Improving hydroxyapatite coating ability on biodegradable metal through laser-induced hydrothermal coating in liquid precursor: Application in orthopedic implants

Authors
Park, Jae hoSeung-Hoon, UmSeo, YoungminLEE JAE HONGKim, Yu ChanOk, Myoung RyulHwang, Suk-WonSun, Jeong-YunHan, Hyung-SeopJeon, Hojeong
Issue Date
2023-07
Publisher
Elsevier
Citation
Bioactive Materials, v.25, pp.796 - 806
Abstract
During the past decade, there has been extensive research toward the possibility of exploring magnesium and its alloys as biocompatible and biodegradable materials for implantable applications. Its practical medical application, however, has been limited to specific areas owing to rapid corrosion in the initial stage and the consequent complications. Surface coatings can significantly reduce the initial corrosion of Mg alloys, and several studies have been carried out to improve the adhesion strength of the coating to the surfaces of the alloys. The composition of hydroxyapatite (HAp) is very similar to that of bone tissue; it is one of the most commonly used coating materials for bone-related implants owing to favorable osseointegration post-implantation. In this study, HAp was coated on Mg using nanosecond laser coating, combining the advantages of chemical and physical treatments. Photothermal heat generated in the liquid precursor by the laser improved the adhesion of the coating through the precipitation and growth of HAp at the localized nanosecond laser focal area and increased the corrosion resistance and cell adhesion of Mg. The physical, crystallographic, and chemical bondings were analyzed to explore the mechanism through which the surface adhesion between Mg and the HAp coating layer increased. The applicability of the coating to Mg screws used for clinical devices and improvement in its corrosion property were confirmed. The liquid environment-based laser surface coating technique offers a simple and quick process that does not require any chemical ligands, and therefore, overcomes a potential obstacle in its clinical use. ? 2022 The Authors
Keywords
TITANIUM; CALCIUM-PHOSPHATE COATINGS; IN-VIVO BIOCOMPATIBILITY; SIMULATED BODY-FLUID; OCTACALCIUM PHOSPHATE; CORROSION BEHAVIOR; MG ALLOY; DEGRADATION BEHAVIOR; MAGNESIUM ALLOYS; VITRO; Biodegradable metal; HAp coating; Nanosecond laser; Photothermal synthesis; Soret effect (thermophoresis)
ISSN
2452-199X
URI
https://pubs.kist.re.kr/handle/201004/79897
DOI
10.1016/j.bioactmat.2022.06.020
Appears in Collections:
KIST Article > 2023
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