Apoptosis of Multi‐Drug Resistant Candida Species on Microstructured Titanium Surfaces

Phuc H. Le; Denver P. Linklater; Arturo Aburto‐Medina; Shuai Nie; Nicholas A. Williamson; Russell J. Crawford; Shane Maclaughlin; Elena P. Ivanova

doi:10.1002/admi.202300314

Advanced Materials Interfaces (Dec 2023)

Apoptosis of Multi‐Drug Resistant Candida Species on Microstructured Titanium Surfaces

Phuc H. Le,
Denver P. Linklater,
Arturo Aburto‐Medina,
Shuai Nie,
Nicholas A. Williamson,
Russell J. Crawford,
Shane Maclaughlin,
Elena P. Ivanova

Affiliations

Phuc H. Le: School of Science STEM College RMIT University Melbourne VIC 3000 Australia
Denver P. Linklater: ARC Research Hub for Australian Steel Manufacturing Melbourne VIC 3001 Australia
Arturo Aburto‐Medina: School of Science STEM College RMIT University Melbourne VIC 3000 Australia
Shuai Nie: Melbourne Mass Spectrometry and Proteomics Facility Bio21 Molecular Science & Biotechnology Institute The University of Melbourne Melbourne VIC 3010 Australia
Nicholas A. Williamson: Melbourne Mass Spectrometry and Proteomics Facility Bio21 Molecular Science & Biotechnology Institute The University of Melbourne Melbourne VIC 3010 Australia
Russell J. Crawford: School of Science STEM College RMIT University Melbourne VIC 3000 Australia
Shane Maclaughlin: BlueScope Steel Ltd Port Kembla NSW 2505 Australia
Elena P. Ivanova: School of Science STEM College RMIT University Melbourne VIC 3000 Australia

DOI: https://doi.org/10.1002/admi.202300314
Journal volume & issue: Vol. 10, no. 34
pp. n/a – n/a

Abstract

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Abstract The proportion of hospital‐acquired medical device infections caused by pathogenic, multi‐drug resistant Candida species occurs in up to 10% of implantations. In this study, a unique antifungal micro‐pillared titanium surface pattern is developed, which demonstrates both fungicidal and fungistatic activity, persistently deterring biofilm formation by Candida albicans and multi‐drug resistant Candida auris fungi for up to 7 days. The Ti micropillars of 3.5 µm height are fabricated using maskless inductively coupled plasma reactive ion etching. The micro‐textured surface consistently kills ≈50% of Candida spp. irreversibly attached cells and prevent the proliferation of the remaining cells by inducing programmed cell death. Proteomic analysis reveals that Candida cells undergo extensive metabolic stress, preventing the transformation from yeast to the filamentous/hyphal cell phenotype that is essential for establishing a typical in vitro biofilm. The mechanical stress imparted following interaction with the micropillars injures attaching cells and induces apoptosis whereby the Candida cells are unable to be revived in a non‐stress environment. These findings shed new insight toward the design of durable antifungal surfaces that prevent biofilm formation by pathogenic, multi‐drug resistant yeasts.

Published in Advanced Materials Interfaces

ISSN: 2196-7350 (Online)
Publisher: Wiley-VCH
Country of publisher: Germany
LCC subjects: Science: Physics; Technology
Website: https://onlinelibrary.wiley.com/journal/21967350

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