Matija Šavli (Avtor), Manca Černila (Avtor), Maja Caf (Avtor), Abida Zahirović (Avtor), Nika Zaveršek (Avtor), Sebastjan Nemec (Avtor), Spase Stojanov (Avtor), Anja Klančnik (Avtor), Jerica Sabotič (Avtor), Slavko Kralj (Avtor), Aleš Berlec (Avtor)

Povzetek

Bacterial biofilms attach to various surfaces and represent an important clinical and public health problem, as they are highly recalcitrant and are often associated with chronic, nonhealing diseases and healthcare-associated infections. Antibacterial agents are often not sufficient for their elimination and have to be combined with mechanical removal. Mechanical forces can be generated by actuating nonspherical (anisotropic) magnetically responsive nanoparticles in a rotating magnetic field. We have thus prepared anisotropic superparamagnetic nanochains in the size range of 0.5−1 μm by magnetically assembling several iron oxide nanoparticle clusters and coating them with a layer of silica with different shell morphologies: smooth, moderately rough, and highly rough. The silica surface was additionally functionalized with carboxylic groups to increase colloidal stability. The efficacy of the nanochains in biofilm removal was studied systematically with three different model nonpathogenic bacterial species Escherichia coli, Lactococcus lactis, and Pseudomonas fragi; two different magnetic field strengths; two stirring speeds; and two treatment durations. All bacterial species were engineered to express fluorescent proteins to enable quantification of biofilm removal by colony-forming unit count and fluorescence measurements. Nanochains removed >90% of Gram-negative E. coli and P. fragi with a stronger magnetic field, and <90% of Gram-positive L. lactis with a weaker magnetic field. Surface roughness of nanochains, duration, and stirring speed also affected removal, but the effect could not be generalized. In contrast to their effects on biofilms, the functionalized nanochains showed no toxicity to Caco-2 intestinal epithelial cells, regardless of whether magnetomechanical force was employed or not. In summary, we demonstrated that remotely controlled spatial movement of nanoparticles can generate sufficient mechanical forces to disperse attached biofilms while retaining safety in an epithelial cell model.

Ključne besede

bakterijski biofilmi;magnetomehansko odstranjevanje;magnetni nanodelci;vnetna pot IL-23/Th17;bacterial biofilm;magnetomechanical detachment;magnetic nanoparticles;nanochains;iron oxide nanoparticles;bacteria;biofilm removal;

Podatki

Jezik: Angleški jezik
Leto izida:
Tipologija: 1.01 - Izvirni znanstveni članek
Organizacija: IJS - Institut Jožef Stefan
Založnik: ACS Publications
UDK: 60
COBISS: 248232707 Povezava se bo odprla v novem oknu
ISSN: 2576-6422
Št. ogledov: 187
Št. prenosov: 87
Ocena: 0 (0 glasov)
Metapodatki: JSON JSON-RDF JSON-LD TURTLE N-TRIPLES XML RDFA MICRODATA DC-XML DC-RDF RDF

Ostali podatki

Sekundarni jezik: Slovenski jezik
Sekundarne ključne besede: bakterijski biofilmi;magnetomehansko odstranjevanje;magnetni nanodelci;vnetna pot IL-23/Th17;
Komentar vira: Soavtorji: Manca Černila, Maja Caf, Abida Zahirović, Nika Zaveršek, Sebastjan Nemec, Spase Stojanov, Anja Klančnik, Jerica Sabotič, Slavko Kralj, Aleš Berlec; Nasl. z nasl. zaslona; Opis vira z dne 9. 9. 2025;
Strani: str. 8059-8071
Letnik: ǂVol. ǂ8
Zvezek: ǂissue ǂ9
Čas izdaje: 2025
DOI: 10.1021/acsabm.5c01029
ID: 27275063