Principles and approach to developing mammalian cell culture media for high cell density perfusion process leveraging established fed‐batch media

Lin, Henry; Leighty, Robert W.; Godfrey, Scott; Wang, Samantha Boran

doi:10.1002/btpr.2472

Cited by 61 publications

(45 citation statements)

References 33 publications

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“…In this study, we investigated the benefit of a rapid and empirical DoE‐driven workflow to develop novel perfusion media by blending chemically defined basal media and established feed supplements. Using this empirical approach, a larger design space can be investigated when the exact media ingredients are unknown, compared to a more rational and targeted optimization approach . Rapid screening of a total of eight different cell supplement solutions in two different basal media was demonstrated.…”

Section: Resultsmentioning

confidence: 99%

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Rapid development of clone‐specific, high‐performing perfusion media from established feed supplements

Mayrhofer

Reinhart

Castan³

et al. 2019

Biotechnology Progress

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Perfusion cultivation of recombinant CHO cells is of substantial interest to the biopharmaceutical industry. This is due to increased space–time‐yields (STYs) and a short residence time of the recombinant protein in the bioreactor. Economic processes rely on cultivation media supporting rapid growth in the exponential phase and high protein production in the stationary phase at minimal media consumption rates. To develop clone‐specific, high‐performing perfusion media we present a straightforward and rapid two‐step approach combining commercially available basal media and feed supplements using design‐of‐experiment. First, the best performing feed supplements are selected in batch cultures. Then, the mixing ratio of selected feed supplements is optimized in small‐scale semicontinuous perfusion cultures. The final media formulation is supported by statistical response surface modeling of a set of cultivation experiments with blended media formulations. Two best performing novel media blends were finally applied to perfusion bioreactor verification runs to reach 200 × 106 c/ml within 2 weeks at minimum cell‐specific perfusion rates as low as 10–30 pL/c/d. Obtained STYs of 0.4–1.2 g/L/d represent a 10‐fold increase compared to batch cultures. This general workflow is universally applicable to any perfusion platform combining a specific cell line, basal medium, and established feed solutions.

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Section: Resultsmentioning

confidence: 99%

“…High cell densities were supported at minimal CSPR as low as 10–30 pL/c/d and no changes of product quality were induced by the included feed supplements. The high‐performing perfusion media, developed from this empirical design approach, can subsequently be used as starting point for further rational and additional targeted optimization …”

Section: Resultsmentioning

confidence: 99%

Rapid development of clone‐specific, high‐performing perfusion media from established feed supplements

Mayrhofer

Reinhart

Castan³

et al. 2019

Biotechnology Progress

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“…Despite differences among the various perfusion operations which are utilized for recombinant protein expression in CHO cell culture, including N − 1 perfusion, concentrated fed‐batch and continuous perfusion production, the starting point for perfusion medium development is typically the basal and feed media used for fed‐batch culture. One successful case of perfusion medium development, which resulted in a titer of 1.2 g/L per day, was achieved by optimizing the ratio between existing basal and feed media, removing unnecessary components, increasing medium depth, optimizing osmolality, and rebalancing amino acids and vitamins . However, more so than with fed‐batch media design, logistical issues such as simplicity of operation and compatibility with manufacturing facilities must be taken into account in the development of perfusion media.…”

Section: Recent Advances In Medium Developmentmentioning

confidence: 99%

“…Concentrated media formulated for precise delivery of nutrition can facilitate the manufacturing process and reduce cost . Although perfusion experiments and processes are typically executed in bench‐scale bioreactors, inexpensive and convenient scale‐down models for perfusion have been developed in deep well plates, spin tubes, and automated bioreactors, which can enable the large statistical DoE screens required to optimize perfusion media …”

Section: Recent Advances In Medium Developmentmentioning

confidence: 99%

Cell culture media for recombinant protein expression in Chinese hamster ovary (CHO) cells: History, key components, and optimization strategies

Ritacco

Khetan

2018

Biotechnology Progress

182

138

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The culture of Chinese Hamster Ovary (CHO) cells for modern industrial applications, such as expression of recombinant proteins, requires media that support growth and production. Such media must support high viable cell densities while also stimulating the synthesis and extracellular transport of biologic products. Early media development efforts in this area yielded basic formulations to sustain growth, viability, and cellular function, albeit comprising animal sourced components, and complex constituents used in batch culture mode. Subsequent improvements included the development of serum‐free and chemically defined (CD) media, the identification of critical nutrients, growth factors, and potentially inhibitory or toxic cellular metabolites, and the use of fed‐batch and perfusion culture techniques to optimize nutrient delivery while minimizing accumulation of unwanted waste products. This review is comprised of sections covering milestones in the evolution of mammalian cell culture media, nutrient composition and formulation requirements, optimization strategies, consistency and scalability of powder and liquid media preparation for industrial applications, and key recent advances driving progress in CHO cell culture medium design and development. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 34:1407–1426, 2018

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“…A proprietary chemically defined medium for perfusion was used as the background for all experiments (Lin, Leighty, Godfrey, & Wang, ). Different levels of Na and K was achieved by interchanging Na forms of certain medium components with the respective K forms (e.g., potassium chloride for sodium chloride).…”

Section: Methodsmentioning

confidence: 99%

Manipulation of the sodium‐potassium ratio as a lever for controlling cell growth and improving cell specific productivity in perfusion CHO cell cultures

Wang

Lee‐Goldman

Ravikrishnan

et al. 2018

Biotech & Bioengineering

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Perfusion processes typically require removal of a continuous or semi-continuous volume of cell culture in order to maintain a desired target cell density. For fast growing cell lines, the product loss from this stream can be upwards of 35%, significantly reducing the overall process yield. As volume removed is directly proportional to cell growth, the ability to modulate growth during perfusion cell culture production thus becomes crucial. Leveraging existing media components to achieve such control without introducing additional supplements is most desirable because it decreases process complexity and eliminates safety and clearance concerns. Here, the impact of extracellular concentrations of sodium (Na) and potassium (K) on cell growth and productivity is explored. High throughput small-scale models of perfusion revealed Na:K ratios below 1 can significantly suppress cell growth by inducing cell cycle arrest in the G0/1 phase. A concomitant increase in cell specific productivity was also observed, reaching as high as 115 pg/cell/day for one cell line studied. Multiple recombinant Chinese hamster ovary (CHO) cell lines demonstrated similar responses to lower Na:K media, indicating the universal applicability of such an approach. Product quality attributes were also assessed and revealed that effects were cell line specific, and can be acceptable or manageable depending on the phase of the drug development. Drastically altering Na and K levels in perfusion media as a lever to impact cell growth and productivity is proposed.

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Principles and approach to developing mammalian cell culture media for high cell density perfusion process leveraging established fed‐batch media

Cited by 61 publications

References 33 publications

Rapid development of clone‐specific, high‐performing perfusion media from established feed supplements

Rapid development of clone‐specific, high‐performing perfusion media from established feed supplements

Cell culture media for recombinant protein expression in Chinese hamster ovary (CHO) cells: History, key components, and optimization strategies

Manipulation of the sodium‐potassium ratio as a lever for controlling cell growth and improving cell specific productivity in perfusion CHO cell cultures

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