Methods in Molecular Biology (2022) 2436: 257–266
DOI 10.1007/7651_2021_444
© Springer Science+Business Media, LLC 2021
Published online: 02 November 2021
Bioreactor-Based Adherent Cells Harvesting from
Microcarriers with 3D Printed Inertial Microfluidics
Lin Ding, Reza Moloudi, and Majid Ebrahimi Warkiani
Abstract
Harvesting adherent cells from microcarriers has become one of the major challenges of the downstream
bioprocessing at large scale the current method has high maintenance and operation cost, which are the
results of frequent clogging, due to cell lysing effect and microcarrier cake formation on membrane-based
technology. These problems hugely impede the adaptation of microcarriers technologies in large-scale cell
culture and hampered the supply of cells to the clinical need. Here, we describe two 3D printing-based
methods to fabricate inertial microfluidic devices for separating adherent cells from microcarriers which
overcome the above-mentioned limitations. The spiral devices are employed to separate mesenchymal stem
cells from the microcarriers with 99% microcarrier removal rate and 77% cell recovery rate in one round of
separation.
Key words Stem cells, Inertial microfluidics, Cell harvesting, Microcarrier-based culture, Cell therapy
industry
1
Introduction
Microcarrier-based cell culture is considered as the future standard
of adherent cells culture in large-scale [1, 2]. They have large
surface area-to-volume ratio for the cells to attach and provide a
better environment for cells interaction and secretion [1]. However,
multilayer flasks are still the most common way of adherent cells
production. The slow adaptation of new technology can be mainly
attributed to the complicated cell harvesting procedure of
microcarrier-based culture method. Harvesting cells from micro-
carriers heavily relies on membrane-based technologies Cells and
microcarriers solution is passed through the physical filters which
are frequently blocked by cell clumps, results in cell lysis and are
expensive to change and operate [2].
One of the potential substitutions of membrane-based tech-
nologies is inertial microfluidic devices. Inertial microfluidics has
been used widely for separation of cells from a heterogeneous
population recently. It focuses particles with different sizes at dif-
ferent cross-sectional positions inside the channel, allowing the
particles to be collected from different outlets [3, 4]. In a straight
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