Thin coatings of biomaterials for hard tissue applications
Abstract
The goal of the present study is the production of new-generation coatings suitable for hard
tissue implants, intended to decrease the healing time, limit infections and rejections and
improve patients' life quality.
Materials designed for implant coatings are mainly bioactive ceramics. Belonging to this class of
biomaterials, hydroxyapatite (HAp), bioglass (BG) and glass-ceramic (BGC) are indicated for
application in hard tissue replacement and regeneration. However the use of each one has
strengths and weaknesses; therefore the attention has been focused on their peculiarity in the
coating of metallic materials, suitable for hard tissue replacement. In particular, in order to
overcome their drawback and enhance their strengths, possible solutions, like the adding of
helpful component in the basic material or the choice of composites, have been investigated.
The main technique used for the coatings production has been the Pulsed Laser Deposition
(PLD). Furthermore the Electrophoretic Deposition (EPD) has been performed to produce
composite biopolymer/bioceramic coatings, which cannot be accomplished by the conventional
PLD.
Hydroxyapatite has been deposited with IONPs (iron oxide nanoparticles). The IONPs have been
previously obtained by the means of a really "green" technique, the PLAL (pulsed laser ablation
in liquid). The obtaining of HAp/IONPs films has demonstrated how PLD is a successful
deposition technique for the production of magnetic composite coatings.
BG_Cu films have been also successfully deposited trough PLD and their bioactivity has been
demonstrated by the hydroxyapatite growth on their surface during the soaking in simulated
body fluid (SBF). The use of electrophoretic deposition (EPD) has allowed the coating of SS
substrate with polymer/bioglass composite films. Also in this case a Cu-doped bioaglass has
been used together with a protein-based polymer, zein, and the films bioactivity has been proved.
RKKP (glass-ceramic) pulsed laser deposited has been proved functional coatings for celldelivery
implantation and for the reduction of the corrosion of biodegradable implant. Although
glass-ceramics show superior mechanical properties than bioglasses, they are still not enough for
load-bearing application. Therefore, RKKP&C60 has been used as target for the deposition of
composite films with improved hardness.
Finally, RKKP has been modified by the adding of another component, manganese, useful
for the bone regeneration, and its biocompatibility has been proved. [edited by author]