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Exploiting the Redox Activity of MIL-100(Fe) Carrier Enables Prolonged Carvacrol Antimicrobial Activity

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Exploiting the Redox Activity of MIL-100(Fe) Carrier Enables Prolonged Carvacrol Antimicrobial Activity

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dc.contributor.author Caamaño Chico, Katia
dc.contributor.author Heras Mozos, Raquel
dc.contributor.author Calbo Roig, Joaquín
dc.contributor.author Cases Díaz, Jesús Antonio
dc.contributor.author Waerenborgh, João C.
dc.contributor.author Vieira, Bruno J. C.
dc.contributor.author Hernández Muñoz, Pilar
dc.contributor.author Gavara Clemente, Rafael José
dc.contributor.author Giménez Marqués, Mónica
dc.date.accessioned 2023-06-13T07:35:44Z
dc.date.available 2023-06-14T04:45:06Z
dc.date.issued 2022 es_ES
dc.identifier.citation Katia Caamaño, Raquel Heras-Mozos, Joaquín Calbo, Jesús Cases Díaz, João C. Waerenborgh, Bruno J. C. Vieira, Pilar Hernández-Muñoz, Rafael Gavara, and Mónica Giménez-Marqués (2022). Exploiting the Redox Activity of MIL-100(Fe) Carrier Enables Prolonged Carvacrol Antimicrobial Activity. ACS Applied Materials & Interfaces, 14 (8), 10758-10768. es_ES
dc.identifier.uri https://hdl.handle.net/10550/87869
dc.description.abstract The design of efficient food contact materials that maintain optimal levels of food safety is of paramount relevance to reduce the increasing number of foodborne illnesses. In this work, we develop a smart composite metal–organic framework (MOF)-based material that fosters a unique prolonged antibacterial activity. The composite is obtained by entrapping a natural food preserving molecule, carvacrol, into a mesoporous MIL-100(Fe) material following a direct and biocompatible impregnation method, and obtaining particularly high payloads. By exploiting the intrinsic redox nature of the MIL-100(Fe) material, it is possible to achieve a prolonged activity against Escherichia coli and Listeria innocua due to a triggered two-step carvacrol release from films containing the carvacrol@MOF composite. Essentially, it was discovered that based on the underlying chemical interaction between MIL-100(Fe) and carvacrol, it is possible to undergo a reversible charge-transfer process between the metallic MOF counterpart and carvacrol upon certain chemical stimuli. During this process, the preferred carvacrol binding site was monitored by infrared, Mössbauer, and electron paramagnetic resonance spectroscopies, and the results are supported by theoretical calculations. es_ES
dc.language.iso en es_ES
dc.publisher ACS es_ES
dc.subject MOFs es_ES
dc.subject controlled delivery es_ES
dc.subject biocomposites es_ES
dc.subject antimicrobial activity es_ES
dc.subject food packaging es_ES
dc.title Exploiting the Redox Activity of MIL-100(Fe) Carrier Enables Prolonged Carvacrol Antimicrobial Activity es_ES
dc.type journal article es_ES
dc.subject.unesco UNESCO::CIENCIAS TECNOLÓGICAS es_ES
dc.identifier.doi 10.1021/acsami.1c21555 es_ES
dc.accrualmethod CI es_ES
dc.embargo.terms 0 days es_ES
dc.type.hasVersion VoR es_ES
dc.rights.accessRights open access es_ES

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