Reassessing the out‐of‐phase phenomenon in shake flasks by evaluating the angle‐dependent liquid distribution relative to the direction of the centrifugal acceleration

Azizan, Amizon; Sieben, Michaela; Wandrey, Georg; Büchs, Jochen

doi:10.1002/bit.27132

Cited by 10 publications

(19 citation statements)

References 20 publications

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“…Due to the high number of genes to be analysed and the heterogeneous character of fungal macromorphological populations in a bioreactor, there is an increased need for the development of parallel multibioreactor systems at the millilitre scale that allow for high-throughput and that generate reproducible cultivation data with low variance. The development and commercialization of several online monitoring tools for shaken flasks (Respiration Activity MOnitoring System, RAMOS) and microtiter plates (µRAMOS, BioLector) are suitable techniques that allow deep insight into the metabolic state of microbial cultivations and are suitable as scaling parameters that can be determined at an early stage of process development with filamentous microorganisms [ 53 – 55 ].…”

Section: Three Areas Ripe For Developmentmentioning

confidence: 99%

Understanding and controlling filamentous growth of fungal cell factories: novel tools and opportunities for targeted morphology engineering

Meyer

Cairns

Barthel

et al. 2021

Fungal Biol Biotechnol

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Filamentous fungal cell factories are efficient producers of platform chemicals, proteins, enzymes and natural products. Stirred-tank bioreactors up to a scale of several hundred m³ are commonly used for their cultivation. Fungal hyphae self-assemble into various cellular macromorphologies ranging from dispersed mycelia, loose clumps, to compact pellets. Development of these macromorphologies is so far unpredictable but strongly impacts productivities of fungal bioprocesses. Depending on the strain and the desired product, the morphological forms vary, but no strain- or product-related correlations currently exist to improve process understanding of fungal production systems. However, novel genomic, genetic, metabolic, imaging and modelling tools have recently been established that will provide fundamental new insights into filamentous fungal growth and how it is balanced with product formation. In this primer, these tools will be highlighted and their revolutionary impact on rational morphology engineering and bioprocess control will be discussed.

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Section: Three Areas Ripe For Developmentmentioning

confidence: 99%

Understanding and controlling filamentous growth of fungal cell factories: novel tools and opportunities for targeted morphology engineering

Meyer

Cairns

Barthel

et al. 2021

Fungal Biol Biotechnol

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“…These are met when the Froude number is below 0.4 and the Phase number, Ph, is below 1.26. The Ph was later adjusted to 0.91 (Azizan et al, 2019 ). It can be calculated via:

…”

Section: Methodsmentioning

confidence: 99%

“…Büchs et al ( 2000 ) established the dimensionless Phase number (Ph), the related Reynolds number ( Re ), and a minimum Froude number (Fr) of 0.4 as engineering characteristics for mixing in shaken flasks. Ph considers the ratio of the shaking diameter and the working volume to the inner diameter of the reactor and gives Ph>0.91 as the characteristic for the “in‐phase” conditions which verifies homogenous flow and optimal mixing (Azizan et al, 2019 ). However, it does not seem to be the only criterion to ensure in‐phase conditions, as Ducci and Weheliye ( 2014 ) considered that the in‐phase conditions are dependent on the positioning of the velocity vector rather than the Ph number.…”

Section: Introductionmentioning

confidence: 99%

Characterization of hydrodynamics and volumetric power input in microtiter plates for the scale‐up of downstream operations

Montes‐Serrano

Satzer

Jungbauer

et al. 2021

Biotech & Bioengineering

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Parameter estimation for scale-up of downstream operations from microtiter plates (MTPs) is mostly done empirically because engineering correlations between microplates and stirred tank reactors (STRs) are not yet available. It is challenging to change the operation mode from shaken MTPs to large-scale STRs. For the scale-up of STRs, volumetric power input is well-established although it is unclear whether this parameter can be used to transfer the operations from MTPs. We determine the volumetric power input in MTPs via the temperature increase caused by the motion of the liquid. The hydrodynamics in MTPs are studied with computational fluid dynamics (CFD). Mixing is investigated in 96-, 24-, and 6-well MTPs to cover different geometries, filling volumes, shaking diameters, and shaking frequencies. All CFD simulations are validated by experimental results, which now allows prediction of the volumetric power input and hydrodynamics at various conditions in MTPs without the need for further experiments. We provide a map of the power input achievable in MTPs. Based on this map, from knowing about large-scale conditions, adequate microscale conditions can be adjusted for process development. This enables the direct scale-up of downstream unit operations from MTPs to STRs.

