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Increased curvature of hollow fiber membranes could up‐regulate differential functions of renal tubular cell layers
Author(s) -
Shen Chong,
Meng Qin,
Zhang Guoliang
Publication year - 2013
Publication title -
biotechnology and bioengineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.136
H-Index - 189
eISSN - 1097-0290
pISSN - 0006-3592
DOI - 10.1002/bit.24874
Subject(s) - membrane , curvature , biophysics , fiber , membrane curvature , materials science , in vivo , hollow fiber membrane , tissue engineering , cell , chemistry , biomedical engineering , biology , composite material , biochemistry , geometry , mathematics , vesicle , medicine , microbiology and biotechnology
Tissue engineering devices as in vitro cell culture systems in scaffolds has encountered the bottleneck due to their much lower cell functions than real tissues/organs in vivo. Such situation has been improved in some extent by mimicking the cell microenvironments in vivo from either chemical or physical ways. However, microenvironmental curvature, commonly seen in real tissues/organs, has never been manipulated to regulate the cell performance in vitro. In this regard, this paper fabricated polysulfone membranes with or without polyethylene glycol modification to investigate the impact of curvature on two renal tubular cells. Regardless the varying membrane curvatures among hollow fiber membranes of different diameters and flat membrane of zero curvature, both renal cells could well attach at 4 h of seeding and form similar confluent layers at 6 days on each membrane. Nevertheless, the renal cells on hollow fibers, though showing confluent morphology as those on flat membranes, expressed higher renal functions and, moreover, the renal functions significantly increased with the membrane curvature among hollow fibers. Such upregulation on functions was unassociated with mass transport barrier of hollow fibers, because the cultures on lengthwise cut hollow fibers without mass transfer barrier showed same curvature effect on renal functions as whole hollow fibers. It could be proposed that the curvature of hollow fiber membrane approaching to the large curvature in kidney tubules increased the mechanical stress in the renal cells and thus might up‐regulate the renal cell functions. In conclusion, the increase of substrate curvature could up‐regulate the cell functions without altering the confluent cell morphology and this finding will facilitate the design of functional tissue engineering devices. Biotechnol. Bioeng. 2013; 110: 2173–2183. © 2013 Wiley Periodicals, Inc.