Synthesis of near-infrared absorbing triangular Au nanoplates using biomineralisation peptides

[Display omitted] Triangular Au nanoplates (TrAuNPls) possessing strong plasmonic properties can be used as photothermal agents in cancer therapy. However, the controlled preparation of such morphologies typically requires harsh synthetic conditions. Biomolecules offer an alternative route to develo...

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Bibliographic Details
Published in:Acta biomaterialia 2021-09, Vol.131, p.519-531
Main Authors: Tanaka, Masayoshi, Hayashi, Mirei, Roach, Lucien, Kiriki, Yuka, Kadonosono, Tetsuya, Nomoto, Takahiro, Nishiyama, Nobuhiro, Choi, Jonghoon, Critchley, Kevin, Evans, Stephen D., Okochi, Mina
Format: Article
Language:English
Subjects:
Amino acids
Biocompatibility
Biomolecules
Cancer
Cancer therapies
Chemical compounds
Gold
Gold nanoparticle
Histidine
I.R. radiation
Mineralisation peptide
Morphology
Nanoparticles
Near infrared radiation
Peptides
Pharmacology
Phototherapy
Photothermal therapy
Reagents
Room temperature
Synthesis
Triangular nanoplate
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Summary:[Display omitted] Triangular Au nanoplates (TrAuNPls) possessing strong plasmonic properties can be used as photothermal agents in cancer therapy. However, the controlled preparation of such morphologies typically requires harsh synthetic conditions. Biomolecules offer an alternative route to developing biocompatible synthetic protocols. In particular, peptides offer a novel route for inorganic synthesis under ambient conditions. Herein, using the previously isolated peptide, ASHQWAWKWE, for Au nanoparticle (AuNP) synthesis, the conditions for preparing TrAuNPls via a one-pot synthetic process of mixing HAuCl4 and peptides at room temperature were investigated to effectively obtain particles possessing near-infrared absorbance for non-invasive optical diagnosis and phototherapy. By adjusting the peptide concentration, the size and property of TrAuNPls were controlled under neutral pH conditions. The synthesised particles showed potential as photothermal therapeutic agents in vitro. In addition, peptide characterisation using B3 derivatives revealed the importance of the third amino acid histidine in morphological regulation and potential circular Au nanoplates (AuNPl) synthesis with ASEQWAWKWE and ASAQWAWKWE peptides. These findings provide not only an easy and green synthetic method for TrAuNPls and circular AuNPls, but also some insight to help elucidate the regulation of peptide-based nanoparticle synthesis for use in cancer therapy. Biological molecules have received increasing attention as a vehicle to synthesise inorganic materials with specific properties under ambient conditions; particularly, short peptides have the potential to control the synthesis of nanoscale materials with tailored functions. Here, the application of a previously isolated peptide was assessed in synthesising Au nanoparticles containing decahedral and triangular nanoplates with near-infrared absorbance. The size and absorbance peaks of the triangular nanoplates observed were peptide concentration-dependent. In addition, these fine-tuned triangular nanoplates exhibited potential as a phototherapeutic agent. Moreover, the peptide derivatives indicated the possibility of synthesising circular nanoplates. These findings may offer insight into development of new techniques for synthesising functional nanoparticles having biological applications using non-toxic molecules under mild conditions stituted in the original B3 peptide is underlined.
ISSN:1742-7061
1878-7568
DOI:10.1016/j.actbio.2021.06.010