Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique

Background: Biotechnological development in shake flask necessitates vital engineering parameters e.g. volumetric power input, mixing time, gas liquid mass transfer coefficient, hydromechanical stress and effective shear rate. Determination and optimization of these parameters through experiments ar...

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Published in:Journal of Biological Engineering
Main Author: Azizan A.; Büchs J.
Format: Article
Language:English
Published: BioMed Central Ltd. 2017
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026773606&doi=10.1186%2fs13036-017-0070-7&partnerID=40&md5=1f291a3edc72990850be9a0b510dcb2f
id 2-s2.0-85026773606
spelling 2-s2.0-85026773606
Azizan A.; Büchs J.
Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique
2017
Journal of Biological Engineering
11
1
10.1186/s13036-017-0070-7
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026773606&doi=10.1186%2fs13036-017-0070-7&partnerID=40&md5=1f291a3edc72990850be9a0b510dcb2f
Background: Biotechnological development in shake flask necessitates vital engineering parameters e.g. volumetric power input, mixing time, gas liquid mass transfer coefficient, hydromechanical stress and effective shear rate. Determination and optimization of these parameters through experiments are labor-intensive and time-consuming. Computational Fluid Dynamics (CFD) provides the ability to predict and validate these parameters in bioprocess engineering. This work provides ample experimental data which are easily accessible for future validations to represent the hydrodynamics of the fluid flow in the shake flask. Results: A non-invasive measuring technique using an optical fluorescence method was developed for shake flasks containing a fluorescent solution with a waterlike viscosity at varying filling volume (VL = 15 to 40 mL) and shaking frequency (n = 150 to 450 rpm) at a constant shaking diameter (do = 25 mm). The method detected the leading edge (LB) and tail of the rotating bulk liquid (TB) relative to the direction of the centrifugal acceleration at varying circumferential heights from the base of the shake flask. The determined LB and TB points were translated into three-dimensional (3D) circumferential liquid distribution plots. The maximum liquid height (Hmax) of the bulk liquid increased with increasing filling volume and shaking frequency of the shaking flask, as expected. The toroidal shapes of LB and TB are clearly asymmetrical and the measured TB differed by the elongation of the liquid particularly towards the torus part of the shake flask. Conclusion: The 3D liquid distribution data collected at varying filling volume and shaking frequency, comprising of LB and TB values relative to the direction of the centrifugal acceleration are essential for validating future numerical solutions using CFD to predict vital engineering parameters in shake flask. © 2017 The Author(s).
BioMed Central Ltd.
17541611
English
Article
All Open Access; Gold Open Access
author Azizan A.; Büchs J.
spellingShingle Azizan A.; Büchs J.
Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique
author_facet Azizan A.; Büchs J.
author_sort Azizan A.; Büchs J.
title Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique
title_short Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique
title_full Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique
title_fullStr Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique
title_full_unstemmed Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique
title_sort Three-dimensional (3D) evaluation of liquid distribution in shake flask using an optical fluorescence technique
publishDate 2017
container_title Journal of Biological Engineering
container_volume 11
container_issue 1
doi_str_mv 10.1186/s13036-017-0070-7
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026773606&doi=10.1186%2fs13036-017-0070-7&partnerID=40&md5=1f291a3edc72990850be9a0b510dcb2f
description Background: Biotechnological development in shake flask necessitates vital engineering parameters e.g. volumetric power input, mixing time, gas liquid mass transfer coefficient, hydromechanical stress and effective shear rate. Determination and optimization of these parameters through experiments are labor-intensive and time-consuming. Computational Fluid Dynamics (CFD) provides the ability to predict and validate these parameters in bioprocess engineering. This work provides ample experimental data which are easily accessible for future validations to represent the hydrodynamics of the fluid flow in the shake flask. Results: A non-invasive measuring technique using an optical fluorescence method was developed for shake flasks containing a fluorescent solution with a waterlike viscosity at varying filling volume (VL = 15 to 40 mL) and shaking frequency (n = 150 to 450 rpm) at a constant shaking diameter (do = 25 mm). The method detected the leading edge (LB) and tail of the rotating bulk liquid (TB) relative to the direction of the centrifugal acceleration at varying circumferential heights from the base of the shake flask. The determined LB and TB points were translated into three-dimensional (3D) circumferential liquid distribution plots. The maximum liquid height (Hmax) of the bulk liquid increased with increasing filling volume and shaking frequency of the shaking flask, as expected. The toroidal shapes of LB and TB are clearly asymmetrical and the measured TB differed by the elongation of the liquid particularly towards the torus part of the shake flask. Conclusion: The 3D liquid distribution data collected at varying filling volume and shaking frequency, comprising of LB and TB values relative to the direction of the centrifugal acceleration are essential for validating future numerical solutions using CFD to predict vital engineering parameters in shake flask. © 2017 The Author(s).
publisher BioMed Central Ltd.
issn 17541611
language English
format Article
accesstype All Open Access; Gold Open Access
record_format scopus
collection Scopus
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