Lipoaspirate Storage Time and Temperature: Effects on Stromal Vascular Fraction Quality and Cell Composition

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Lipoaspirate Storage Time and Temperature : Effects on Stromal Vascular Fraction Quality and Cell Composition. / Svalgaard, Jesper Dyrendom; Juul, Sarah; Vester-Glovinski, Peter Viktor; Haastrup, Eva Kannik; Ballesteros, Olga Rivera; Lynggaard, Charlotte Duch; Jensen, Andreas Kryger; Fischer-Nielsen, Anne; Herly, Mikkel; Munthe-Fog, Lea.

In: Cells, Tissues, Organs, Vol. 209, 2020, p. 54-63.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Svalgaard, JD, Juul, S, Vester-Glovinski, PV, Haastrup, EK, Ballesteros, OR, Lynggaard, CD, Jensen, AK, Fischer-Nielsen, A, Herly, M & Munthe-Fog, L 2020, 'Lipoaspirate Storage Time and Temperature: Effects on Stromal Vascular Fraction Quality and Cell Composition', Cells, Tissues, Organs, vol. 209, pp. 54-63. https://doi.org/10.1159/000507825

APA

Svalgaard, J. D., Juul, S., Vester-Glovinski, P. V., Haastrup, E. K., Ballesteros, O. R., Lynggaard, C. D., Jensen, A. K., Fischer-Nielsen, A., Herly, M., & Munthe-Fog, L. (2020). Lipoaspirate Storage Time and Temperature: Effects on Stromal Vascular Fraction Quality and Cell Composition. Cells, Tissues, Organs, 209, 54-63. https://doi.org/10.1159/000507825

Vancouver

Svalgaard JD, Juul S, Vester-Glovinski PV, Haastrup EK, Ballesteros OR, Lynggaard CD et al. Lipoaspirate Storage Time and Temperature: Effects on Stromal Vascular Fraction Quality and Cell Composition. Cells, Tissues, Organs. 2020;209:54-63. https://doi.org/10.1159/000507825

Author

Svalgaard, Jesper Dyrendom ; Juul, Sarah ; Vester-Glovinski, Peter Viktor ; Haastrup, Eva Kannik ; Ballesteros, Olga Rivera ; Lynggaard, Charlotte Duch ; Jensen, Andreas Kryger ; Fischer-Nielsen, Anne ; Herly, Mikkel ; Munthe-Fog, Lea. / Lipoaspirate Storage Time and Temperature : Effects on Stromal Vascular Fraction Quality and Cell Composition. In: Cells, Tissues, Organs. 2020 ; Vol. 209. pp. 54-63.

Bibtex

@article{f741808294db49969c46242efb5a439e,
title = "Lipoaspirate Storage Time and Temperature: Effects on Stromal Vascular Fraction Quality and Cell Composition",
abstract = "The adipose tissue-derived stromal vascular fraction (SVF) is a promising candidate for use in cell therapy and tissue engineering due to its regenerative and immunomodulatory properties. Some therapies are based on using the complete SVF product, whereas others depend on the expansion of adipose-derived stromal cells (ASCs) in culture. The latter application often involves a time delay between adipose tissue harvest and SVF isolation. This study investigated how storage time and temperature affected cell quality and composition. Aliquots of lipoaspirate were stored cold (4°C), at room temperature (18-20°C), or at 37°C. SVF was isolated on sequential time points over a period of 48 h, and the following were assessed: Cell viability, vitality, composition, and the proliferative potential of the ASCs. When the lipoaspirate was stored cold, the viability of the SVF remained stable for up to 48 h; however, the vitality of the SVF decreased significantly after 24 h. When stored at higher temperatures (room temperature or 37°C), the vitality of the SVF decreased after 8 h. The ASC fraction in the SVF decreased rapidly after 8 h when stored at higher temperatures, whereas this change was delayed significantly when the lipoaspirate was stored cold. Tendencies towards increases in the lag phase, population doubling time (PDt), and time to reach confluency were observed when the lipoaspirate was stored at higher temperatures. The vitality of the SVF was correlated significantly with the time of the lag phase and the time required to reach confluence, whereas no correlation was observed with the PDt. Both prolonged storage time and increased temperature during lipoaspirate storage negatively affected the quality of the obtained SVF. Our results suggest that lipoaspirate should be stored for no longer than 24 h at 4°C to maintain the optimal quality for the isolation of SVF and the expansion of ASCs.",
keywords = "Adipose-derived stromal cells, Colony-forming unit fibroblast, Endothelial cells, Endothelial progenitor cells, Nucleated cells, Stromal vascular fraction",
author = "Svalgaard, {Jesper Dyrendom} and Sarah Juul and Vester-Glovinski, {Peter Viktor} and Haastrup, {Eva Kannik} and Ballesteros, {Olga Rivera} and Lynggaard, {Charlotte Duch} and Jensen, {Andreas Kryger} and Anne Fischer-Nielsen and Mikkel Herly and Lea Munthe-Fog",
year = "2020",
doi = "10.1159/000507825",
language = "Dansk",
volume = "209",
pages = "54--63",
journal = "Cells Tissues Organs",
issn = "1422-6405",
publisher = "S Karger AG",

