Exploring the potential of laser-textured metal alloys: Fine-tuning vascular cells responses through in vitro and ex vivo analysis

Authors
Jun, IndongChoi, HaneulKim, HyeokChoi, Byoung ChanChang, Hye JungKim, YoungjunCho, Sung WooEdwards, James R.Hwang, Suk-WonKim, Yu-ChanHan, Hyung-SeopJeon, Hojeong
Issue Date
2025-01
Publisher
Elsevier
Citation
Bioactive Materials, v.43, pp.181 - 194
Abstract
Medical stents are vital for treating vascular complications and restoring blood flow in millions of patients. Despite its widespread effectiveness, restenosis, driven by the complex interplay of cellular responses, remains a concern. This study investigated the reactions of vascular cells to nano/microscale wrinkle (nano-W and microW) patterns created on laser-textured nitinol (NiTi) surfaces by adjusting laser processing parameters, such as spot overlap ratio and line overlap ratio. Evaluation of topographical effects on endothelial and smooth muscle cells (SMCs) revealed diverse morphologies, proliferation rates, and gene expressions. Notably, microscale wrinkle patterns exhibited reduced monocyte adhesion and inflammation-related gene expression, demonstrating their potential applications in mitigating vascular complications after stent insertion. Additionally, an ex vivo metatarsal assay was utilized to bridge the gap between in vitro and in vivo studies, demonstrating enhanced angiogenesis on laser-textured NiTi surfaces. Laser-textured NiTi exhibits a guided formation process, emphasizing their potential to promote swift endothelialization. These findings underscore the efficacy of laser texturing for tailored cellular interactions on metallic surfaces and offer valuable insights into optimizing biocompatibility and controlling cellular responses, which may pave the way for innovative advances in vascular care and contribute to the ongoing improvement of stent insertion.
Keywords
CARDIOVASCULAR STENT; SURFACE; STRATEGIES; NITINOL; ENDOTHELIALIZATION; MECHANISMS; CHALLENGES; ANATASE; MICRO; Metal alloy; Surface modification; Vascular cells; Ex vivo angiogenesis assays; Laser texturing
URI
https://pubs.kist.re.kr/handle/201004/150883
DOI
10.1016/j.bioactmat.2024.09.019
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KIST Article > Others
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