Partial Coated Stem Cells with Bioinspired Silica as New Generation of Cellular Hybrid Materials
authors Maciel, MM; Correia, TR; Gaspar, VM; Rodrigues, JMM; Choi, IS; Mano, JF
nationality International
journal ADVANCED FUNCTIONAL MATERIALS
author keywords advanced cell‐ material interactions; cell partial coatings; cell‐ based materials; organic– inorganic hybrid composites; sol– gel processes
abstract The manipulation of cell surfaces in anchorage-dependent cells can help overcome difficulties presented during cell handling and application. Silica-based protective mechanisms existing in free-floating microorganisms may be used as inspiration for sustaining human cell survival in suspension. Gathering on this, herein human adipose-derived mesenchymal stem cells (hASCs) are partially coated with a hard silica layer that operates as a supporting platform for individual cells in suspension. Inspired by the organic templates involved in biosilicification, a novel chitosan (CHT) derivative displaying fully natural quaternary amine moieties is synthetized via a rapid, one-pot strategy. Silicification is promoted on individual hASCs surfaces via a two-step process: a priming step onto previously adhered cell with this CHT derivative, followed by a biocompatible sol-gel process. hASCs holding a silica backpack exhibit enhanced cell survival in suspension conditions and can spread and acquire a more adherent phenotype. This new protocol for cell-surface modification also provides a new generation of hybrid materials with functionalization of the silica backpack, which can be applied to different areas such as tissue engineering, biosensing, drug delivery, and targeted cell-based therapies.
publisher WILEY-V C H VERLAG GMBH
issn 1616-301X
isbn 1616-3028
year published 2021
volume 31
issue 29
digital object identifier (doi) 10.1002/adfm.202009619
web of science category 9
subject category Chemistry, Multidisciplinary; Chemistry, Physical; Nanoscience & Nanotechnology; Materials Science, Multidisciplinary; Physics, Applied; Physics, Condensed Matter
unique article identifier WOS:000626638700001
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journal analysis (jcr 2019):
journal impact factor 16.836
5 year journal impact factor 15.722
category normalized journal impact factor percentile 95.322
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