The ability of mimicking
the extracellular matrix architecture
has gained electrospun scaffolds a prominent space into the tissue
engineering field. The high surface-to-volume aspect ratio of nanofibers
increases their bioactivity while enhancing the bonding strength with
the host tissue. Over the years, numerous polyesters, such as poly(lactic
acid) (PLA), have been consolidated as excellent matrices for biomedical
applications. However, this class of polymers usually has a high hydrophobic
character, which limits cell attachment and proliferation, and therefore
decreases biological interactions. In this way, functionalization
of polyester-based materials is often performed in order to modify
their interfacial free energy and achieve more hydrophilic surfaces.
Herein, we report the preparation, characterization, and
in
vitro
assessment of electrospun PLA fibers with low contents
(0.1 wt %) of different curcuminoids featuring π-conjugated
systems, and a central β-diketone unit, including curcumin itself.
We evaluated the potential of these materials for photochemical and
biomedical purposes. For this, we investigated their optical properties,
water contact angle, and surface features while assessing their
in vitro
behavior using SH-SY5Y cells. Our results demonstrate
the successful generation of homogeneous and defect-free fluorescent
fibers, which are noncytotoxic, exhibit enhanced hydrophilicity, and
as such greater cell adhesion and proliferation toward neuroblastoma
cells. The unexpected tailoring of the scaffolds’ interfacial
free energy has been associated with the strong interactions between
the PLA hydrophobic sites and the nonpolar groups from curcuminoids,
which indicate its role for releasing hydrophilic sites from both
parts. This investigation reveals a straightforward approach to produce
photoluminescent 3D-scaffolds with enhanced biological properties
by using a polymer that is essentially hydrophobic combined with the
low contents of photoactive and multifunctional curcuminoids
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