metallic ions so formed are intercalated between the DNA base pairs of the bacterial
genome, thus resulting in a mutation and ultimately bacterial cell death (Hemeg
2017). In this context, studies were conducted where the antibacterial effect of
metallic nanoparticles, viz., AgNPs and CuNPs, were assessed (Chatterjee et al.
2014; Dakal et al. 2016; Durán et al. 2016; Yoon et al. 2007). The study clearly
depicted that AgNPs were capable of inhibiting the cell division and DNA replica-
tion, whereas CuNPs on coming in contact with the bacterial cell resulted in the
degradation of bacterial DNA (Hemeg 2017). In a different experiment, a combina-
torial approach employing both X-ray irradiations and BiNPs was used as potent
vectors for antibacterial activity. The study pointed toward an efficient killing of the
pathogen bacterial population. The exact mechanism behind this vicious killing was
found to be the generation of free radicals, which brought intricate damage to the
nucleic acid component (viz., DNA) of the bacterial genome (Hemeg 2017;
Lellouche et al. 2012a).
11.3.6 Adsorption of Nanoparticles in Bacterial Cells (NP Interaction
With Cell Barrier)
The level of toxicity of NPs is greatly governed by the electrostatic or charged
interactions occurring between the NPs and the bacterial cell surface. It has been
noted that a positively charged particle tends to establish much-enhanced cytotoxic-
ity as compared to its negatively charged counterparts (Hemeg 2017). Keeping this
point in consideration, surface-engineered TIO2 NPs (AgNP-impregnated N-doped
titania) were prepared by Wong et al. (2015). It was deciphered that the prepared
NPs were able to establish an effective bridging, and they were readily absorbed into
the bacterial cell surface. The study also pointed out that this swift translocation of
NPs on the cellular surface resulted in enhanced cytotoxicity. The major mechanism
behind this toxicity generation in the bacterial cell was found to be the initiation of
redox reactions, which further lead to an escalation in the oxidative stress levels.
Damage to bilayer lipidic membrane and intracellular proteins were some other
detrimental effects, which originated due to the adhesion of these metallic particles
(Hemeg 2017; Wong et al. 2015).
11.3.7 Altered Bacterial Membrane Permeability
In a series of studies, researchers prepared polyvinyl alcohol (PVA)-stabilized
AgNPs (Dakal et al. 2016; Durán et al. 2016; Hemeg 2017; Sirelkhatim et al.
2015). The outcomes of the study clearly demarcated that the metallic ions thus
formed adhere to the charged lipopolysaccharide membrane. This results in altered
cellular membrane permeability and a subsequently enhanced ROS level production.
Further, it was noticed that these factors lead to an alteration in the viscosity of the
cellular membranes, thereby inhibiting and disrupting the respiratory transport
mechanisms (electron transport chain, ETC) as well as electrochemical proton
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