Slippery liquid-like solid surfaces with promising antibiofilm performance in both static and flow conditions
Slippery liquid-like solid surfaces with promising antibiofilm performance in both static and flow conditions
Biofilms are central to some of the most urgent global challenges across diverse fields of application, from medicine to industries to the environment, and exert considerable economic and social impact. A fundamental assumption in anti-biofilms has been that the coating on a substrate surface is solid. The invention of slippery liquid-infused porous surfaces-a continuously wet lubricating coating retained on a solid surface by capillary forces-has led to this being challenged. However, in situations where flow occurs, shear stress may deplete the lubricant and affect the anti-biofilm performance. Here, we report on the use of slippery omniphobic covalently attached liquid (SOCAL) surfaces, which provide a surface coating with short (ca. 4 nm) non-cross-linked polydimethylsiloxane (PDMS) chains retaining liquid-surface properties, as an antibiofilm strategy stable under shear stress from flow. This surface reduced biofilm formation of the key biofilm-forming pathogens Staphylococcus epidermidis and Pseudomonas aeruginosa by three-four orders of magnitude compared to the widely used medical implant material PDMS after 7 days under static and dynamic culture conditions. Throughout the entire dynamic culture period of P. aeruginosa, SOCAL significantly outperformed a typical antibiofilm slippery surface [i.e., swollen PDMS in silicone oil (S-PDMS)]. We have revealed that significant oil loss occurred after 2-7 day flow for S-PDMS, which correlated to increased contact angle hysteresis (CAH), indicating a degradation of the slippery surface properties, and biofilm formation, while SOCAL has stable CAH and sustainable antibiofilm performance after 7 day flow. The significance of this correlation is to provide a useful easy-to-measure physical parameter as an indicator for long-term antibiofilm performance. This biofilm-resistant liquid-like solid surface offers a new antibiofilm strategy for applications in medical devices and other areas where biofilm development is problematic.
Antibiofilm, Biofilm detachment, Liquid-like surface, Slippery polymer surfaces, Surface wetting, liquid-like surface, slippery polymer surfaces, antibiofilm, surface wetting, biofilm detachment
6307–6319
Zhu, Yufeng
f23edd69-0069-4e3e-a6e2-e5f8cf87f86a
McHale, Glen
8f4a9960-c9ac-4754-b219-40ce3a45c65e
Dawson, Jack M.S.
3b57eb78-4e38-4b6e-ae4c-9c9df5310ff5
Armstrong, Steven
784e199c-bb5c-4024-9c01-43a177bc6282
Wells, Gary
de5c7552-ce46-4c28-b764-76da94b129c9
Han, Rui
57af6baf-6a3b-40f7-ae28-db89cd3575f8
Liu, Hongzhong
4506dbea-b61a-41f2-b6f4-10bde2e34852
Vollmer, Waldemar
9e7142d0-635f-43da-a483-de7fb7e9669a
Stoodley, Paul
08614665-92a9-4466-806e-20c6daeb483f
Jakubovics, Nicholas
7311a551-3274-4a24-948f-aa54e2080e6d
Chen, Jinju
105a3320-0a27-49fc-83c5-9c07e89b506c
9 February 2022
Zhu, Yufeng
f23edd69-0069-4e3e-a6e2-e5f8cf87f86a
McHale, Glen
8f4a9960-c9ac-4754-b219-40ce3a45c65e
Dawson, Jack M.S.
3b57eb78-4e38-4b6e-ae4c-9c9df5310ff5
Armstrong, Steven
784e199c-bb5c-4024-9c01-43a177bc6282
Wells, Gary
de5c7552-ce46-4c28-b764-76da94b129c9
Han, Rui
57af6baf-6a3b-40f7-ae28-db89cd3575f8
Liu, Hongzhong
4506dbea-b61a-41f2-b6f4-10bde2e34852
Vollmer, Waldemar
9e7142d0-635f-43da-a483-de7fb7e9669a
Stoodley, Paul
08614665-92a9-4466-806e-20c6daeb483f
Jakubovics, Nicholas
7311a551-3274-4a24-948f-aa54e2080e6d
Chen, Jinju
105a3320-0a27-49fc-83c5-9c07e89b506c
Zhu, Yufeng, McHale, Glen, Dawson, Jack M.S., Armstrong, Steven, Wells, Gary, Han, Rui, Liu, Hongzhong, Vollmer, Waldemar, Stoodley, Paul, Jakubovics, Nicholas and Chen, Jinju
(2022)
Slippery liquid-like solid surfaces with promising antibiofilm performance in both static and flow conditions.
