Methods in Molecular Biology (2022) 2436: 67–81
DOI 10.1007/7651_2021_423
© Springer Science+Business Media, LLC 2021
Published online: 15 September 2021
Integrating Human-Induced Pluripotent Stem Cell
Expansion Capability and Cardiomyocyte Differentiation
Potential in a Microcarrier Suspension Culture
Valerie Ho, Gerine Tong, Alan Lam, Shaul Reuveny, and Steve Oh
Abstract
Human-induced pluripotent stem cells are known for their high proliferation capacity as well as their ability
to differentiate to different lineages (Ban et al., Theranostics 7(7):2067–2077, 2017; Chen et al., Stem Cell
Res 15(2):365–375, 2015; Serra et al., Trends Biotechnol 30(6):350–359, 2012). For stem-cell-derived
cardiomyocytes to evolve into a scalable therapeutic source, a large quantity of highly pure cardiomyocytes
is needed. Thus, lies the challenge of defining an efficient cardiomyocyte differentiation process. This
chapter describes a method to evaluate multiple human-induced pluripotent stem cell lines for their cardiac
differentiation potentials before evaluating their integrated proliferation and differentiation abilities in
microcarrier cultures in a spinner culture format.
Key words Cardiomyocytes, Human-induced pluripotent stem cells, Microcarrier
1
Introduction
Cardiac-related diseases are the one of the leading causes of death
around the world [1]. Since mature cardiomyocytes (CM) are
unable to regenerate to restore original functionality, the only way
to restore a damaged heart is through heart transplantation
[1, 2]. However, demand for such treatment exceeds the supply
due to the shortage of donors [1, 2]. To satisfy the demand, stem-
cell-derived CMs can be considered as a potential solution to
replace damaged cardiac tissue. For this reason, an optimized,
scalable, efficient system of producing high-purity stem-cell-
derived CMs utilizing microcarriers (MC) is needed [3]. By taking
advantage of human-induced pluripotent stem cells’ high prolifera-
tion as well as their ability to differentiate into CMs, the vision for a
renewable source of mature CMs may be realized [4–6]. Different
cell lines are shown to have different cardiac differentiation poten-
tials as well as growth rates on microcarriers [7]. The first step is
cell-line selection for high cardiac differentiation potentials on the
monolayer cultures. While the second is selection for high prolifer-
ation capacity in an MC spinner culture followed by differentiation
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