Twenty‐four‐well plate miniature bioreactor high‐throughput system: Assessment for microbial cultivations

Isett, Kevin; George, Hugh A.; Herber, Wayne K.; Amanullah, Ashraf

doi:10.1002/bit.21484

Cited by 120 publications

(88 citation statements)

References 26 publications

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“…Temperature shift was performed from 37˚C to 34˚C on day 3 in both the systems and maintained till the end of the run. One of the primary advantages of the AMBR over other known MBR systems is that the AMBR does not require agitation to pause for sampling or feed addition hence reducing interruption in temperature maintenance [14]. The mixing time of the feeds are also not impacted since the agitation is not affected.…”

Section: Open Accessmentioning

confidence: 99%

“…Recent literature have demonstrated availability of various designs of micro-scale reactors from a simpler standard plate with integrated sensors called Microtiter plate based bioreactors (MTB) [6][7][8][9][10][11][12] to more advanced cell culture systems such as the Stirred Mini Bioreactors (MBR) with control capabilities close to bench-top bioreactors for high throughput cell culture screening and optimization studies [13][14][15][16][17]. MBRs possess the advantage of being able to closely mirror the bench-scale bio-reactors in their monitoring and control capabilities and hence are considered as a preferred alternative vessel over shake flasks or MTBs for early stage process development.…”

Section: Introductionmentioning

confidence: 99%

“…MBRs possess the advantage of being able to closely mirror the bench-scale bio-reactors in their monitoring and control capabilities and hence are considered as a preferred alternative vessel over shake flasks or MTBs for early stage process development. MBRs are generally equipped with optical probes to monitor pH and DO online and it has been extensively characterized for its oxygen transfer rate, mixing capabilities and gassing efficiency [13][14][15][16][17]. The above mentioned characteristics of MBRs typically make them an ideal set up for early high-throughput clonal screening efforts as part of process development.…”

Section: Introductionmentioning

confidence: 99%

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Assessment of AMBR<sup>TM</sup> as a model for high-throughput cell culture process development strategy

Moses¹,

Manahan²,

Ambrogelly³

et al. 2012

ABB

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The development and delivery of high quality therapeutic products necessitates the need for highthroughput (HTP) process development tools. Traditionally, these works requires a combination of shake flask and small-scale stirred tank bioreactor (STR) which are labor and resource intensive and time-consuming. Here we demonstrate a strategy for rapid and robust cell culture process development by evaluating and implementing the use of a new HTP disposable micro bioreactor (MBR) called AMBR TM system (Advanced Microscale Bioreactor) that has the capabilities for automated sampling, feed addition, pH, dissolved oxygen (DO), gassing and agitation controls. In these studies the performance of two monoclonal antibody (MAb) producing cell lines (MAb1 and MAb2) was evaluated both in the AMBR system and 3-L STR. We demonstrated that cell culture performance (growth and viability, production titer and product quality) were similar in both vessel systems. Furthermore, process control and feed optimization were demonstrated in an additional cell line (MAb3) in the disposable MBR and its performance confirmed at STR scale. The results indicate that the AMBR system can be used to streamline the process development effort and facilitate a rapid and robust cell culture process development effort for MAb programs in a HTP manner.

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Section: Open Accessmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Assessment of AMBR<sup>TM</sup> as a model for high-throughput cell culture process development strategy

Moses¹,

Manahan²,

Ambrogelly³

et al. 2012

ABB

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“…Enzyme production and thermochemical pretreatment are primary economic barriers to commercial scale-up of biorefineries that require further cost reductions through reduction in enzyme loading and pre-treatment severity. Coupling high-throughput pre-treatment , hydrolysis (Berlin et al, 2005), fermentation (Isett et al, 2007;Weimer et al, 2005), and compositional analysis (Chambliss et al, 2007) will facilitate rapid screening and identification of key bottlenecks to the biomass conversion process.…”

Section: Discussionmentioning

confidence: 99%

High‐throughput microplate technique for enzymatic hydrolysis of lignocellulosic biomass

