Laser-Mediated antibacterial effects of Few- and Multi-Layer Ti3C2Tx MXenes

Andreas Rosenkranz; Giordano Perini; Jose Y. Aguilar-Hurtado; Dario F. Zambrano; Bo Wang; Benedetta Niccolini; Patricia C. Henriques; Enrico Di Rosa; Flavio De Maio; Giovanni Delogu; Marco De Spirito; Valentina Palmieri; Massimiliano Papi

doi:10.1016/j.apsusc.2021.150795

Laser-Mediated antibacterial effects of Few- and Multi-Layer Ti3C2Tx MXenes

Andreas Rosenkranz, Giordano Perini, Jose Y. Aguilar-Hurtado, Dario F. Zambrano, Bo Wang, Benedetta Niccolini, Patricia C. Henriques, Enrico Di Rosa, Flavio De Maio, Giovanni Delogu, Marco De Spirito, Valentina Palmieri, Massimiliano Papi^*

^*Autore corrispondente per questo lavoro

Risultato della ricerca: Contributo in rivista › Articolo in rivista › peer review

Abstract

Ti3C2TX nano-sheets (MXenes) with excellent light-conversion capacity have gained importance in treating infectious diseases due to their limited bacterial resistance. In this study, we exploit this property to design photothermal antibacterial therapy using few- (FX) and multi-layer (MX) Ti3C2Tx nano-sheets. We demonstrate that FX have a higher cytocompatibility and conversion of light to heat, but MX show a better efficacy in inhibiting growth of S. aureus and E. coli due to MXenes’ reversible bacteria trapping. For MX (25 µg/mL), □37% of E. coli and □23% of S. aureus cells survived, while the effect was less pronounced for FX with □72% of E. coli and □46% of S. aureus viable cells after treatment. After using 100 µg/mL of MX, □11% of E. coli and □4% of S. aureus survived, while FX had only a mild effect on both species. The NIR laser treatment increased the efficacy of both materials: 100 µg/mL of MX combined with 5 min laser treatment at 5.7 W cm − 2 completely killed both species. For FX, the treatment with 3 W cm − 2 and the highest concentration (100 µg/mL) induced an effect comparable to MX (87% on E. coli, 95% on S.aureus). The combined NIR-MXene treatment causes an irreversible cell death linked to the loss of cell integrity (DNA release quantification and bacteria debris observation).

Lingua originale	English
pagine (da-a)	150795-150803
Numero di pagine	9
Rivista	Applied Surface Science
Volume	2021
DOI	https://doi.org/10.1016/j.apsusc.2021.150795
Stato di pubblicazione	Pubblicato - 2021

Keywords

MXenes
Nanomaterials

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10.1016/j.apsusc.2021.150795

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title = "Laser-Mediated antibacterial effects of Few- and Multi-Layer Ti3C2Tx MXenes",

abstract = "Ti3C2TX nano-sheets (MXenes) with excellent light-conversion capacity have gained importance in treating infectious diseases due to their limited bacterial resistance. In this study, we exploit this property to design photothermal antibacterial therapy using few- (FX) and multi-layer (MX) Ti3C2Tx nano-sheets. We demonstrate that FX have a higher cytocompatibility and conversion of light to heat, but MX show a better efficacy in inhibiting growth of S. aureus and E. coli due to MXenes{\textquoteright} reversible bacteria trapping. For MX (25 µg/mL), □37% of E. coli and □23% of S. aureus cells survived, while the effect was less pronounced for FX with □72% of E. coli and □46% of S. aureus viable cells after treatment. After using 100 µg/mL of MX, □11% of E. coli and □4% of S. aureus survived, while FX had only a mild effect on both species. The NIR laser treatment increased the efficacy of both materials: 100 µg/mL of MX combined with 5 min laser treatment at 5.7 W cm − 2 completely killed both species. For FX, the treatment with 3 W cm − 2 and the highest concentration (100 µg/mL) induced an effect comparable to MX (87% on E. coli, 95% on S.aureus). The combined NIR-MXene treatment causes an irreversible cell death linked to the loss of cell integrity (DNA release quantification and bacteria debris observation).",

