Nanobiotechnology

About: Nanobiotechnology is a research topic. Over the lifetime, 796 publications have been published within this topic receiving 46309 citations. The topic is also known as: bionanotechnology & nanobiology.

Optoelectronic Signatures of Biomolecules Including Hybrid Nanostructure-DNA Ensembles

Abstract: Biological macromolecules such as DNA, proteins, and polysaccharides often display unique absorptive signatures in the THz region, useful in their identification and imaging through Raman and Fourier transform transmission spectroscopy. The optoelectronic properties of nanostructure-DNA complexes immobilized on transparent, semi-rigid substrates such as polymethyl methacrylate (PMMA) have been studied. By chemically modifying the PMMA substrates with amine terminal groups and using suitable linking agents, amine terminated DNA can be localized on these substrates. THz Fourier transform transmission spectroscopy was used to detect low-frequency vibrational modes (10-25 cm-1) within single- and double-stranded DNA molecules immobilized on PMMA attached to TiO2 nanoparticles. Additionally, DNA strands end terminated with TiO2 nanoparticles are used in this study to cleave the DNA at guanine (G) rich sites due to trapping of photo-induced charge carriers from the TiO2 at these sites. Theoretical modeling of charge transport through DNA via polaron transport is discussed in detail. By examining the vibrational modes of DNA, as well as the transport of charge in DNA this study underlies potential applications involving DNA micro-arrays, DNA-based sensors, and DNA-based THz devices.

An In Vitro and In Vivo Study of the Efficacy and Toxicity of Plant-Extract-Derived Silver Nanoparticles

Abstract: Silver nanoparticles (AgNPs) display unique plasmonic and antimicrobial properties, enabling them to be helpful in various industrial and consumer products. However, previous studies showed that the commercially acquired silver nanoparticles exhibit toxicity even in small doses. Hence, it was imperative to determine suitable synthesis techniques that are the most economical and least toxic to the environment and biological entities. Silver nanoparticles were synthesized using plant extracts and their physico-chemical properties were studied. A time-dependent in vitro study using HEK-293 cells and a dose-dependent in vivo study using a Drosophila model helped us to determine the correct synthesis routes. Through biological analyses, we found that silver nanoparticles’ cytotoxicity and wound-healing capacity depended on size, shape, and colloidal stability. Interestingly, we observed that out of all the synthesized AgNPs, the ones derived from the turmeric extract displayed excellent wound-healing capacity in the in vitro study. Furthermore, the same NPs exhibited the least toxic effects in an in vivo study of ingestion of these NPs enriched food in Drosophila, which showed no climbing disability in flies, even at a very high dose (250 mg/L) for 10 days. We propose that stabilizing agents played a superior role in establishing the bio-interaction of nanoparticles. Our study reported here verified that turmeric-extract-derived AgNPs displayed biocompatibility while exhibiting the least cytotoxicity.

Biochemical Synthesis and Manipulation of a 70 nm DNA Linker for the Assembly of DNA‐Functionalized Gold Nanoparticles

Abstract: DNA oligonucleotides are extraordinarily well suited as linkers for the programmable assembly of nanoparticles. To extend the scope of DNA-directed particle assembly, a 70 nm DNA linker molecule for the DNA-directed assembly of gold nanoparticles is synthesized by biochemical reactions. In particular, polymerase chain reaction (PCR) and subsequent restriction and ligation reactions are employed to synthesize the DNA linker, comprising a 178 base pair (bp) double helical core region supplemented with two sticky-end binding sites of 12 nucleotides in length, attached to one of the core-forming strands. The linker is used for the assembly of DNA-functionalized gold nanoparticles employing yet another biochemical reaction, namely covalent linkage through the enzyme DNA ligase. The resulting nanoparticle assemblies are characterized by using atomic force microscopy. The methodology described here represents a general way of synthesizing programmable DNA linker molecules with dimensions that exceed those presently available by using chemical synthetic methods, and thus, supplements the synthetic toolbox of nanobiotechnology to asses complex and functional nanoparticle/linker architectures for potential applications in sensing and materials science.