Publication detail

Effect of Surface Texturing on Friction and Lubrication of Ti6Al4V Biomaterials for Joint Implants

RANUŠA, M. ODEHNAL, L. KUČERA, O. NEČAS, D. HARTL, M. KŘUPKA, I. VRBKA, M.

English title

Effect of Surface Texturing on Friction and Lubrication of Ti6Al4V Biomaterials for Joint Implants

Type

journal article in Web of Science

Language

en

Original abstract

The number of endoprosthetic implants for both large and small joints is increasing at a steady rate, thereby creating a growing demand for durable products that closely replicate the functionality of human joints. Notwithstanding the aforementioned advancements, challenges pertaining to implant fixation and tribological surfaces persist. The advent of progressive technologies, such as three-dimensional printing, offers a promising avenue for addressing these challenges in implant design and surface engineering. The Ti6Al4V and CoCrMo alloys, renowned for their biocompatibility and osseointegration properties, represent promising printable materials, although they are susceptible to wear on articulating surfaces. In order to mitigate the effects of abrasion, it is essential to implement surface treatments to facilitate the formation of a robust lubricating film. This research investigates the potential of texturing and electrochemical polishing to enhance protein aggregation in the contact area. The study employs a reciprocating simulator and colorimetric interferometry to observe the contact area and measure the coefficient of friction (CoF) of modified surfaces. The findings demonstrate that textured surfaces and the combination of electrochemical polishing result in an increase in the thickness of the protein lubrication film, which may potentially reduce wear. These outcomes suggest the potential for the utilization of Ti6Al4V alloy implants with fewer elements manufactured by additive technology.

English abstract

The number of endoprosthetic implants for both large and small joints is increasing at a steady rate, thereby creating a growing demand for durable products that closely replicate the functionality of human joints. Notwithstanding the aforementioned advancements, challenges pertaining to implant fixation and tribological surfaces persist. The advent of progressive technologies, such as three-dimensional printing, offers a promising avenue for addressing these challenges in implant design and surface engineering. The Ti6Al4V and CoCrMo alloys, renowned for their biocompatibility and osseointegration properties, represent promising printable materials, although they are susceptible to wear on articulating surfaces. In order to mitigate the effects of abrasion, it is essential to implement surface treatments to facilitate the formation of a robust lubricating film. This research investigates the potential of texturing and electrochemical polishing to enhance protein aggregation in the contact area. The study employs a reciprocating simulator and colorimetric interferometry to observe the contact area and measure the coefficient of friction (CoF) of modified surfaces. The findings demonstrate that textured surfaces and the combination of electrochemical polishing result in an increase in the thickness of the protein lubrication film, which may potentially reduce wear. These outcomes suggest the potential for the utilization of Ti6Al4V alloy implants with fewer elements manufactured by additive technology.

Keywords in English

Ti6Al4V; Micro-texture; Implant; Optical interferometry; Friction; Film thickness

Released

01.03.2025

Publisher

Springer Nature

Location

NEW YORK

ISSN

1023-8883

Volume

73

Number

1

Pages from–to

1–18

Pages count

18

BIBTEX


@article{BUT196773,
  author="Matúš {Ranuša} and Lukáš {Odehnal} and Ondřej {Kučera} and David {Nečas} and Martin {Hartl} and Ivan {Křupka} and Martin {Vrbka},
  title="Effect of Surface Texturing on Friction and Lubrication of Ti6Al4V Biomaterials for Joint Implants",
  year="2025",
  volume="73",
  number="1",
  month="March",
  pages="1--18",
  publisher="Springer Nature",
  address="NEW YORK",
  issn="1023-8883"
}