Pilot‐scale demonstration of an end‐to‐end integrated and continuous biomanufacturing process

High volumetric productivities can be achieved when perfusion processes are operated at high cell densities. Yet it is fairly challenging to keep high cell density cultures in a steady state over an extended period. Aiming for robust processes, cultures were operated at a constant biomass specific perfusion rate (BSPR) in this study. The cell density was monitored with a capacitance probe and a continuous bleed maintained the targeted viable cell volume. Despite our tightly controlled BSPR, a gradual accumulation of ammonium and changes in cell diameter were observed during the production phase for three different monoclonal antibodies. Although a lot of efforts in media optimization have been made to reduce ammonium in fed‐batch process, less examples are known about how media components impact the cellular metabolism and thus the quality of monoclonal antibodies in continuous processes. In this study, we show that a continuous Na‐pyruvate feed (2 g/L/day) strongly reduced ammonium production and stabilized fucosylation, sialylation and high mannose content for three different mAbs.

Section: Introductionmentioning

confidence: 99%

Effects of pyruvate on primary metabolism and product quality for a high‐density perfusion process

Caso

Aeby

Jordan

et al. 2022

“…While design variables have been explored quite extensively in past work in continuous viral inactivation (Amarikwa et al, 2019; Coolbaugh et al, 2021; Gillespie et al, 2019; Klutz et al, 2016; Orozco et al, 2017; Parker et al, 2018), disturbance rejection has not been discussed directly. Disturbance rejection is especially important to consider when operating continuously for an extended period of time.…”

Section: Resultsmentioning

confidence: 99%

“…work in continuous viral inactivation (Amarikwa et al, 2019;Coolbaugh et al, 2021;Gillespie et al, 2019;Klutz et al, 2016;Orozco et al, 2017;Parker et al, 2018), disturbance rejection has not been discussed directly.…”

Section: While Design Variables Have Been Explored Quite Extensively ...mentioning

confidence: 99%

“…Methods for adapting low-pH hold to continuous processing have involved cyclic batch operation (Pall Life Sciences, 2018), continuousflow tubular reactors (Amarikwa et al, 2019;Coolbaugh et al, 2021;Gillespie et al, 2019;Klutz et al, 2016;Orozco et al, 2017;Parker et al, 2018), and continuous-flow column-based reactors (Arnold et al, 2019;Martins et al, 2019Martins et al, , 2020Senčar et al, 2020). None of the continuous-flow reactors, however, directly address control considerations with operating the systems.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Model‐based control for column‐based continuous viral inactivation of biopharmaceuticals

Hong

et al. 2021

Batch low-pH hold is a common processing step to inactivate enveloped viruses for biologics derived from mammalian sources. Increased interest in the transition of biopharmaceutical manufacturing from batch to continuous operation resulted in numerous attempts to adapt batch low-pH hold to continuous processing. However, control challenges with operating this system have not been directly addressed. This article describes a low-cost, column-based continuous viral inactivation system constructed with off-the-shelf components. Model-based, reaction-invariant pH controller is implemented to account for the nonlinearities with Bayesian estimation addressing variations in the operation. The residence time distribution is modeled as a plug flow reactor with axial dispersion in series with a continuously stirred tank reactor, and is periodically estimated during operation through inverse tracer experiments. The estimated residence time distribution quantifies the minimum residence time, which is used to adjust feed flow rates. Controller validation experiments demonstrate that pH and minimum residence time setpoint tracking and disturbance rejection are achieved with fast and accurate response and no instability. Viral inactivation testing demonstrates tight control of logarithmic reduction values over extended operation. This study provides tools for the design and operation of continuous viral inactivation systems in service of increasing productivity, improving product quality, and enhancing patient safety.

“…However, Godawat et al ( 2015 ) were able to combine a perfusion bioreactor with two periodic PCC units for initial capture and successive ion‐exchange steps, showing it is feasible to fully create and integrate an end‐to‐end continuous bioprocessing platform. More recently, Coolbaugh et al ( 2021 ) have demonstrated such end‐to‐end continuous processes are scalable by showing a successful proof‐of‐concept at pilot‐scale.…”

Section: Current Needs In the Integrated Continuous Bioprocessingmentioning

confidence: 99%

White paper on high‐throughput process development for integrated continuous biomanufacturing

Pedro

Silva

Patil

et al. 2021

Self Cite

Continuous manufacturing is an indicator of a maturing industry, as can be seen by the example of the petrochemical industry. Patent expiry promotes a price competition between manufacturing companies, and more efficient and cheaper processes are needed to achieve lower production costs. Over the last decade, continuous biomanufacturing has had significant breakthroughs, with regulatory agencies encouraging the industry to implement this processing mode. Process development is resource and time consuming and, although it is increasingly becoming less expensive and faster through high‐throughput process development (HTPD) implementation, reliable HTPD technology for integrated and continuous biomanufacturing is still lacking and is considered to be an emerging field. Therefore, this paper aims to illustrate the major gaps in HTPD and to discuss the major needs and possible solutions to achieve an end‐to‐end Integrated Continuous Biomanufacturing, as discussed in the context of the 2019 Integrated Continuous Biomanufacturing conference. The current HTPD state‐of‐the‐art for several unit operations is discussed, as well as the emerging technologies which will expedite a shift to continuous biomanufacturing.