IntroductionAeromonas hydrophila ca

Introduction
Aeromonas hydrophila causes disease in
fish known as “Motile Aeromonas
Septicemia” (MAS), “Hemorrhagic
Septicemia”, “Ulcer Disease,” or “Red-
Sore Disease.” The many synonyms of this
disease relate to the lesions caused by this
bacterium which include septicemia where
the bacteria or bacterial toxins are present
within numerous organs of the fish, and
ulcers of the fish’s skin. Aeromonas
hydrophila is a ubiquitous gram-negative
rod-shaped bacterium which is commonly
isolated from fresh water ponds and which
is a normal inhabitant of the
gastrointestinal tract. The disease caused
by this bacterium primarily affects
freshwater fish such as rainbow trout and
catfish (1). Copper oxide (CuO) is a
semiconducting compound with a
monoclinic structure. It is the simplest
member of the family of copper
compounds and exhibits a range of
potentially useful physical properties such
as high temperature conductivity,
superconductivity, electron correlation
effects and spin dynamics. Therefore, it
finds a wide application (2-3). CuO crystal
also has photo catalytic or photovoltaic
properties and photoconductive
functionalities (4). There is limited
information available about the
antimicrobial activity of nano CuO. As
CuO is cheaper than silver, easily mixes
with polymers and relatively stable in
terms of both chemical and physical
properties, it finds a wide application (5).
It is suggested that highly ionic
nanoparticulate metal oxides, such as CuO,
may find potential application as
antimicrobial agents as they can be
prepared with extremely high surface areas
and unusual crystal morphologies (6). CuO
nanoparticles (NPs) were effective in
killing a range of bacterial pathogens
involved in hospital-acquired infections.
But a high concentration of nano CuO is
required to achieve a bactericidal effect
(7). It has been suggested that the reduced
amount of negatively charged
peptidoglycans makes Gram-negative
bacteria such as Pseudomonas aeruginosa
and Proteus sp. less susceptible to such
positively charged antimicrobials. Studies
have been conducted to assess the potential
of nano CuO embedded in a range of
polymer materials. A lower contact-killing
ability was observed in comparison with
release killing ability against MRSA
strains. This suggests that a release of ions
into the local environment is required for
optimal antimicrobial activity (7, 8).
Copper NPs have a high antimicrobial
activity against B. subtilis. This may be
attributed to greater abundance of amines
and carboxyl groups on cell surface of B.
subtilis and greater affinity of copper
towards these groups.
Copper ions released may also interact
with DNA molecules and intercalate with
nucleic acid strands. Copper ions inside
bacterial cells also disrupt biochemical
processes (9).
In this study, we studied the synthesis,
characterization and antibacterial activity
of copper oxide nanoparticles as a new
class of agents against A. hydrophila and
compare new drug effects with
Tetracycline as reference antibacterial
drug.