MicroRNAs modulation by isodrimeninol from Drimys winteri in periodontitis-associated cellular models: preliminary results

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datacite.alternateIdentifier.citationApplied Sciences, 15 (10), 5646-5646, 2025
datacite.alternateIdentifier.doi10.3390/app15105646
datacite.alternateIdentifier.issn2076-3417
datacite.creatorCacciuttolo, Carlos
datacite.creatorNavarrete, Martin
datacite.creatorCano, Deyvis
datacite.date2025
datacite.rightsRegistro Bibliográfico
datacite.subjectEnergía renovable
datacite.subjectEnergía eólica terrestre
datacite.subjectEnergía eólica marina
datacite.subjectParque eólico
datacite.subjectHidrógeno verde
datacite.subjectSostenibilidad
datacite.subject.englishRenewable energy
datacite.subject.englishOnshore wind energy
datacite.subject.englishOffshore wind energy
datacite.subject.englishWind farm
datacite.subject.englishGreen hydrogen
datacite.subject.englishSustainability
datacite.titleMicroRNAs modulation by isodrimeninol from Drimys winteri in periodontitis-associated cellular models: preliminary results
dc.date.accessioned2025-08-06T18:22:42Z
dc.date.available2025-08-06T18:22:42Z
dc.description.abstractBrazil has emerged as one of the global leaders in adopting renewable energy, standing out in the implementation of onshore wind energy and, more recently, in the development of future offshore wind energy projects. Onshore wind energy has experienced exponential growth in the last decade, positioning Brazil as one of the countries with the largest installed capacity in the world by 2023, with 30 GW. Wind farms are mainly concentrated in the northeast region, where winds are constant and powerful, enabling efficient and cost-competitive generation. Although in its early stages, offshore wind energy presents significant potential of 1228 GW due to Brazil's extensive coastline, which exceeds 7000 km. Offshore wind projects promise greater generating capacity and stability, as offshore winds are more constant than onshore winds. However, their development faces challenges such as high initial costs, environmental impacts on marine ecosystems, and the need for specialized infrastructure. From a sustainability perspective, this article discusses that both types of wind energy are key to Brazil's energy transition. They reduce dependence on fossil fuels, generate green jobs, and foster technological innovation. However, it is crucial to implement policies that foster synergy with green hydrogen production and minimize socio-environmental impacts, such as impacts on local communities and biodiversity. Finally, the article concludes that by 2050, Brazil is expected to consolidate its leadership in renewable energy by integrating advanced technologies, such as larger, more efficient turbines, energy storage systems, and green hydrogen production. The combination of onshore and offshore wind energy and other renewable sources could position the country as a global model for a clean, sustainable, and resilient energy mix.
dc.identifier.issn2076-3417
dc.identifier.urihttps://repositoriodigital.uct.cl/handle/10925/6509
dc.language.isoen
dc.publisherMultidisciplinary Digital Publishing Institute - MDPI
dc.rightsObra bajo licencia Creative Commons Atribución 4.0 Internacional
dc.rights.licensehttps://creativecommons.org/licenses/by/4.0/
dc.sourceApplied Sciences
dspace.entity.typePublication
oaire.citationEdition2025
oaire.citationEndPage5646
oaire.citationIssue10
oaire.citationStartPage5646
oaire.citationTitleApplied Sciences
oaire.citationVolume15
oaire.fundingReferenceUniversidad Católica de Temuco - UCT
oaire.fundingReferenceDepartamento de Investigación de la Universidad Católica de Temuco - UCT
oaire.resourceTypeArtículo de Revisión
oaire.resourceType.enReview
uct.catalogadorjvu
uct.comunidadIngenieríaen_US
uct.departamentoDepartamento de Obras Civiles y Geología
uct.facultadFacultad de Ingeniería
uct.indizacionScience Citation Index Expanded - SCIE
uct.indizacionSCOPUS
uct.indizacionDOAJ
uct.indizacionWOS
uct.indizacionPubMed
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