Abstract
The colonization of microorganisms and their subsequent interaction with stone substrates under different environmental conditions encourage deterioration of materials by multiple mechanisms resulting in changes in the original color, appearance and durability. One of the emerging alternatives to remedy biodeterioration is nanotechnology, thanks to nanoparticle properties such as small size, no-toxicity, high photo-reactivity, and low impact on the environment. This study highlighted the effects of ZnO-based nanomaterials of two bacteria genera isolated from the Temple of Concordia (Agrigento’s Valley of the Temples in Sicily, Italy) that are involved in biodeterioration processes. The antimicrobial activities of ZnO-nanorods (Zn-NRs) and graphene nanoplatelets decorated with Zn-NRs (ZNGs) were evaluated against the Gram positive Arthrobacter aurescens and two isolates of the Gram negative Achromobacter spanius. ZNGs demonstrated high antibacterial and antibiofilm activities on several substrates such as stones with different porosity. In the case of ZNGs, a marked time- and dose-dependent bactericidal effect was highlighted against all bacterial species. Therefore, these nanomaterials represent a promising tool for developing biocompatible materials that can be exploited for the conservation of cultural heritage. These nanostructures can be successfully applied without releasing toxic compounds, thus spreading their usability.
Highlights
The biodeterioration process refers to any form of irreversible alteration and any undesirable change in the properties of materials, caused by the activity of living organisms
Antimicrobial and antibiofilm properties of zinc oxide (ZnO)-based nanomaterials were evaluated against two bacterial genera involved in biodeterioration processes
Bacterial survival was evaluated by colonies forming units (CFU) counting analysis after incubation with ZnO nanorods (ZnO-NRs) in liquid assay
Summary
The biodeterioration process refers to any form of irreversible alteration and any undesirable change in the properties of materials, caused by the activity of living organisms. Changes in temperature, humidity, rain, erosion, wind or atmospheric pollution induce the growth of microbial biofilms and the deterioration processes [1,2]. Bacteria biofilm can colonize organic and inorganic materials using them as chemical and energy sources and causing extensive and irreversible damage to artifacts of any type or composition, such as stones, frescoes, books, or canvas [3,4,5]. The type of substrate on which the microorganisms settle, the availability of nutrients, the mineralogical composition, and water permeability [6], often determine the mechanism of biodeterioration
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