Comportamento mecânico da liga Ti-6Al-4V com superfície modificada por laser de femtosegundo para uso biomédico
Abstract
Stainless steel orthopedic implants are still the most widely used in Brazil
due to their lower cost. There is, however, a tendency to expand the use of
special alloys such as titanium-based, due to clinical advantages that they
present, notably the low modulus of elasticity and the best biocompatibility
among the metallic biomaterials. The surface treatments aim to develop
substrates suitable for bone growth, thus preventing the implantation of the
prosthesis with PMMA cement, which results in an efficient mechanical fixing,
but there is no biological interaction between implant and bone. There are
several surface modification techniques, all of them improving at some level the
process of osseointegration. However, researches have focused on biological
aspects of the process and, despite the durability of the implant, there is
currently no objective information in the literature about the influence of surface
treatments on the mechanical behavior under cyclic stresses. The laser surface
modification emerges as a promising alternative, since it permits precise control
of parameters, regular surface development, induces reduced mechanical and
thermal damage, and is known to promote osseointegration. The femtosecond
laser, in particular, allows pulses of short duration (10-15s), reducing even more
the damage caused by heat input. This study evaluated the influence of surface
modification by femtosecond LASER in the fatigue resistance of Ti-6Al-4V alloy
samples. S-N curves were determined for the reference samples and for the
samples with modified surface. The topography developed and the fracture
surfaces were analyzed by scanning electron microscopy. The femtosecond
LASER has developed a regular surface with a bimodal distribution of
microcolumns and ripples, and did not cause severe damage adjacent to the
modified surface, however, has significantly reduced fatigue resistance.