Metal nanoparticles synthesis through natural phenolic acids

For being applied in medicine as therapeutic agents, nanostructures need to be biocompatible and eco-friendly. Plant-derived phenolic acids have been utilised for green synthesis of metallic or metallic oxide nanoparticles (NPs). The phenolic acids play role as both reducing agents and stabilisers i...

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Published in	IET nanobiotechnology Vol. 13; no. 8; pp. 771 - 777
Main Authors	Amini, Seyed Mohammad, Akbari, Abolfazl
Format	Journal Article
Language	English
Published	United States The Institution of Engineering and Technology 01.10.2019 John Wiley & Sons, Inc Wiley
Subjects	adsorption Amino acids Antioxidants Antioxidants - chemical synthesis Antioxidants - pharmacology biomedical applications biomedical materials bio‐inspired materials efficient green synthesis techniques Green Chemistry Technology - methods Health aspects Humans Hydroxybenzoates - pharmacology medicine metal ion bioreduction Metal Nanoparticles - chemistry metal nanoparticles synthesis metallic oxide nanoparticles nanofabrication nanomaterial synthesis nanomedicine Nanoparticles natural phenolic acids organic compounds phenolic acids surface adsorption phytochemical synthesis Plant Extracts - pharmacology plant‐derived phenolic acids reducing agents Review Review Article therapeutic agents toxicity Type 2 diabetes toxicity adsorption antioxidants reducing agents natural phenolic acids metal nanoparticles synthesis nanomaterial synthesis nanofabrication nanomedicine metallic oxide nanoparticles plant-derived phenolic acids medicine therapeutic agents efficient green synthesis techniques bio-inspired materials nanoparticles metal ion bioreduction biomedical applications biomedical materials organic compounds phytochemical synthesis phenolic acids surface adsorption
Online Access	Get full text
ISSN	1751-8741 1751-875X 1751-875X
DOI	10.1049/iet-nbt.2018.5386

