Plastron lifetime of superhydrophobic surfaces submerged in biofluids (poster)

Mohammad Awashra; Seyed Mehran Mirmohammadi; Lingju Meng; Sami Franssila; Ville Jokinen

Plastron lifetime of superhydrophobic surfaces submerged in biofluids (poster)

Mohammad Awashra^*, Seyed Mehran Mirmohammadi, Lingju Meng, Sami Franssila, Ville Jokinen^*

^*Tämän työn vastaava kirjoittaja

Tutkimustuotos: Artikkeli kirjassa/konferenssijulkaisussa › Poster › Scientific › vertaisarvioitu

Abstrakti

Superhydrophobic surfaces find applications in numerous biomedical scenarios
requiring the repulsion of biofluids, biomolecules, and cells. Plastron, an entrapped air film on a superhydrophobic surface submerged in liquid, plays a pivotal role in this repellence. A key challenge is that the sometimes-limited plastron lifetime, which is the time that the fluid spends in contact with the air-solid composite interface before the air is lost and the fluid is then in contact with only a solid. Here we study the plastron lifetime of superhydrophobic surfaces immersed in several types of biofluids (protein solutions, cell media). We found that biofluids of all types had a shorter plastron lifetimes compared to pure water, and this is attributed to their lower surface tension and to biomolecule adsorption through hydrophobic-hydrophobic interactions. Proteins
(albumin and fibronectin) and glucose were found to be the major contributors to
plastron dissipation. We also studied the plastron lifetime of different
superhydrophobic surfaces that vary in terms of texture, feature size, solid fraction, structure height, and surface chemistry. The key findings are that longer term plastron stability and biofluid repellency benefits from a large plastron volume, a higher degree of surface roughness and Cassie solid fraction and smaller size scale.

Alkuperäiskieli	Englanti
Tila	Julkaistu - 18 syysk. 2024
OKM-julkaisutyyppi	Ei sovellu
Tapahtuma	International Conference on Micro- and Nano-Engineering - Le Corum, Montpellier, Ranska Kesto: 16 syysk. 2024 → 19 syysk. 2024 Konferenssinumero: 50 https://mne2024.imnes.org/

Conference

Conference	International Conference on Micro- and Nano-Engineering
Lyhennettä	MNE
Maa/Alue	Ranska
Kaupunki	Montpellier
Ajanjakso	16/09/2024 → 19/09/2024
www-osoite	https://mne2024.imnes.org/

CELLREP: Cell-Repellent Superhydrophobic Surfaces
Jokinen, V. (Vastuullinen tutkija)
01/09/2021 → 31/08/2025
Projekti: RCF Academy Project

Siteeraa tätä

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title = "Plastron lifetime of superhydrophobic surfaces submerged in biofluids (poster)",

abstract = "Superhydrophobic surfaces find applications in numerous biomedical scenariosrequiring the repulsion of biofluids, biomolecules, and cells. Plastron, an entrapped air film on a superhydrophobic surface submerged in liquid, plays a pivotal role in this repellence. A key challenge is that the sometimes-limited plastron lifetime, which is the time that the fluid spends in contact with the air-solid composite interface before the air is lost and the fluid is then in contact with only a solid. Here we study the plastron lifetime of superhydrophobic surfaces immersed in several types of biofluids (protein solutions, cell media). We found that biofluids of all types had a shorter plastron lifetimes compared to pure water, and this is attributed to their lower surface tension and to biomolecule adsorption through hydrophobic-hydrophobic interactions. Proteins(albumin and fibronectin) and glucose were found to be the major contributors toplastron dissipation. We also studied the plastron lifetime of different superhydrophobic surfaces that vary in terms of texture, feature size, solid fraction, structure height, and surface chemistry. The key findings are that longer term plastron stability and biofluid repellency benefits from a large plastron volume, a higher degree of surface roughness and Cassie solid fraction and smaller size scale.",

author = "Mohammad Awashra and Mirmohammadi, {Seyed Mehran} and Lingju Meng and Sami Franssila and Ville Jokinen",

year = "2024",

month = sep,

day = "18",

language = "English",

note = "International Conference on Micro- and Nano-Engineering, MNE ; Conference date: 16-09-2024 Through 19-09-2024",

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TY - CONF

T1 - Plastron lifetime of superhydrophobic surfaces submerged in biofluids (poster)

AU - Awashra, Mohammad

AU - Mirmohammadi, Seyed Mehran

AU - Meng, Lingju

AU - Franssila, Sami

AU - Jokinen, Ville

N1 - Conference code: 50

PY - 2024/9/18

Y1 - 2024/9/18

N2 - Superhydrophobic surfaces find applications in numerous biomedical scenariosrequiring the repulsion of biofluids, biomolecules, and cells. Plastron, an entrapped air film on a superhydrophobic surface submerged in liquid, plays a pivotal role in this repellence. A key challenge is that the sometimes-limited plastron lifetime, which is the time that the fluid spends in contact with the air-solid composite interface before the air is lost and the fluid is then in contact with only a solid. Here we study the plastron lifetime of superhydrophobic surfaces immersed in several types of biofluids (protein solutions, cell media). We found that biofluids of all types had a shorter plastron lifetimes compared to pure water, and this is attributed to their lower surface tension and to biomolecule adsorption through hydrophobic-hydrophobic interactions. Proteins(albumin and fibronectin) and glucose were found to be the major contributors toplastron dissipation. We also studied the plastron lifetime of different superhydrophobic surfaces that vary in terms of texture, feature size, solid fraction, structure height, and surface chemistry. The key findings are that longer term plastron stability and biofluid repellency benefits from a large plastron volume, a higher degree of surface roughness and Cassie solid fraction and smaller size scale.

AB - Superhydrophobic surfaces find applications in numerous biomedical scenariosrequiring the repulsion of biofluids, biomolecules, and cells. Plastron, an entrapped air film on a superhydrophobic surface submerged in liquid, plays a pivotal role in this repellence. A key challenge is that the sometimes-limited plastron lifetime, which is the time that the fluid spends in contact with the air-solid composite interface before the air is lost and the fluid is then in contact with only a solid. Here we study the plastron lifetime of superhydrophobic surfaces immersed in several types of biofluids (protein solutions, cell media). We found that biofluids of all types had a shorter plastron lifetimes compared to pure water, and this is attributed to their lower surface tension and to biomolecule adsorption through hydrophobic-hydrophobic interactions. Proteins(albumin and fibronectin) and glucose were found to be the major contributors toplastron dissipation. We also studied the plastron lifetime of different superhydrophobic surfaces that vary in terms of texture, feature size, solid fraction, structure height, and surface chemistry. The key findings are that longer term plastron stability and biofluid repellency benefits from a large plastron volume, a higher degree of surface roughness and Cassie solid fraction and smaller size scale.

M3 - Poster

T2 - International Conference on Micro- and Nano-Engineering

Y2 - 16 September 2024 through 19 September 2024

ER -

Plastron lifetime of superhydrophobic surfaces submerged in biofluids (poster)

Abstrakti

Conference

Sormenjälki

Projektit

CELLREP: Cell-Repellent Superhydrophobic Surfaces

Siteeraa tätä