This work aims at preparing and characterizing a versatile
multifunctional
platform enabling the immobilization of macromolecules on a titanium
surface by robust covalent grafting. Functionalized titanium is widely
used in the biomedical field to improve its properties. Despite its
high biocompatibility and osteointegrability, titanium implants are
not very stable in the long term due to the onset of inflammation
and bacterial infections. The proposed method allows the superficial
insertion of three different organic linkers to be used as anchors
for the attachment of biopolymers or bioactive molecules. This strategy
used green solvents and is a good alternative to the proposed classic
methods that employ organic solvents. The uniformly modified surfaces
were characterized by micro-Fourier transform infrared spectroscopy
(micro-FTIR), X-ray Photoelectron spectroscopy (XPS) and Near-Edge
X-ray Absorption Fine Structure (NEXAFS). The latter made it possible
to assess the orientation of the linker molecules with respect to
the titanium surface. To test the efficiency of the linkers, two polymers
(alginate and 2-(dimethylamino)-ethyl methacrylate (PDMAEMA)), with
the potential ability to increase biocompatibility, were covalently
attached to the titanium surfaces. The obtained results are a good
starting point for the realization of stable polymeric coatings permanently
bonded to the surface that could be used to extend the life of biomedical
implants.
Despite the significant contribution of titanium and
its alloys
for hard tissue regenerative medicine, some major issues remain to
be solved. Implants’ long-term stability is threatened by poor
osseointegration. Moreover, bacterial adhesion and excessive inflammatory
response are also to be considered in the design of a device intended
to be integrated into the human body. Here, a cerium mixed oxide (CeO
x
) coating was realized on pristine and nanotubular-structured
Ti and Ti6Al4V surfaces using a simple layer-by-layer drop-casting
technique. Bioactivity, resistance in simulated inflammatory conditions,
and bactericidal capacity were evaluated as a function of morphological
surface characteristics combined with the cerium quantity deposited.
The results obtained suggest that the presence of CeO
x
on the surfaces with nanotubes enhanced osseointegration,
while on the non-nanostructured surfaces, this coating improved resistance
under oxidative stress and provided excellent antibacterial properties.
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