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Abstract	For being applied in medicine as therapeutic agents, nanostructures need to be biocompatible and eco-friendly. Plant-derived phenolic acids have been utilised for green synthesis of metallic or metallic oxide nanoparticles (NPs). The phenolic acids play role as both reducing agents and stabilisers in the process of NPs synthesis. Many experiments have been dedicated to develop efficient green synthesis techniques for producing metal NPs. Using phenolic acids represents a reproducible, simple, profitable, and cost-effective strategy to synthesise metal NPs. As a phytochemical for metal NPs synthesis, phenolic acids are antioxidants that represent many health benefits. However, limited studies have been dedicated to the synthesis and characterisation of NPs produced by phenolic acids. Thus, this review focused on phenolic acids mediated nanomaterial synthesis and its biomedical applications. It should be noted the mechanism of metal ion bioreduction, phenolic acids surface adsorption, characterisation, and toxicity of metal NPs made with different phenolic acids have been discussed in this review.
AbstractList	For being applied in medicine as therapeutic agents, nanostructures need to be biocompatible and eco‐friendly. Plant‐derived phenolic acids have been utilised for green synthesis of metallic or metallic oxide nanoparticles (NPs). The phenolic acids play role as both reducing agents and stabilisers in the process of NPs synthesis. Many experiments have been dedicated to develop efficient green synthesis techniques for producing metal NPs. Using phenolic acids represents a reproducible, simple, profitable, and cost‐effective strategy to synthesise metal NPs. As a phytochemical for metal NPs synthesis, phenolic acids are antioxidants that represent many health benefits. However, limited studies have been dedicated to the synthesis and characterisation of NPs produced by phenolic acids. Thus, this review focused on phenolic acids mediated nanomaterial synthesis and its biomedical applications. It should be noted the mechanism of metal ion bioreduction, phenolic acids surface adsorption, characterisation, and toxicity of metal NPs made with different phenolic acids have been discussed in this review. For being applied in medicine as therapeutic agents, nanostructures need to be biocompatible and eco-friendly. Plant-derived phenolic acids have been utilised for green synthesis of metallic or metallic oxide nanoparticles (NPs). The phenolic acids play role as both reducing agents and stabilisers in the process of NPs synthesis. Many experiments have been dedicated to develop efficient green synthesis techniques for producing metal NPs. Using phenolic acids represents a reproducible, simple, profitable, and cost-effective strategy to synthesise metal NPs. As a phytochemical for metal NPs synthesis, phenolic acids are antioxidants that represent many health benefits. However, limited studies have been dedicated to the synthesis and characterisation of NPs produced by phenolic acids. Thus, this review focused on phenolic acids mediated nanomaterial synthesis and its biomedical applications. It should be noted the mechanism of metal ion bioreduction, phenolic acids surface adsorption, characterisation, and toxicity of metal NPs made with different phenolic acids have been discussed in this review.For being applied in medicine as therapeutic agents, nanostructures need to be biocompatible and eco-friendly. Plant-derived phenolic acids have been utilised for green synthesis of metallic or metallic oxide nanoparticles (NPs). The phenolic acids play role as both reducing agents and stabilisers in the process of NPs synthesis. Many experiments have been dedicated to develop efficient green synthesis techniques for producing metal NPs. Using phenolic acids represents a reproducible, simple, profitable, and cost-effective strategy to synthesise metal NPs. As a phytochemical for metal NPs synthesis, phenolic acids are antioxidants that represent many health benefits. However, limited studies have been dedicated to the synthesis and characterisation of NPs produced by phenolic acids. Thus, this review focused on phenolic acids mediated nanomaterial synthesis and its biomedical applications. It should be noted the mechanism of metal ion bioreduction, phenolic acids surface adsorption, characterisation, and toxicity of metal NPs made with different phenolic acids have been discussed in this review.
Audience	Academic
Author	Amini, Seyed Mohammad Akbari, Abolfazl
AuthorAffiliation	2 Colorectal Research Center Iran University of Medical Sciences Tehran Iran 1 Radiation Biology Research Center Iran University of Medical Sciences Tehran Iran
AuthorAffiliation_xml	– name: 2 Colorectal Research Center Iran University of Medical Sciences Tehran Iran – name: 1 Radiation Biology Research Center Iran University of Medical Sciences Tehran Iran
Author_xml	– sequence: 1 givenname: Seyed Mohammad orcidid: 0000-0001-6447-9872 surname: Amini fullname: Amini, Seyed Mohammad email: Amini.sm@iums.ac.ir organization: 1Radiation Biology Research Center, Iran University of Medical Sciences, Tehran, Iran – sequence: 2 givenname: Abolfazl surname: Akbari fullname: Akbari, Abolfazl organization: 2Colorectal Research Center, Iran University of Medical Sciences, Tehran, Iran
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/31625516$$D View this record in MEDLINE/PubMed
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Keywords	toxicity adsorption antioxidants reducing agents natural phenolic acids metal nanoparticles synthesis nanomaterial synthesis nanofabrication nanomedicine metallic oxide nanoparticles plant-derived phenolic acids medicine therapeutic agents efficient green synthesis techniques bio-inspired materials nanoparticles metal ion bioreduction biomedical applications biomedical materials organic compounds phytochemical synthesis phenolic acids surface adsorption
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Snippet	For being applied in medicine as therapeutic agents, nanostructures need to be biocompatible and eco-friendly. Plant-derived phenolic acids have been utilised... For being applied in medicine as therapeutic agents, nanostructures need to be biocompatible and eco‐friendly. Plant‐derived phenolic acids have been utilised...
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SubjectTerms	adsorption Amino acids Antioxidants Antioxidants - chemical synthesis Antioxidants - pharmacology biomedical applications biomedical materials bio‐inspired materials efficient green synthesis techniques Green Chemistry Technology - methods Health aspects Humans Hydroxybenzoates - pharmacology medicine metal ion bioreduction Metal Nanoparticles - chemistry metal nanoparticles synthesis metallic oxide nanoparticles nanofabrication nanomaterial synthesis nanomedicine Nanoparticles natural phenolic acids organic compounds phenolic acids surface adsorption phytochemical synthesis Plant Extracts - pharmacology plant‐derived phenolic acids reducing agents Review Review Article therapeutic agents toxicity Type 2 diabetes
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Title	Metal nanoparticles synthesis through natural phenolic acids
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