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Autori principali: Alshammari, Mohammed S, Alamer, Badriah, Alharbi, Mashael M, Alaysuy, Omaymah, Alnoman, Maryam M, Alrefaei, Abdulmajeed F, Sayqal, Ali, El-Metwaly, Nashwa M
Natura: Artículo científico
Lingua:en
Pubblicazione: Journal of materials science. Materials in medicine 2026
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Accesso online:https://pubmed.ncbi.nlm.nih.gov/41845045/
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author Alshammari, Mohammed S
Alamer, Badriah
Alharbi, Mashael M
Alaysuy, Omaymah
Alnoman, Maryam M
Alrefaei, Abdulmajeed F
Sayqal, Ali
El-Metwaly, Nashwa M
author_facet Alshammari, Mohammed S
Alamer, Badriah
Alharbi, Mashael M
Alaysuy, Omaymah
Alnoman, Maryam M
Alrefaei, Abdulmajeed F
Sayqal, Ali
El-Metwaly, Nashwa M
Alshammari, Mohammed S
Alamer, Badriah
Alharbi, Mashael M
Alaysuy, Omaymah
Alnoman, Maryam M
Alrefaei, Abdulmajeed F
Sayqal, Ali
El-Metwaly, Nashwa M
collection PubMed - marine biology
contents Marine algae-derived Ag/AlO and Ag/CoO/AlO nanohybrids: A green approach to phytochemical profiling, molecular docking, and bioactivity assessment. Alshammari, Mohammed S Alamer, Badriah Alharbi, Mashael M Alaysuy, Omaymah Alnoman, Maryam M Alrefaei, Abdulmajeed F Sayqal, Ali El-Metwaly, Nashwa M Molecular Docking Simulation Silver Anti-Bacterial Agents Phytochemicals Antioxidants Aluminum Oxide Sargassum Green Chemistry Technology Nanocomposites Microbial Sensitivity Tests Plant Extracts Green synthesis of Ag/AlO and Ag/CoO/AlO nanohybrids was achieved using Sargassum latifolium extract as a bioreductant. The resulting nanocomposites were thoroughly characterized and exhibited enhanced antioxidant and antibacterial activities. Molecular docking revealed strong binding affinities of key phytochemicals (e.g., naringenin) to bacterial targets. This eco-friendly,marine-algae-based approach offers a sustainable platform for developing multifunctional nanomaterials for biomedical and environmental applications.
format Artículo científico
id pubmed_41845045
institution PubMed
language en
publishDate 2026
publisher Journal of materials science. Materials in medicine
record_format pubmed
spellingShingle Marine algae-derived Ag/AlO and Ag/CoO/AlO nanohybrids: A green approach to phytochemical profiling, molecular docking, and bioactivity assessment.
Alshammari, Mohammed S
Alamer, Badriah
Alharbi, Mashael M
Alaysuy, Omaymah
Alnoman, Maryam M
Alrefaei, Abdulmajeed F
Sayqal, Ali
El-Metwaly, Nashwa M
Molecular Docking Simulation
Silver
Anti-Bacterial Agents
Phytochemicals
Antioxidants
Aluminum Oxide
Sargassum
Green Chemistry Technology
Nanocomposites
Microbial Sensitivity Tests
Plant Extracts
Marine algae-derived Ag/AlO and Ag/CoO/AlO nanohybrids: A green approach to phytochemical profiling, molecular docking, and bioactivity assessment. Alshammari, Mohammed S Alamer, Badriah Alharbi, Mashael M Alaysuy, Omaymah Alnoman, Maryam M Alrefaei, Abdulmajeed F Sayqal, Ali El-Metwaly, Nashwa M Molecular Docking Simulation Silver Anti-Bacterial Agents Phytochemicals Antioxidants Aluminum Oxide Sargassum Green Chemistry Technology Nanocomposites Microbial Sensitivity Tests Plant Extracts Green synthesis of Ag/AlO and Ag/CoO/AlO nanohybrids was achieved using Sargassum latifolium extract as a bioreductant. The resulting nanocomposites were thoroughly characterized and exhibited enhanced antioxidant and antibacterial activities. Molecular docking revealed strong binding affinities of key phytochemicals (e.g., naringenin) to bacterial targets. This eco-friendly,marine-algae-based approach offers a sustainable platform for developing multifunctional nanomaterials for biomedical and environmental applications.
title Marine algae-derived Ag/AlO and Ag/CoO/AlO nanohybrids: A green approach to phytochemical profiling, molecular docking, and bioactivity assessment.
topic Molecular Docking Simulation
Silver
Anti-Bacterial Agents
Phytochemicals
Antioxidants
Aluminum Oxide
Sargassum
Green Chemistry Technology
Nanocomposites
Microbial Sensitivity Tests
Plant Extracts
url https://pubmed.ncbi.nlm.nih.gov/41845045/