Chundawat

Balan

Dale

2008

Biotech & Bioengineering

118

113

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Several factors will influence the viability of a biochemical platform for manufacturing lignocellulosic based fuels and chemicals, for example, genetically engineering energy crops, reducing pre-treatment severity, and minimizing enzyme loading. Past research on biomass conversion has focused largely on acid based pre-treatment technologies that fractionate lignin and hemicellulose from cellulose. However, for alkaline based (e.g., AFEX) and other lower severity pre-treatments it becomes critical to co-hydrolyze cellulose and hemicellulose using an optimized enzyme cocktail. Lignocellulosics are appropriate substrates to assess hydrolytic activity of enzyme mixtures compared to conventional unrealistic substrates (e.g., filter paper, chromogenic, and fluorigenic compounds) for studying synergistic hydrolysis. However, there are few, if any, high-throughput lignocellulosic digestibility analytical platforms for optimizing biomass conversion. The 96-well Biomass Conversion Research Lab (BCRL) microplate method is a high-throughput assay to study digestibility of lignocellulosic biomass as a function of biomass composition, pre-treatment severity, and enzyme composition. The most suitable method for delivering milled biomass to the microplate was through multi-pipetting slurry suspensions. A rapid bio-enzymatic, spectrophotometric assay was used to determine fermentable sugars. The entire procedure was automated using a robotic pipetting workstation. Several parameters that affect hydrolysis in the microplate were studied and optimized (i.e., particle size reduction, slurry solids concentration, glucan loading, mass transfer issues, and time period for hydrolysis). The microplate method was optimized for crystalline cellulose (Avicel) and ammonia fiber expansion (AFEX) pre-treated corn stover.

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“…These technological developments were also timely introduced to contribute to gaining insight on the identification of the key parameters required to allow for reproducibility between shaken vessels and bench-scale stirred reactors, a feature that only in a relatively recent period has been suitably addressed [11][12][13][14]. There are hence few examples of scaling fermentation or bioconversion processes directly from MWP to bench-scale bioreactor partially due to the lack of instrumentation in traditional MWP [5, [14][15][16]. scales, viz.…”

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confidence: 99%

A microwell platform for the scale‐up of a multistep bioconversion to bench‐scale reactors: Sitosterol side‐chain cleavage

Marques¹,

Fernandes²

2010

Biotechnology Journal

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The microwell‐scale approach is widely used for screening purposes and one‐pot biotransformations, but it has seldom been applied to complex whole cell multistep bioconversions, requiring prolonged incubation periods. The present study aims to contribute to filling this gap. The side‐chain cleavage of sitosterol to androstenedione (AD) with Mycobacterium sp. NRRL B‐3805 cells was used as a model system, and focus was given to the screening of suitable bioconversion media with 24‐well microwell plates. Results show that to perform this particular bioconversion growing cells are preferred over resting cells due to higher conversion yields obtained in aqueous medium. The use of resting cells may nevertheless present an interesting approach provided catalytic activity is retained throughout successive runs. Maintaining suitable aeration levels (air flow of 1 mL/min) allowed minimizing the decay of catalytic activity typically observed alongside consecutive bioconversion runs with resting cells. Microwell plates with dedicated oxygen and pH monitoring capabilities proved effective in media development for complex multistep bioconversions using relatively slow‐growing bacteria. Under constant kLa (0.044/s) similar AD production and dissolved oxygen profiles were observed in microwell plates and in a bench‐scale reactor. Selection of a suitable kLa value proved critical, since under lower kLa values scale‐up proved unsuccessful. The same pattern was observed when other scale‐up criteria were evaluated to perform the scale‐up of this particular bioconversion. Results gathered seem to validate the proposed approach “from microwell plate to bench‐scale fermentor”.

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Twenty‐four‐well plate miniature bioreactor high‐throughput system: Assessment for microbial cultivations

Cited by 120 publications

References 26 publications

Assessment of AMBR<sup>TM</sup> as a model for high-throughput cell culture process development strategy

Assessment of AMBR<sup>TM</sup> as a model for high-throughput cell culture process development strategy

High‐throughput microplate technique for enzymatic hydrolysis of lignocellulosic biomass

A microwell platform for the scale‐up of a multistep bioconversion to bench‐scale reactors: Sitosterol side‐chain cleavage

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Twenty‐four‐well plate miniature bioreactor high‐throughput system: Assessment for microbial cultivations

Cited by 120 publications

References 26 publications

Assessment of AMBR&lt;sup&gt;TM&lt;/sup&gt; as a model for high-throughput cell culture process development strategy

Assessment of AMBR&lt;sup&gt;TM&lt;/sup&gt; as a model for high-throughput cell culture process development strategy

High‐throughput microplate technique for enzymatic hydrolysis of lignocellulosic biomass

A microwell platform for the scale‐up of a multistep bioconversion to bench‐scale reactors: Sitosterol side‐chain cleavage

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Assessment of AMBR<sup>TM</sup> as a model for high-throughput cell culture process development strategy

Assessment of AMBR<sup>TM</sup> as a model for high-throughput cell culture process development strategy