The Impact of Fluid Dynamic Stress in Stirred Bioreactors – The Scale of the Biological Entity: A Personal View

Nienow, Alvin W.

doi:10.1002/cite.202000176

Cited by 30 publications

(25 citation statements)

References 64 publications

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“…We have discussed this in detail previously (Nienow et al 2014 ) and though rapid increases in the impact stresses with increasing speed have proved to be an effective way of detaching cells from microcarriers in the presence of detachment enzymes during harvest, there is no evidence to suggest that damage occurs either during that process or culture at N JS . On the other hand, it has also been found that the impact of fluid dynamic stress from turbulence can be effectively considered in relation to the size of the Kolmogorov scale in relation to the size of the biological entity (Nienow 2020 ). Typically, in brief, if the size of the biological entity is less than the Kolmogorov scale, λ K , the cell will not be damaged in stirred bioreactors.…”

Section: Resultsmentioning

confidence: 99%

Design and development of a new ambr250® bioreactor vessel for improved cell and gene therapy applications

et al. 2021

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The emergence of cell and gene therapies has generated significant interest in their clinical and commercial potential. However, these therapies are prohibitively expensive to manufacture and can require extensive time for development due to our limited process knowledge and understanding. The automated ambr250® stirred-tank bioreactor platform provides an effective platform for high-throughput process development. However, the original dual pitched-blade 20 mm impeller and baffles proved sub-optimal for cell therapy candidates that require suspension of microcarriers (e.g. for the culture of adherent human mesenchymal stem cells) or other particles such as activating Dynabeads® (e.g. for the culture of human T-cells). We demonstrate the development of a new ambr250® stirred-tank bioreactor vessel which has been designed specifically to improve the suspension of microcarriers/beads and thereby improve the culture of such cellular systems. The new design is unbaffled and has a single, larger elephant ear impeller. We undertook a range of engineering and physical characterizations to determine which vessel and impeller configuration would be most suitable for suspension based on the minimum agitation speed (NJS) and associated specific power input (P/V)JS. A vessel (diameter, T, = 60 mm) without baffles and incorporating a single elephant ear impeller (diameter 30 mm and 45° pitch-blade angle) was selected as it had the lowest (P/V)JS and therefore potentially, based on Kolmogorov concepts, was the most flexible system. These experimentally-based conclusions were further validated firstly with computational fluid dynamic (CFD) simulations and secondly experimental studies involving the culture of both T-cells with Dynabeads® and hMSCs on microcarriers. The new ambr250® stirred-tank bioreactor successfully supported the culture of both cell types, with the T-cell culture demonstrating significant improvements compared to the original ambr250® and the hMSC-microcarrier culture gave significantly higher yields compared with spinner flask cultures. The new ambr250® bioreactor vessel design is an effective process development tool for cell and gene therapy candidates and potentially for autologous manufacture too.

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Section: Resultsmentioning

confidence: 99%

Design and development of a new ambr250® bioreactor vessel for improved cell and gene therapy applications

et al. 2021

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“…The reduction of agitation speed while scaling up fermenters is mainly practised to maintain sufficient shear stress between the impeller blades and vessel wall (Junker 2004 ). As a result, uniform mixing is achieved with minimum microbial cell damage (Nienow 2021 ). The industrial scale fermenter was found to have a lower specific energy or P/V w value than lab and pilot scale fermenters (Table 3 ) and observed to be lower than the range of values (2–10 kWm −3 ) suggested by Meyer et al ( 2017 ) for pilot scale fermentations.…”

Section: Resultsmentioning

confidence: 99%

“…Usually, the greater torque was associated with greater energy consumption, which increased with an increase in agitation speed, but it is interesting to note that RTB was calculated to have 1.9 times greater torque output than LA315 at similar specific energy consumption (~2.8 or 4.31 kW m −3 at Z = 6 or 9.29 m) and lower agitation rate (1.33 s −1 ). Moreover, Nienow ( 2021 ) indicated that microbial cells may remain unaffected by the hydrodynamic stress if the cell size is smaller than Kolmogoroff microscale of turbulence ( λ k ), which was calculated using Eq. 6 and 7 .…”

Section: Resultsmentioning

confidence: 99%

Upscale fermenter design for lactic acid production from cheese whey permeate focusing on impeller selection and energy optimization

et al. 2021

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This study focusses on the design and scale-up of industrial lactic acid production by fermentation of dairy cheese whey permeate based on standard methodological parameters. The aim was to address the shortcomings of standard scale-up methodologies and provide a framework for fermenter scale-up that enables the accurate estimation of energy consumption by suitable selection of turbine and speed for industrial deployment. Moreover, life cycle assessment (LCA) was carried out to identify the potential impacts and possibilities to reduce the operation associated emissions at an early stage. The findings showed that a 3000 times scale-up strategy assuming constant geometric dimensions and specific energy consumption (P/Vw) resulted in lower impeller speed and energy demand. The Rushton turbine blade (RTB) and LightninA315 four-blade hydrofoil (LA315) were found to have the highest and lowest torque output, respectively, at a similar P/Vw of 2.8 kWm−3, with agitation speeds of 1.33 and 2.5 s−1, respectively. RTB demonstrating lower shear damage towards cells (up to 1.33 s−1) was selected because it permits high torque, low-power and acceptable turbulence. The LCA results showed a strong relation between the number of impellers installed and associated emissions suggesting a trade-off between mixing performance and environmental impacts.

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“…For instance, velocity fluctuations (turbulent intensity) help to improve the mixing process [19]. Some authors have found that there is a close interaction between the morphology, the broth rheology, and the turbulent intensity in submerged fungal fermentations in stirred tank reactors [20][21][22]. On the other hand, the turbulent intensity can be linked to the strain rate.…”

Section: Introductionmentioning

confidence: 99%

Flow Patterns of Multiple Axial‐Radial Impellers for Potential Use in Aerated Stirred Tanks

et al. 2022

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The hydrodynamics of a stirred tank equipped with multiple hybrid impellers was experimentally characterized. They were coaxially placed to agitate a viscous Newtonian fluid under gassed conditions. Experiments were performed by using the particle image velocimetry technique, and flow fields were reported in terms of the velocity magnitude, vertical currents, turbulent intensity, and strain rates. For comparison purposes, impellers providing radial flow (Rushton turbines) and axial flow (pitched blade turbines) were also tested. The results showed that hybrid impellers provided a uniform flow distribution throughout the tank at moderate strain rates, which make them an attractive alternative for fermentation processes with shear-sensitive cultures and viscous liquids.

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The Impact of Fluid Dynamic Stress in Stirred Bioreactors – The Scale of the Biological Entity: A Personal View

Cited by 30 publications

References 64 publications

Design and development of a new ambr250® bioreactor vessel for improved cell and gene therapy applications

Design and development of a new ambr250® bioreactor vessel for improved cell and gene therapy applications

Upscale fermenter design for lactic acid production from cheese whey permeate focusing on impeller selection and energy optimization

Flow Patterns of Multiple Axial‐Radial Impellers for Potential Use in Aerated Stirred Tanks

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