posted on 2016-06-01, 00:00authored byDan Kai, Wei Ren, Lingling Tian, Pei Lin Chee, Ye Liu, Seeram Ramakrishna, Xian Jun Loh
Biodegradable
poly(lactic acid) (PLA)–lignin composites are considered to
be promising renewable plastic materials toward a sustainable world.
The addition of lignin to PLA may assist to combat the oxidative stress
induced by PLA as biomaterials. In this study, PLA–lignin copolymers
with various contents of alkylated lignin (10–50%) were synthesized
by ring-opening polymerization. The molecular weight of such copolymers
ranged from 28 to 75 kDa, while the PLA chain length varied from 5
to 38. These PLA–lignin copolymers were further blended with
poly(l-lactide) (PLLA) and fabricated into nanofibrous composites
by electrospinning. The PLLA/PLA–lignin nanofibers displayed
uniform and bead-free nanostructures with fiber diameter of 350–500
nm, indicating the miscibility of PLLA and lignin copolymers in nanoscale.
Unlike bulk materials, incorporation of PLA–lignin copolymers
did not enhance the mechanical properties of the nanofibrous composites.
Antioxidant assay showed that the lignin copolymers and PLLA/PLA–lignin
nanofibers rendered excellent radical scavenging capacity for over
72 h. Moreover, three different types of cells (PC12, human dermal
fibroblasts, and human mesenchymal stem cells) were cultured on the
electrospun nanofibers to evaluate their biocompatibility. Lignin-containing
nanofibers exhibited higher cell proliferation compared to neat PLLA
nanofibers. PLLA/PLA-Lig20 nanofibers displayed the best biocompatibility
as it achieved a balance between the antioxidant activities and the
cytotoxicity. With excellent antioxidant activities and good biocompatibility,
the PLLA/PLA–lignin electrospun nanofibers hold great potential
to be used as biomedical materials for protecting cells from oxidative
stress conditions.