Abstract
Cell‐based therapeutics, such as in vitro manufactured red blood cells (mRBCs), are different to traditional biopharmaceutical products (the final product being the cells themselves as opposed to biological molecules such as proteins) and that presents a challenge of developing new robust and economically feasible manufacturing processes, especially for sample purification. Current purification technologies have limited throughput, rely on expensive fluorescent or magnetic immunolabeling with a significant (up to 70%) cell loss and quality impairment. To address this challenge, previously characterized mechanical properties of umbilical cord blood CD34+ cells undergoing in vitro erythropoiesis were used to develop an mRBC purification strategy. The approach consists of two main stages: (a) a microfluidic separation using inertial focusing for deformability‐based sorting of enucleated cells (mRBC) from nuclei and nucleated cells resulting in 70% purity and (b) membrane filtration to enhance the purity to 99%. Herein, we propose a new route for high‐throughput (processing millions of cells/min and mls of medium/min) purification process for mRBC, leading to high mRBC purity while maintaining cell integrity and no alterations in their global gene expression profile. Further adaption of this separation approach offers a potential route for processing of a wide range of cellular products.
Highlights
Stem cell‐derived red blood cells could constitute an attractive pathogen‐free and sustainable alternative for donated blood for rare blood groups and patients requiring regular transfusions (Zeuner et al, 2012)
We successfully developed a passive, high‐throughput, label‐free purification strategy for cord blood (CB) CD34+ derived red blood cells
Using advances in the field of deformability cytometry, heterogeneous end‐products of CB CD34+ in vitro erythropoiesis were characterized and label‐free markers were identified for the target enucleated cells as well as contaminant nucleated cells and expelled nuclei
Summary
Stem cell‐derived red blood cells could constitute an attractive pathogen‐free and sustainable alternative for donated blood for rare blood groups and patients requiring regular transfusions (Zeuner et al, 2012). Due to its simplicity in operation, low manufacturing cost and proven scalability by parallelization (allowing processing millions of cells per minute) inertial focusing in spiral channels has been recognized as an attractive approach for high‐throughput cell sorting (Gou, Jia, Wang, & Sun, 2018) for a wide range of applications (for a comprehensive review, see Gou et al, 2018). The impact of deformability on the focusing mechanism has been translated into an effective label‐free purification protocol for mRBC derived from cord blood CD34+ cells This approach offers a viable alternative to FACS and MACS for sorting mRBC at industrial scale in a label‐free manner at high purities and without compromising cell quality, creating a new route to bring mRBC into clinical use
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