Detail publikace
In Situ Homogeneous Generation of Copper Nanoparticles in Collagen-Cellulose Freeze-Dried Foams Using Natural Reduction Agents to Enhance Their Stability, Antibacterial Properties, and Cytocompatibility
POLÁKOVÁ, V. MATULOVÁ, J. BRTNÍKOVÁ, J. FOHLEROVÁ, Z. ŠMERKOVÁ, K. KAISER, J. ZIKMUND, T. PROCHÁZKOVÁ, P. ŽÍDEK, J. VOJTOVÁ, L.
Originální název
In Situ Homogeneous Generation of Copper Nanoparticles in Collagen-Cellulose Freeze-Dried Foams Using Natural Reduction Agents to Enhance Their Stability, Antibacterial Properties, and Cytocompatibility
Typ
článek v časopise ve Web of Science, Jimp
Jazyk
angličtina
Originální abstrakt
The treatment of chronic wounds remains a major challenge in regenerative medicine due to prolonged healing times, susceptibility to infection, and underlying conditions like diabetes. Incorporating bioactive and antibacterial nanoparticles (NPs) into wound dressings can significantly enhance their mechanical properties, structural integrity, and functionality, improving stability, biocompatibility, and healing efficacy. However, conventional methods of loading NPs in polymer matrices often lead to uneven distribution and localized toxicity. To overcome these limitations, we employ a novel in situ synthesis of copper nanoparticles (CuNPs) using an encapsulation method via the self-assembled polymerization of dopamine (DOPA) or tannic acid (TA) within collagen/carboxymethyl cellulose (Coll/CMC) 3D freeze-dried scaffolds. When CuNPs are synthesized ex situ, both DOPA and TA act as reducing and encapsulating agents. However, in situ synthesis within Coll/CMC scaffolds results in TA functioning solely as a reducing agent, while DOPA serves both as a reducing agent and, through its polymerization into polydopamine, as a stabilizing agent. The polydopamine network enhances collagen fiber adhesion to CuNPs and stabilizes them via noncovalent interactions. Notably, the DOPA-in situ/Cu sample exhibited prolonged enzymatic stability for up to 7 days. X-ray microcomputed tomography confirmed the homogeneous distribution of CuNPs throughout the scaffold. Biological assays demonstrated the enhanced antibacterial efficacy of DOPA/TA-in situ/Cu samples against Staphylococcus aureus and MRSA, along with cytocompatibility with 3T3 fibroblasts. Future research should explore the in vivo application of these scaffolds and their potential in regenerative medicine for treating infected wounds.
Klíčová slova
Nanoparticles, antibacterial, wound healing, regenerative medicine, collagen scaffolds
Autoři
POLÁKOVÁ, V.; MATULOVÁ, J.; BRTNÍKOVÁ, J.; FOHLEROVÁ, Z.; ŠMERKOVÁ, K.; KAISER, J.; ZIKMUND, T.; PROCHÁZKOVÁ, P.; ŽÍDEK, J.; VOJTOVÁ, L.
Vydáno
28. 7. 2025
Nakladatel
American Chemical Society
ISSN
2470-1343
Periodikum
ACS OMEGA
Ročník
10
Číslo
35
Stát
Spojené státy americké
Strany od
39799
Strany do
39813
Strany počet
15
URL
Plný text v Digitální knihovně
BibTex
@article{BUT198430,
author="Veronika {Poláková} and Jana {Matulová} and Jana {Brtníková} and Zdenka {Fohlerová} and Kristýna {Šmerková} and Jozef {Kaiser} and Tomáš {Zikmund} and Petra {Procházková} and Jan {Žídek} and Lucy {Vojtová}",
title="In Situ Homogeneous Generation of Copper Nanoparticles in Collagen-Cellulose Freeze-Dried Foams Using Natural Reduction Agents to Enhance Their Stability, Antibacterial Properties, and Cytocompatibility",
journal="ACS OMEGA",
year="2025",
volume="10",
number="35",
pages="15",
doi="10.1021/acsomega.5c03661",
issn="2470-1343",
url="https://pubs.acs.org/doi/10.1021/acsomega.5c03661"
}