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“…This even includes pH control and, thus, by reducing buffer concentrations, similar osmotic conditions as commonly used in stirred tank bioreactors can be applied ( Scheidle et al, 2011 ; Philip et al, 2018 ). 4) The extensive characterization with respect to engineering parameters such as power input ( Büchs et al, 2000a ; Büchs et al, 2000b ; Büchs et al, 2001 ; Peter et al, 2006a ; Peter et al, 2006b ), mixing times ( Tan et al, 2011 ), hydrodynamics ( Büchs et al, 2001 ; Peter et al, 2004 ; Büchs et al, 2007 ; Tianzhong et al, 2010 ; Liu et al, 2016 ; Palacios-Morales et al, 2016 ; Azizan and Büchs, 2017 ; Azizan et al, 2019 ), and gas-liquid mass transfer ( Van Suijdam et al, 1978 ; Henzler and Schedel, 1991 ; Maier and Büchs, 2001 ; Maier et al, 2004 ; Giese et al, 2014 ) enables good and reliable experimental designs. 5) Due to surface aeration, complicating phenomena that usually come along with bubble aeration are avoided.…”

Section: Introductionmentioning

confidence: 99%

“…4) The extensive characterization with respect to engineering parameters such as power input ( Büchs et al, 2000a ; Büchs et al, 2000b ; Büchs et al, 2001 ; Peter et al, 2006a ; Peter et al, 2006b ), mixing times ( Tan et al, 2011 ), hydrodynamics ( Büchs et al, 2001 ; Peter et al, 2004 ; Büchs et al, 2007 ; Tianzhong et al, 2010 ; Liu et al, 2016 ; Palacios-Morales et al, 2016 ; Azizan and Büchs, 2017 ; Azizan et al, 2019 ), and gas-liquid mass transfer ( Van Suijdam et al, 1978 ; Henzler and Schedel, 1991 ; Maier and Büchs, 2001 ; Maier et al, 2004 ; Giese et al, 2014 ) enables good and reliable experimental designs.…”

Section: Introductionmentioning

confidence: 99%

Implementation of Perforated Concentric Ring Walls Considerably Improves Gas-Liquid Mass Transfer of Shaken Bioreactors

Hansen

Gumprecht

Micheel

et al. 2022

Front. Bioeng. Biotechnol.

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Since their first use in the 1930s, shake flasks have been a widely used bioreactor type for screening and process development due to a number of advantages. However, the limited gas-liquid mass transfer capacities—resulting from practical operation limits regarding shaking frequency and filling volumes—are a major drawback. The common way to increase the gas-liquid mass transfer in shake flasks with the implementation of baffles is generally not recommended as it comes along with several severe disadvantages. Thus, a new design principle for shaken bioreactors that aims for improving the gas-liquid mass transfer without losing the positive characteristics of unbaffled shake flasks is introduced. The flasks consist of cylindrical glass vessels with implemented perforated concentric ring walls. The ring walls improve the gas-liquid mass transfer via the formation of additional liquid films on both of its sides, whereas the perforations allow for mixing between the compartments. Sulfite oxidation experiments revealed over 200% higher maximum oxygen transfer capacities (OTRmax) compared to conventional shake flasks. In batch cultivations of Escherichia coli BL21 in mineral media, unlimited growth until glucose depletion and oxygen transfer rates (OTR) of up to 138 mmol/L/h instead of an oxygen limitation at 57 mmol/L/h as in normal shake flasks under comparable conditions could be achieved. Even overflow metabolism could be prevented due to sufficient oxygen supply without the use of unconventional shaking conditions or oxygen enrichment. Therefore, we believe that the new perforated ring flask principle has a high potential to considerably improve biotechnological screening and process development steps.

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Reassessing the out‐of‐phase phenomenon in shake flasks by evaluating the angle‐dependent liquid distribution relative to the direction of the centrifugal acceleration

Cited by 10 publications

References 20 publications

Understanding and controlling filamentous growth of fungal cell factories: novel tools and opportunities for targeted morphology engineering

Understanding and controlling filamentous growth of fungal cell factories: novel tools and opportunities for targeted morphology engineering

Characterization of hydrodynamics and volumetric power input in microtiter plates for the scale‐up of downstream operations

Implementation of Perforated Concentric Ring Walls Considerably Improves Gas-Liquid Mass Transfer of Shaken Bioreactors

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