents (CPAs) such as dimethyl sulfoxide (DMSO), gly...

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Published inCell transplantation Vol. 30; p. 963689721999617
Main Authors Whaley, David, Damyar, Kimia, Witek, Rafal P., Mendoza, Alan, Alexander, Michael, Lakey, Jonathan RT
Format Journal Article
LanguageEnglish
Published Los Angeles, CA SAGE Publications 2021
Sage Publications Ltd
SAGE Publishing
Subjects
Alginic acid
Apoptosis
Cell death
Cell survival
Cryopreservation
Dimethyl sulfoxide
Embryo cells
Ethylene glycol
Glycerol
Hematopoietic stem cells
Hepatocytes
Low temperature
Mesenchyme
Oocytes
Osmotic stress
Oxidants
Pancreas
Propylene glycol
Review (Unsolicited)
Stem cells
Thawing
low temperature banking
cryoprotectants
freezing
cryopreservation
Online AccessGet full text

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Abstract The origins of low-temperature tissue storage research date back to the late 1800s. Over half a century later, osmotic stress was revealed to be a main contributor to cell death during cryopreservation. Consequently, the addition of cryoprotective agents (CPAs) such as dimethyl sulfoxide (DMSO), glycerol (GLY), ethylene glycol (EG), or propylene glycol (PG), although toxic to cells at high concentrations, was identified as a necessary step to protect against rampant cell death during cryopreservation. In addition to osmotic stress, cooling and thawing rates were also shown to have significant influence on cell survival during low temperature storage. In general, successful low-temperature cell preservation consists of the addition of a CPA (commonly 10% DMSO), alone or in combination with additional permeating or non-permeating agents, cooling rates of approximately 1ºC/min, and storage in either liquid or vapor phase nitrogen. In addition to general considerations, cell-specific recommendations for hepatocytes, pancreatic islets, sperm, oocytes, and stem cells should be observed to maximize yields. For example, rapid cooling is associated with better cryopreservation outcomes for oocytes, pancreatic islets, and embryonic stem cells while slow cooling is recommended for cryopreservation of hepatocytes, hematopoietic stem cells, and mesenchymal stem cells. Yields can be further maximized by implementing additional pre-cryo steps such as: pre-incubation with glucose and anti-oxidants, alginate encapsulation, and selecting cells within an optimal age range and functional ability. Finally, viability and functional assays are critical steps in determining the quality of the cells post-thaw and improving the efficiency of the current cryopreservation methods.
AbstractList The origins of low-temperature tissue storage research date back to the late 1800s. Over half a century later, osmotic stress was revealed to be a main contributor to cell death during cryopreservation. Consequently, the addition of cryoprotective agents (CPAs) such as dimethyl sulfoxide (DMSO), glycerol (GLY), ethylene glycol (EG), or propylene glycol (PG), although toxic to cells at high concentrations, was identified as a necessary step to protect against rampant cell death during cryopreservation. In addition to osmotic stress, cooling and thawing rates were also shown to have significant influence on cell survival during low temperature storage. In general, successful low-temperature cell preservation consists of the addition of a CPA (commonly 10% DMSO), alone or in combination with additional permeating or non-permeating agents, cooling rates of approximately 1ºC/min, and storage in either liquid or vapor phase nitrogen. In addition to general considerations, cell-specific recommendations for hepatocytes, pancreatic islets, sperm, oocytes, and stem cells should be observed to maximize yields. For example, rapid cooling is associated with better cryopreservation outcomes for oocytes, pancreatic islets, and embryonic stem cells while slow cooling is recommended for cryopreservation of hepatocytes, hematopoietic stem cells, and mesenchymal stem cells. Yields can be further maximized by implementing additional pre-cryo steps such as: pre-incubation with glucose and anti-oxidants, alginate encapsulation, and selecting cells within an optimal age range and functional ability. Finally, viability and functional assays are critical steps in determining the quality of the cells post-thaw and improving the efficiency of the current cryopreservation methods.
