The dramatic increase in the use of

The dramatic increase in the use of silver nanoparticles (AgNP)
has resulted many beneficial applications but also raised some
concern. On the one hand, nanotechnology has begun to make
efficient use of the well-known anti-microbial properties of silver.
On the other hand, the increasing quantities in which AgNP are
produced and applied, as well as the unique characteristics
resulting from the nanoscale size, have led to concern over the
toxicological implications of exposure for nontarget species. Results
from studies with several plant species are largely in agreement
over the phytotoxic effects of AgNP in artificial conditions such as
hydroponic systems. AgNP have been demonstrated in hydroponics
to impair root elongation, seed germination and plant biomass
production of plants like zucchini, cucumber, onion, rye grass and
rice (Stampoulis et al., 2009; Anjum et al., 2013; Dimkpa, 2014;
Gardea-Torresdey et al., 2014). However, in the much scarcer soilbased
studies, the concentrations at which a negative effect of
AgNP on plants are observed are often higher than in hydroponics
studies, and the proportion of reported neutral AgNP effects on
plant growth increases (Dimkpa, 2014). As mentioned, the interest
in AgNP mainly originates from its well-known potency as a broad
spectrum antimicrobial agent effective against diverse species of
Gram-positive and Gram-negative bacteria (Morones et al., 2005;
Kim et al., 2007), as well as against several fungal species,
although reports of this anti-fungal activity are considerably less
numerous (Panacek et al., 2009). As both bacteria and fungi are
present in the rhizosphere of plants, the antimicrobial effects from
AgNP exposure may have significant implications for the host plant
health. Notably, the amount of research investigating the implications
of rhizosphere-based nanoparticle exposure on both the microbes
present and the supporting host plant is scarce.