Green-assisted tool for nanogold synthesis based on alginate as a biological macromolecule

Large-scale biomedical applications of nanogold reflect the challenge faced by recent researches in the investigation of green synthesis methodologies, which are mostly complicated and/or expensive processes. The present report offers a totally green method using a quite simple and costless techniqu...

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Bibliographic Details
Published in:RSC advances 2016-01, Vol.6 (78), p.73974-73985
Main Authors: Ahmed, Hanan B, Abdel-Mohsen, A. M, Emam, Hossam E
Format: Article
Language:English
Subjects:
Alginates
Biomedical materials
Fragments
Glucose
Macromolecules
Nanostructure
Reduction
Synthesis
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Summary:Large-scale biomedical applications of nanogold reflect the challenge faced by recent researches in the investigation of green synthesis methodologies, which are mostly complicated and/or expensive processes. The present report offers a totally green method using a quite simple and costless technique for the manufacture of Au nanoparticles based on alginate macromolecules. Hydrogen peroxide was used for the oxidative degradation of alginate at room temperature to produce more accessible fragments, beneficial for the reduction of Au ions to Au 0 and as a stabilizer for the produced nanogold. The competence of the mentioned procedure was tested by comparison with the alkali/glucose/alginate system, in which glucose and alginate were used as a reducer and stabilizer, respectively. For both the systems, surface plasmon resonance peaks for nanogold were detected and similar absorbance spectra were observed. Using either 30 mmol L −1 H 2 O 2 or 1 g L −1 glucose, similar reducing sugar content (0.32 g L −1 ) resulted from 1 g L −1 alginate. Nanogold manufactured by H 2 O 2 exhibited smaller size (3.7 ± 1.1) with narrower size distribution (1.5-8.0 nm) than that produced in the case of glucose. However, enlarged nanogold was observed after storage for 5 months, which still maintained the nano dimension. The produced nanogold via the completely green technique using H 2 O 2 /alginate could be safely used in biomedical applications. Large-scale biomedical applications of nanogold reflect the challenge faced by recent researches in the investigation of green synthesis methodologies, which are mostly complicated and/or expensive processes.
ISSN:2046-2069
2046-2069
DOI:10.1039/c6ra16794b