Functionalization of poly(lactic acid) scaffold surface by aminolysis and hyaluronan immobilization: How it affects mesenchymal stem cell proliferation

[Display omitted] •HA, a bioactive species, is immobilized on aminolyzed surface of PLA scaffolds.•MSC proliferation is maximal for a low surface concentration of hydrated HA.•MSC proliferation depends on both aminolysis and HA immobilization conditions.•Functionalization conditions affect HA abilit...

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Bibliographic Details
Published in:European polymer journal 2018-10, Vol.107, p.202-217
Main Authors: Monnier, Alexandre, Al Tawil, Elias, Nguyen, Quang Trong, Valleton, Jean-Marc, Fatyeyeva, Kateryna, Deschrevel, Brigitte
Format: Article
Language:English
Subjects:
Aminolysis
Analytical chemistry
Biocompatibility
Biomaterial
Biomedical materials
Chemical Sciences
Glycosaminoglycans
Human tissues
Hyaluronan
Hyaluronic acid
Immobilization
Material chemistry
Mesenchymal stem cells
Natural polymers
Poly(lactic acid) scaffold
Polylactic acid
Polymerization
Polymers
Proteins
Receptors
Scaffolds
Stem cells
Surface functionalization
Tissue engineering
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Summary:[Display omitted] •HA, a bioactive species, is immobilized on aminolyzed surface of PLA scaffolds.•MSC proliferation is maximal for a low surface concentration of hydrated HA.•MSC proliferation depends on both aminolysis and HA immobilization conditions.•Functionalization conditions affect HA ability to interact with membrane receptors. Natural polymers are often used to functionalize the surface of synthetic polymer scaffolds to improve their cytocompatibility for their use as biomaterial for tissue engineering. Here we used hyaluronan (HA), a glycosaminoglycan providing essential functions in human tissues, to functionalize the surface of poly(lactic acid) (PLA) films. PLA was first aminolyzed using hexane-1,6-diamine (HDA) to bring positive charges to the scaffold surface, then allowing HA immobilization by electrostatic interactions. Since HA interact specifically with various proteins, it should be considered as a bioactive species. Thus, we investigated the influence of both aminolysis and HA immobilization conditions on HA immobilization and on mesenchymal stem cells (MSC) proliferation. Results show that (i) there is an optimum in the number of HDA molecules grafted per surface unit to reach the highest surface concentration of hydrated HA, (ii) MSC proliferation is maximal for a low surface concentration of hydrated HA (20–100 ng·cm−2), and (iii) whatever the surface concentration of hydrated HA, the MSC proliferation level depends on aminolysis conditions. We conclude that conditions used for PLA aminolysis and HA immobilization influence MSC proliferation by affecting the organization of HA molecules on scaffold surface and consequently their ability to interact with MSC membrane receptors.
ISSN:0014-3057
1873-1945
DOI:10.1016/j.eurpolymj.2018.08.011