keywords = "MXenes, Nanomaterials, MXenes, Nanomaterials",

author = "Andreas Rosenkranz and Giordano Perini and Aguilar-Hurtado, {Jose Y.} and Zambrano, {Dario F.} and Bo Wang and Benedetta Niccolini and Henriques, {Patricia C.} and {Di Rosa}, Enrico and {De Maio}, Flavio and Giovanni Delogu and {De Spirito}, Marco and Valentina Palmieri and Massimiliano Papi",

year = "2021",

doi = "10.1016/j.apsusc.2021.150795",

language = "English",

volume = "2021",

pages = "150795--150803",

journal = "Applied Surface Science",

issn = "0169-4332",

publisher = "Elsevier B.V.",

}

TY - JOUR

T1 - Laser-Mediated antibacterial effects of Few- and Multi-Layer Ti3C2Tx MXenes

AU - Rosenkranz, Andreas

AU - Perini, Giordano

AU - Aguilar-Hurtado, Jose Y.

AU - Zambrano, Dario F.

AU - Wang, Bo

AU - Niccolini, Benedetta

AU - Henriques, Patricia C.

AU - Di Rosa, Enrico

AU - De Maio, Flavio

AU - Delogu, Giovanni

AU - De Spirito, Marco

AU - Palmieri, Valentina

AU - Papi, Massimiliano

PY - 2021

Y1 - 2021

N2 - Ti3C2TX nano-sheets (MXenes) with excellent light-conversion capacity have gained importance in treating infectious diseases due to their limited bacterial resistance. In this study, we exploit this property to design photothermal antibacterial therapy using few- (FX) and multi-layer (MX) Ti3C2Tx nano-sheets. We demonstrate that FX have a higher cytocompatibility and conversion of light to heat, but MX show a better efficacy in inhibiting growth of S. aureus and E. coli due to MXenes’ reversible bacteria trapping. For MX (25 µg/mL), □37% of E. coli and □23% of S. aureus cells survived, while the effect was less pronounced for FX with □72% of E. coli and □46% of S. aureus viable cells after treatment. After using 100 µg/mL of MX, □11% of E. coli and □4% of S. aureus survived, while FX had only a mild effect on both species. The NIR laser treatment increased the efficacy of both materials: 100 µg/mL of MX combined with 5 min laser treatment at 5.7 W cm − 2 completely killed both species. For FX, the treatment with 3 W cm − 2 and the highest concentration (100 µg/mL) induced an effect comparable to MX (87% on E. coli, 95% on S.aureus). The combined NIR-MXene treatment causes an irreversible cell death linked to the loss of cell integrity (DNA release quantification and bacteria debris observation).

AB - Ti3C2TX nano-sheets (MXenes) with excellent light-conversion capacity have gained importance in treating infectious diseases due to their limited bacterial resistance. In this study, we exploit this property to design photothermal antibacterial therapy using few- (FX) and multi-layer (MX) Ti3C2Tx nano-sheets. We demonstrate that FX have a higher cytocompatibility and conversion of light to heat, but MX show a better efficacy in inhibiting growth of S. aureus and E. coli due to MXenes’ reversible bacteria trapping. For MX (25 µg/mL), □37% of E. coli and □23% of S. aureus cells survived, while the effect was less pronounced for FX with □72% of E. coli and □46% of S. aureus viable cells after treatment. After using 100 µg/mL of MX, □11% of E. coli and □4% of S. aureus survived, while FX had only a mild effect on both species. The NIR laser treatment increased the efficacy of both materials: 100 µg/mL of MX combined with 5 min laser treatment at 5.7 W cm − 2 completely killed both species. For FX, the treatment with 3 W cm − 2 and the highest concentration (100 µg/mL) induced an effect comparable to MX (87% on E. coli, 95% on S.aureus). The combined NIR-MXene treatment causes an irreversible cell death linked to the loss of cell integrity (DNA release quantification and bacteria debris observation).

KW - MXenes

KW - Nanomaterials

KW - MXenes

KW - Nanomaterials

UR - http://hdl.handle.net/10807/200343

U2 - 10.1016/j.apsusc.2021.150795

DO - 10.1016/j.apsusc.2021.150795

M3 - Article

SN - 0169-4332

VL - 2021

SP - 150795

EP - 150803

JO - Applied Surface Science

JF - Applied Surface Science

ER -

Laser-Mediated antibacterial effects of Few- and Multi-Layer Ti3C2Tx MXenes

Abstract

Keywords

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