Conteneurs de cryoconservation de cellules à base de tubes en acier inoxydable.
Stainless steel tube-based cell cryopreservation containers.
Auteurs : SHIH W. H., YU Z. Y., WU W. T.
Type d'article : Article
Résumé
This study focused on increasing the freezing rate in cell vitrification cryopreservation by using a cryopreservation container possessing rigid mechanical properties and high heat-transfer efficiency. Applying a fast freezing rate in vitrification cryopreservation causes a rapid temperature change in the cryopreservation container and has a substantial impact on mechanical properties; therefore, a highly rigid cryopreservation container that possesses a fast freezing rate must be developed. To produce a highly rigid cryopreservation container possessing superior heat transfer efficiency, this study applies an electrochemical machining (ECM) method to an ANSI 316L stainless steel tube to treat the surface material by polishing and roughening, thereby increasing the freezing rate and reducing the probability of ice crystal formation. The results indicated that the ECM method provided high-quality surface treatment of the stainless steel tube. This method can reduce internal surface roughness in the stainless steel tube, thereby reducing the probability of ice crystal formation, and increase external surface roughness, consequently raising convection heat-transfer efficiency. In addition, by thinning the stainless steel tube, this method reduces heat capacity and thermal resistance, thereby increasing the freezing rate. The freezing rate (3399 ± 197 °C/min) of a stainless steel tube after interior and exterior polishing and exterior etching by applying ECM compared with the freezing rate (1818 ± 54 °C/min) of an original stainless steel tube was increased by 87%, which also exceeds the freezing rate (2015 ± 49 °C/min) of an original quartz tube that has a 20% lower heat capacity. However, the results indicated that increasing heat-transferring surface areas and reducing heat capacities cannot effectively increase the freezing rate of a stainless steel tube if only one method is applied; instead, both techniques must be implemented concurrently to improve the freezing rate
Détails
- Titre original : Stainless steel tube-based cell cryopreservation containers.
- Identifiant de la fiche : 30011372
- Langues : Anglais
- Source : Cryobiology - vol. 67 - n. 3
- Date d'édition : 12/2013
- DOI : http://dx.doi.org/10.1016/j.cryobiol.2013.08.008
Liens
Voir d'autres articles du même numéro (4)
Voir la source
Indexation
-
Heat transfer coefficient of cryotop during fre...
- Auteurs : LI W., ZHOU X., WANG H., et al.
- Date : 05/2013
- Langues : Anglais
- Source : CryoLetters - vol. 34 - n. 3
Voir la fiche
-
A device to record ultra-rapid cooling profiles.
- Auteurs : PAZ L. J. de, GRAF D. A., SCANDIZZI A. L., et al.
- Date : 07/2013
- Langues : Anglais
- Source : CryoLetters - vol. 34 - n. 4
Voir la fiche
-
Comparison of vitrification and slow freezing e...
- Auteurs : PETRUSHKO M. P., PYNYAEV V. I., YURCHUK T. A.
- Date : 08/09/2016
- Langues : Anglais
- Source : 2nd IIR Workshop on cold applications in life sciences.
- Formats : PDF
Voir la fiche
-
CRYOPROTECTION OF RED BLOOD CELLS BY 1,3-BUTANE...
- Auteurs : MEHL P., BOUTRON P.
- Date : 1988
- Langues : Anglais
- Source : Cryobiology - vol. 25 - n. 1
Voir la fiche
-
A preliminary method for ultra-rapid freezing o...
- Auteurs : SCHUMACHER H. M., BITTER E., HEINE-DOBBERNACK E.
- Date : 11/09/2012
- Langues : Anglais
- Source : Cryogenics 2012. Proceedings of the 12th IIR International Conference: Dresden, Germany, September 11-14, 2012.
- Formats : PDF
Voir la fiche