The origins of low-temperature tissue storage research date back to the late 1800s. Over half a century later, osmotic stress was revealed to be a main contributor to cell death during cryopreservation. Consequently, the addition of cryoprotective agents (CPAs) such as dimethyl sulfoxide (DMSO), glycerol (GLY), ethylene glycol (EG), or propylene glycol (PG), although toxic to cells at high concentrations, was identified as a necessary step to protect against rampant cell death during cryopreservation. In addition to osmotic stress, cooling and thawing rates were also shown to have significant influence on cell survival during low temperature storage. In general, successful low-temperature cell preservation consists of the addition of a CPA (commonly 10% DMSO), alone or in combination with additional permeating or non-permeating agents, cooling rates of approximately 1ºC/min, and storage in either liquid or vapor phase nitrogen. In addition to general considerations, cell-specific recommendations for hepatocytes, pancreatic islets, sperm, oocytes, and stem cells should be observed to maximize yields. For example, rapid cooling is associated with better cryopreservation outcomes for oocytes, pancreatic islets, and embryonic stem cells while slow cooling is recommended for cryopreservation of hepatocytes, hematopoietic stem cells, and mesenchymal stem cells. Yields can be further maximized by implementing additional pre-cryo steps such as: pre-incubation with glucose and anti-oxidants, alginate encapsulation, and selecting cells within an optimal age range and functional ability. Finally, viability and functional assays are critical steps in determining the quality of the cells post-thaw and improving the efficiency of the current cryopreservation methods.The origins of low-temperature tissue storage research date back to the late 1800s. Over half a century later, osmotic stress was revealed to be a main contributor to cell death during cryopreservation. Consequently, the addition of cryoprotective agents (CPAs) such as dimethyl sulfoxide (DMSO), glycerol (GLY), ethylene glycol (EG), or propylene glycol (PG), although toxic to cells at high concentrations, was identified as a necessary step to protect against rampant cell death during cryopreservation. In addition to osmotic stress, cooling and thawing rates were also shown to have significant influence on cell survival during low temperature storage. In general, successful low-temperature cell preservation consists of the addition of a CPA (commonly 10% DMSO), alone or in combination with additional permeating or non-permeating agents, cooling rates of approximately 1ºC/min, and storage in either liquid or vapor phase nitrogen. In addition to general considerations, cell-specific recommendations for hepatocytes, pancreatic islets, sperm, oocytes, and stem cells should be observed to maximize yields. For example, rapid cooling is associated with better cryopreservation outcomes for oocytes, pancreatic islets, and embryonic stem cells while slow cooling is recommended for cryopreservation of hepatocytes, hematopoietic stem cells, and mesenchymal stem cells. Yields can be further maximized by implementing additional pre-cryo steps such as: pre-incubation with glucose and anti-oxidants, alginate encapsulation, and selecting cells within an optimal age range and functional ability. Finally, viability and functional assays are critical steps in determining the quality of the cells post-thaw and improving the efficiency of the current cryopreservation methods.
Author Alexander, Michael
Whaley, David
Witek, Rafal P.
Damyar, Kimia
Mendoza, Alan
Lakey, Jonathan RT
AuthorAffiliation 3 Department of Biomedical Engineering, 8788 University of California Irvine , Irvine, CA, USA
2 Ambys Medicines, South San Francisco, CA, USA
1 Department of Surgery, 8788 University of California Irvine , Orange, CA, USA
AuthorAffiliation_xml – name: 2 Ambys Medicines, South San Francisco, CA, USA
– name: 3 Department of Biomedical Engineering, 8788 University of California Irvine , Irvine, CA, USA
– name: 1 Department of Surgery, 8788 University of California Irvine , Orange, CA, USA
Author_xml – sequence: 1
  givenname: David
  surname: Whaley
  fullname: Whaley, David
– sequence: 2
  givenname: Kimia
  surname: Damyar
  fullname: Damyar, Kimia
– sequence: 3
  givenname: Rafal P.
  surname: Witek
  fullname: Witek, Rafal P.
– sequence: 4
  givenname: Alan
  surname: Mendoza
  fullname: Mendoza, Alan
– sequence: 5
  givenname: Michael
  surname: Alexander
  fullname: Alexander, Michael
– sequence: 6
  givenname: Jonathan RT
  orcidid: 0000-0001-8553-4287
  surname: Lakey
  fullname: Lakey, Jonathan RT
  email: jlakey@hs.uci.edu
BackLink https://www.ncbi.nlm.nih.gov/pubmed/33757335$$D View this record in MEDLINE/PubMed
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Keywords low temperature banking
cryoprotectants
freezing
cryopreservation
Language English
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Snippet The origins of low-temperature tissue storage research date back to the late 1800s. Over half a century later, osmotic stress was revealed to be a main...
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SubjectTerms Alginic acid
Apoptosis
Cell death
Cell survival
Cryopreservation
Dimethyl sulfoxide
Embryo cells
Ethylene glycol
Glycerol
Hematopoietic stem cells
Hepatocytes
Low temperature
Mesenchyme
Oocytes
Osmotic stress
Oxidants
Pancreas
Propylene glycol
Review (Unsolicited)
Stem cells
Thawing
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Title Cryopreservation: An Overview of Principles and Cell-Specific Considerations
URI https://journals.sagepub.com/doi/full/10.1177/0963689721999617
https://www.ncbi.nlm.nih.gov/pubmed/33757335
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https://www.proquest.com/docview/2504777096
https://pubmed.ncbi.nlm.nih.gov/PMC7995302
https://doaj.org/article/c7d17f41cf704e939996af70ceccfa93
Volume 30
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