A common framework for integrated and continuous biomanufacturing

Coffman, Jon; Brower, Mark; Connell-Crowley, Lisa; Deldari, Sevda; Farid, Suzanne S.; Horowski, Brian; Patil, Ujwal; Pollard, David; Qadan, Maen; Rose, Steven; Schaefer, Edward J.; Shultz, Joseph

doi:10.1002/bit.27690

Cited by 40 publications

(42 citation statements)

References 63 publications

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“…The high‐level consequences of the common framework ICB are discussed in the accompanying article (Coffman et al, 2020 ). Here we discuss the details of the design to demonstrate the flexibility and productivity of the framework ICB.…”

Section: Resultsmentioning

confidence: 99%

The design basis for the integrated and continuous biomanufacturing framework

Coffman

Bibbo²,

Brower

et al. 2021

Biotech & Bioengineering

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An 8 ton per year manufacturing facility is described based on the framework for integrated and continuous bioprocessing (ICB) common to all known biopharmaceutical implementations. While the output of this plant rivals some of the largest fed‐batch plants in the world, the equipment inside the plant is relatively small: the plant consists of four 2000 L single‐use bioreactors and has a maximum flow rate of 13 L/min. The equipment and facility for the ICB framework is described in sufficient detail to allow biopharmaceutical companies, vendors, contract manufacturers to build or buy their own systems. The design will allow the creation of a global ICB ecosystem that will transform biopharmaceutical manufacturing. The design is fully backward compatible with legacy fed‐batch processes. A clinical production scale is described that can produce smaller batch sizes with the same equipment as that used at the commercial scale. The design described allows the production of as little as 10 g to nearly 35 kg of drug substance per day.

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Section: Resultsmentioning

confidence: 99%

The design basis for the integrated and continuous biomanufacturing framework

Coffman

Bibbo²,

Brower

et al. 2021

Biotech & Bioengineering

Self Cite

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“…A broader analysis of new bioprocessing concepts has also been modelled and assessed with respect to economics [252]. Likewise, a very useful common framework was recently published to assist the overall evaluation of novel biomanufacturing options in a combined industry-academic partnership [253]. Finally, short-cut calculations have also been used to assess product recovery options [254], where modelling in detail has been found too time-demanding.…”

Section: Bioprocess Intensification Modelling Toolsmentioning

confidence: 99%

Bioprocess intensification: A route to efficient and sustainable biocatalytic transformations for the future

Boodhoo

Flickinger

Woodley

et al. 2022

Chemical Engineering and Processing - Process Intensification

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“…Continuous chromatography has increasingly been used for clinical manufacturing, due to economic benefits, reduced resin and buffer needs, and fewer waste amounts. [ 1,2 ] Different vendors have developed and provide continuous chromatography systems, for example, Chromacon, Novasep, Sartorius, Cytiva, Lewa, and others. These can be run in simulated moving bed principle, for example, the BioSMB system, or periodic counter‐current mode, for example, Cytiva systems.…”

Section: Introductionmentioning

confidence: 99%

“…Economic benefits in these systems are achieved by overloading the resin of a first column, with antibody binding to that first column. The effluent or break‐through of that first column, containing residual amounts of antibody is then captured via a 2 nd column [ 1,3,4 ] (example in Figure 1A–E). The effluent, containing residual amounts of antibody is referred to as “spent load” as most of the antibody present has been bound to the 1st column.…”

Section: Introductionmentioning

confidence: 99%

Mimicking continuous capture chromatography for virus clearance using a single chromatography column model

Capito

Flato

Oeinck

et al. 2022

Biotechnology Journal

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Continuous chromatography is increasingly being used across the biotechnology industry due to its economic advantages. For adoption in commercial manufacturing, also models for virus clearance studies must be available. It is demonstrated how for a virus clearance study for a multispecific antibody, the continuous protein A capture chromatography process, being run on multiple interconnected columns, can be mimicked with only a single column. With this mimicking small‐scale model, resources and complexity can be minimized, when conducting virus clearance studies at a contract research organization (CRO) lab. Obtained log reduction values (LRV) for murine leukemia virus (xMuLV) and minute virus of mice (MVM) virus, used as model viruses, are comparable to batch protein A chromatography and results described by other groups. The feasibility of this mimicking small‐scale model helps to further reduce barriers to adoption when implementing continuous chromatography.

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A common framework for integrated and continuous biomanufacturing

Cited by 40 publications

References 63 publications

The design basis for the integrated and continuous biomanufacturing framework

The design basis for the integrated and continuous biomanufacturing framework

Bioprocess intensification: A route to efficient and sustainable biocatalytic transformations for the future

Mimicking continuous capture chromatography for virus clearance using a single chromatography column model

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