}

RIS

TY - JOUR

T1 - Lipoaspirate Storage Time and Temperature

T2 - Effects on Stromal Vascular Fraction Quality and Cell Composition

AU - Svalgaard, Jesper Dyrendom

AU - Juul, Sarah

AU - Vester-Glovinski, Peter Viktor

AU - Haastrup, Eva Kannik

AU - Ballesteros, Olga Rivera

AU - Lynggaard, Charlotte Duch

AU - Jensen, Andreas Kryger

AU - Fischer-Nielsen, Anne

AU - Herly, Mikkel

AU - Munthe-Fog, Lea

PY - 2020

Y1 - 2020

N2 - The adipose tissue-derived stromal vascular fraction (SVF) is a promising candidate for use in cell therapy and tissue engineering due to its regenerative and immunomodulatory properties. Some therapies are based on using the complete SVF product, whereas others depend on the expansion of adipose-derived stromal cells (ASCs) in culture. The latter application often involves a time delay between adipose tissue harvest and SVF isolation. This study investigated how storage time and temperature affected cell quality and composition. Aliquots of lipoaspirate were stored cold (4°C), at room temperature (18-20°C), or at 37°C. SVF was isolated on sequential time points over a period of 48 h, and the following were assessed: Cell viability, vitality, composition, and the proliferative potential of the ASCs. When the lipoaspirate was stored cold, the viability of the SVF remained stable for up to 48 h; however, the vitality of the SVF decreased significantly after 24 h. When stored at higher temperatures (room temperature or 37°C), the vitality of the SVF decreased after 8 h. The ASC fraction in the SVF decreased rapidly after 8 h when stored at higher temperatures, whereas this change was delayed significantly when the lipoaspirate was stored cold. Tendencies towards increases in the lag phase, population doubling time (PDt), and time to reach confluency were observed when the lipoaspirate was stored at higher temperatures. The vitality of the SVF was correlated significantly with the time of the lag phase and the time required to reach confluence, whereas no correlation was observed with the PDt. Both prolonged storage time and increased temperature during lipoaspirate storage negatively affected the quality of the obtained SVF. Our results suggest that lipoaspirate should be stored for no longer than 24 h at 4°C to maintain the optimal quality for the isolation of SVF and the expansion of ASCs.

AB - The adipose tissue-derived stromal vascular fraction (SVF) is a promising candidate for use in cell therapy and tissue engineering due to its regenerative and immunomodulatory properties. Some therapies are based on using the complete SVF product, whereas others depend on the expansion of adipose-derived stromal cells (ASCs) in culture. The latter application often involves a time delay between adipose tissue harvest and SVF isolation. This study investigated how storage time and temperature affected cell quality and composition. Aliquots of lipoaspirate were stored cold (4°C), at room temperature (18-20°C), or at 37°C. SVF was isolated on sequential time points over a period of 48 h, and the following were assessed: Cell viability, vitality, composition, and the proliferative potential of the ASCs. When the lipoaspirate was stored cold, the viability of the SVF remained stable for up to 48 h; however, the vitality of the SVF decreased significantly after 24 h. When stored at higher temperatures (room temperature or 37°C), the vitality of the SVF decreased after 8 h. The ASC fraction in the SVF decreased rapidly after 8 h when stored at higher temperatures, whereas this change was delayed significantly when the lipoaspirate was stored cold. Tendencies towards increases in the lag phase, population doubling time (PDt), and time to reach confluency were observed when the lipoaspirate was stored at higher temperatures. The vitality of the SVF was correlated significantly with the time of the lag phase and the time required to reach confluence, whereas no correlation was observed with the PDt. Both prolonged storage time and increased temperature during lipoaspirate storage negatively affected the quality of the obtained SVF. Our results suggest that lipoaspirate should be stored for no longer than 24 h at 4°C to maintain the optimal quality for the isolation of SVF and the expansion of ASCs.

KW - Adipose-derived stromal cells

KW - Colony-forming unit fibroblast

KW - Endothelial cells

KW - Endothelial progenitor cells

KW - Nucleated cells

KW - Stromal vascular fraction

U2 - 10.1159/000507825

DO - 10.1159/000507825

M3 - Tidsskriftartikel

C2 - 32580198

VL - 209

SP - 54

EP - 63

JO - Cells Tissues Organs

JF - Cells Tissues Organs

SN - 1422-6405

ER -

ID: 248695678