Picosecond laser induced hybrid groove structures on Ti6Al4V bio-alloy to accelerate osseointegration

TL;DR

This study demonstrates that picosecond laser-induced hybrid groove structures on Ti6Al4V bio-alloy significantly enhance cell growth, protein adsorption, and hydroxyapatite formation, potentially improving implant integration.

Contribution

It introduces novel hybrid groove structures created by picosecond laser processing that improve bioactivity and cell growth on Ti6Al4V implants.

Findings

3-fold increase in hydroxyapatite growth rate

2.5-fold increase in protein adsorption

2-fold enhancement in cell adhesion

Abstract

Regulating cell growth, extracellular matrix deposition and mineralization of artificial implants are some important parameters that decide the longevity of implants in the body. Picosecond laser induced hybrid groove structures have been shown to improve these properties of the Ti6Al4V bio-alloy. Two hybrid structures containing groove patterns with periodic and non-periodic substructures therein were generated on Ti6Al4V by varying the extent of laser pulse overlapping on sample surface. Laser induced alteration in surface topography, chemical composition and wettability of Ti6Al4V resulted in 3-fold increase in the rate of hydroxyapatite growth, 2.5-fold increment in protein adsorption and 2-fold enhancement in cell adhesion in comparison to pristine sample. While the periodic substructure was found to guide cell growth, the non periodic sub structure offered homogenous growth leading to higher overall cell density on the substrate surface.