Cell Separation in Aqueous Two‐Phase Systems − Influence of Polymer Molecular Weight and Tie‐Line Length on the Resolution of Five Model Cell Lines

Zimmermann, Sarah C.; Gretzinger, Sarah; Zimmermann, Philipp K.; Bogsnes, Are; Hansson, Mattias; Hubbuch, Jürgen

doi:10.1002/biot.201700250

Cited by 6 publications

(2 citation statements)

References 35 publications

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“…In the past, the integration of robotic systems for downstream process development led to significant increases in the throughput of several standard operation procedures. For example, cell lysis has been optimized for improved release of intracellular products, the screening of chromatographic material and binding/elution conditions was facilitated, and the identification of optimal compositions of aqueous two‐phase systems or precipitation conditions has become experimentally feasible. So far only a few but highly interesting studies have been reported that combine high‐throughput upstream and downstream bioprocess development .…”

Section: Microbioreactor (Mbr) Systemsmentioning

confidence: 99%

Microbioreactor Systems for Accelerated Bioprocess Development

Hemmerich

Noack

Wiechert

et al. 2018

Biotechnology Journal

138

143

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In recent years, microbioreactor (MBR) systems have evolved towards versatile bioprocess engineering tools. They provide a unique solution to combine higher experimental throughput with extensive bioprocess monitoring and control, which is indispensable to develop economically and ecologically competitive bioproduction processes. MBR systems are based either on down-scaled stirred tank reactors or on advanced shaken microtiter plate cultivation devices. Importantly, MBR systems make use of optical measurements for non-invasive, online monitoring of important process variables like biomass concentration, dissolved oxygen, pH, and fluorescence. The application range of MBR systems can be further increased by integration into liquid handling robots, enabling automatization and, thus standardization, of various handling and operation procedures. Finally, the tight integration of quantitative strain phenotyping with bioprocess development under industrially relevant conditions greatly increases the probability of finding the right combination of producer strain and bioprocess control strategy. This review will discuss the current state of the art in the field of MBR systems and we can readily conclude that their importance for industrial biotechnology will further increase in the near future.

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Section: Microbioreactor (Mbr) Systemsmentioning

confidence: 99%

Microbioreactor Systems for Accelerated Bioprocess Development

Hemmerich

Noack

Wiechert

et al. 2018

Biotechnology Journal

138

143

View full text Add to dashboard Cite

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“…They are formed when two hydrophilic compounds such as polymers, salts or ionic liquids are combined above critical concentrations, resulting in the formation of two immiscible phases . The resulting phases have different concentrations of both compounds and thus different electrochemical and hydrophobic characteristics, allowing the partition of biomolecules according to their intrinsic properties . However, such systems lack specificity when the differences between the component of interest and the contaminants (red blood cells, non‐viable cells, cell debris and other mononuclear cells) are small.…”

Section: Introductionmentioning

confidence: 99%

Characterization and optimization of immunoaffinity aqueous two‐phase systems with PEGylated CD133/2‐biotin antibody in route to stem cell separation

Ornelas‐González

Reisenauer

Rito‐Palomares

2019

J of Chemical Tech & Biotech

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BACKGROUND: A short processing time and efficient scale-up stem cell isolation bioprocess is essential to exploit the potential of these cells for the treatment of multiple chronic diseases. Various methodologies have been used for stem cell recovery. However, most of them present economic and/or time-consuming drawbacks. RESULTS: This paper reports the characterization and optimization of immunoaffinity aqueous two-phase systems (ATPS), a liquid-liquid based separation technology enhanced with the PEGylation of the antibody as a promising platform in route tothe separation of CD133 + stem cells. The best results were obtained with Ucon-DEX or PEG-DEX systems with tie-line length (TLL) 15 or 20% w/w and volume ratio (V R ) 3. When the PEGylated antibodies were added to these selected optimized ATPS, they partitioned to both phases, but with higher preference for the bottom phase. CONCLUSION: PEGylation was an effective strategy to induce a change in the partition behavior of the CD133/2-biotin antibody when Ucon-DEX ATPS were used. Similarly, variation of the parameters (TLL and V R ) resulted to be useful for this goal.Nevertheless, further studies are required to find the optimal ATPS composition that will fractionate 100% of the antibody to the contaminants' opposite phase, making this system an ideal candidate to be tested for the selectivity of CD133 + stem cells. Immunoaffinity ATPS optimization strategyA multilevel categorical design was carried out using Statgraph-ics18 software (Statgraphics Technologies, Inc., The Plains, VA, USA). A total of 27 combinations by duplicate of three TLLs (15, 20 and 25% w/w) and three V R s (0.33, 1 and 3) were explored J Chem Technol Biotechnol 2020; 95: 123-131

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