ACS Applied Materials and Interfaces, 14 (5), .
(doi:10.1021/acsami.1c14533).
Abstract
Biofilms are central to some of the most urgent global challenges across diverse fields of application, from medicine to industries to the environment, and exert considerable economic and social impact. A fundamental assumption in anti-biofilms has been that the coating on a substrate surface is solid. The invention of slippery liquid-infused porous surfaces-a continuously wet lubricating coating retained on a solid surface by capillary forces-has led to this being challenged. However, in situations where flow occurs, shear stress may deplete the lubricant and affect the anti-biofilm performance. Here, we report on the use of slippery omniphobic covalently attached liquid (SOCAL) surfaces, which provide a surface coating with short (ca. 4 nm) non-cross-linked polydimethylsiloxane (PDMS) chains retaining liquid-surface properties, as an antibiofilm strategy stable under shear stress from flow. This surface reduced biofilm formation of the key biofilm-forming pathogens Staphylococcus epidermidis and Pseudomonas aeruginosa by three-four orders of magnitude compared to the widely used medical implant material PDMS after 7 days under static and dynamic culture conditions. Throughout the entire dynamic culture period of P. aeruginosa, SOCAL significantly outperformed a typical antibiofilm slippery surface [i.e., swollen PDMS in silicone oil (S-PDMS)]. We have revealed that significant oil loss occurred after 2-7 day flow for S-PDMS, which correlated to increased contact angle hysteresis (CAH), indicating a degradation of the slippery surface properties, and biofilm formation, while SOCAL has stable CAH and sustainable antibiofilm performance after 7 day flow. The significance of this correlation is to provide a useful easy-to-measure physical parameter as an indicator for long-term antibiofilm performance. This biofilm-resistant liquid-like solid surface offers a new antibiofilm strategy for applications in medical devices and other areas where biofilm development is problematic.
Text
SOCAL Paper _non_marked_manuscript
- Accepted Manuscript
More information
Accepted/In Press date: 19 January 2022
e-pub ahead of print date: 31 January 2022
Published date: 9 February 2022
Additional Information:
Funding Information:
We thank Dr. Rolando Berlinguer-Palmini Dr. Alex Laude, Ross Laws, and Tracey Davey for technical support of imaging. We also acknowledge the technical assistance from Dave Race, Ekaterina Kozhevnikova, and Dr. Nadia Rostami. We also acknowledge Dr. George Roberts and Prof. Anthony O'Neill for technical support on ellipsometry. We also acknowledge Prof. Lidija Siller at NEXUS, Newcastle University, for the XPS measurements.
Publisher Copyright:
© 2022 American Chemical Society.
Keywords:
Antibiofilm, Biofilm detachment, Liquid-like surface, Slippery polymer surfaces, Surface wetting, liquid-like surface, slippery polymer surfaces, antibiofilm, surface wetting, biofilm detachment
Identifiers
Local EPrints ID: 454420
URI: http://eprints.soton.ac.uk/id/eprint/454420
ISSN: 1944-8244
PURE UUID: 23ea7172-f4e9-4054-bbfc-93531d2c4ff4
Catalogue record
Date deposited: 09 Feb 2022 17:34
Last modified: 12 Nov 2024 05:02
Export record
Altmetrics
Contributors
Author:
Yufeng Zhu
Author:
Glen McHale
Author:
Jack M.S. Dawson
Author:
Steven Armstrong
Author:
Gary Wells
Author:
Rui Han
Author:
Hongzhong Liu
Author:
Waldemar Vollmer
Author:
Nicholas Jakubovics
Author:
Jinju Chen
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics