Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductor

Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductor

Recently, Nanotechnology has made easier utilizing plant pathogens as a potential nanomaterial in biomedical applications. In this research work, we have exploited a devastating plant pathogenic virus of Squash leaf curl China virus (SLCCNV), as a nano-bio template (32 nm) to fabricate the gold and...

Full description

Bibliographic Details
Main Authors: Raja Muthuramalingam Thangavelu, Rajendran Ganapathy, Pandian Ramasamy, Kathiravan Krishnan
Format: Article
Language:English
Published: Elsevier 2020-01-01
Series:Arabian Journal of Chemistry
Online Access:http://www.sciencedirect.com/science/article/pii/S1878535218301540
id doaj-a0a7531f5ad5414cacdf6c6100acb91b
record_format Article
spelling doaj-a0a7531f5ad5414cacdf6c6100acb91b2020-11-25T01:37:01ZengElsevierArabian Journal of Chemistry1878-53522020-01-0113127502765Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductorRaja Muthuramalingam Thangavelu0Rajendran Ganapathy1Pandian Ramasamy2Kathiravan Krishnan3Plant Molecular Virology and Nanobiotechnology Research Laboratory, Department of Biotechnology, University of Madras, Chennai, Tamil Nadu 600 025, IndiaPlant Molecular Virology and Nanobiotechnology Research Laboratory, Department of Biotechnology, University of Madras, Chennai, Tamil Nadu 600 025, IndiaPlant Molecular Virology and Nanobiotechnology Research Laboratory, Department of Biotechnology, University of Madras, Chennai, Tamil Nadu 600 025, IndiaCorresponding author.; Plant Molecular Virology and Nanobiotechnology Research Laboratory, Department of Biotechnology, University of Madras, Chennai, Tamil Nadu 600 025, IndiaRecently, Nanotechnology has made easier utilizing plant pathogens as a potential nanomaterial in biomedical applications. In this research work, we have exploited a devastating plant pathogenic virus of Squash leaf curl China virus (SLCCNV), as a nano-bio template (32 nm) to fabricate the gold and silver nanomaterials. This is achieved through the direct exposure of SLCCNV to gold chloride (HAuCl4) and silver nitrate (AgNO3) precursors at sunlight, resulted into SLCCNV-metallic-hybrid nanomaterials which are synthesized quick (∼5 min) and eco-friendly. However, virus hybrid nanomaterials are fabricated through the nucleation and growth of metal precursors over the pH-activated capsid of SLCCNV. Under the controlled fabrication process, it produced a highly arrayed virus-metallic-hybrid nanomaterial at nanoscale size limit. Its properties are thoroughly studied through spectroscopic techniques (UV–Vis, DLS, Raman) and electron microscopy (HRTEM & FESEM). In a follow-up study of cytotoxicity assay, the virus and its fabricated nanomaterials show better biocompatibility features even at high concentrations. Finally, the electrical conductivities of virus-metallic-hybrid nanomaterials (Au & Ag) are determined by simple “lab on a chip” system and Keithley's pico-ammeter. The result of electrical conductivity measurement revealed that hybrid nanomaterials have greater electrical conductive properties within the band-gap of semi-conductive materials. It is truly remarkable that a plant virus associated metal nanomaterials can be efficiently used as bio-semi-conductors which are the ideal one for biomedical applications. Keywords: Virus nanotechnology, Virus template, Surface biomineralization, Virus hybrid nanomaterials, Electrical conductivity, Biocompatibilityhttp://www.sciencedirect.com/science/article/pii/S1878535218301540
collection DOAJ
language English
format Article
sources DOAJ
author Raja Muthuramalingam Thangavelu
Rajendran Ganapathy
Pandian Ramasamy
Kathiravan Krishnan
spellingShingle Raja Muthuramalingam Thangavelu
Rajendran Ganapathy
Pandian Ramasamy
Kathiravan Krishnan
Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductor
Arabian Journal of Chemistry
author_facet Raja Muthuramalingam Thangavelu
Rajendran Ganapathy
Pandian Ramasamy
Kathiravan Krishnan
author_sort Raja Muthuramalingam Thangavelu
title Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductor
title_short Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductor
title_full Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductor
title_fullStr Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductor
title_full_unstemmed Fabrication of virus metal hybrid nanomaterials: An ideal reference for bio semiconductor
title_sort fabrication of virus metal hybrid nanomaterials: an ideal reference for bio semiconductor
publisher Elsevier
series Arabian Journal of Chemistry
issn 1878-5352
publishDate 2020-01-01
description Recently, Nanotechnology has made easier utilizing plant pathogens as a potential nanomaterial in biomedical applications. In this research work, we have exploited a devastating plant pathogenic virus of Squash leaf curl China virus (SLCCNV), as a nano-bio template (32 nm) to fabricate the gold and silver nanomaterials. This is achieved through the direct exposure of SLCCNV to gold chloride (HAuCl4) and silver nitrate (AgNO3) precursors at sunlight, resulted into SLCCNV-metallic-hybrid nanomaterials which are synthesized quick (∼5 min) and eco-friendly. However, virus hybrid nanomaterials are fabricated through the nucleation and growth of metal precursors over the pH-activated capsid of SLCCNV. Under the controlled fabrication process, it produced a highly arrayed virus-metallic-hybrid nanomaterial at nanoscale size limit. Its properties are thoroughly studied through spectroscopic techniques (UV–Vis, DLS, Raman) and electron microscopy (HRTEM & FESEM). In a follow-up study of cytotoxicity assay, the virus and its fabricated nanomaterials show better biocompatibility features even at high concentrations. Finally, the electrical conductivities of virus-metallic-hybrid nanomaterials (Au & Ag) are determined by simple “lab on a chip” system and Keithley's pico-ammeter. The result of electrical conductivity measurement revealed that hybrid nanomaterials have greater electrical conductive properties within the band-gap of semi-conductive materials. It is truly remarkable that a plant virus associated metal nanomaterials can be efficiently used as bio-semi-conductors which are the ideal one for biomedical applications. Keywords: Virus nanotechnology, Virus template, Surface biomineralization, Virus hybrid nanomaterials, Electrical conductivity, Biocompatibility
url http://www.sciencedirect.com/science/article/pii/S1878535218301540
work_keys_str_mv AT rajamuthuramalingamthangavelu fabricationofvirusmetalhybridnanomaterialsanidealreferenceforbiosemiconductor
AT rajendranganapathy fabricationofvirusmetalhybridnanomaterialsanidealreferenceforbiosemiconductor
AT pandianramasamy fabricationofvirusmetalhybridnanomaterialsanidealreferenceforbiosemiconductor
AT kathiravankrishnan fabricationofvirusmetalhybridnanomaterialsanidealreferenceforbiosemiconductor
_version_ 1725060095993184256

Similar Items