The potential stressors to fish dis

The potential stressors to fish discussed
here are grouped as being environmental,
physical, or biological. They are presented
here as a selection of examples in each category
and by no means represent a complete
or extensive list of published stressors,
as reported by Barton and Iwama (1991).
Many stressors are unique to certain species
or geographic areas. Furthermore, the stress
response in fish has a genetic component
(see Pottinger and Pickering, 1997). Thus,
there are differences in the generalized
stress response among different fish species,
and different stocks or races of the same
species differ in their tolerance to applied
stressors. The observed stress response is
therefore an expression of both genetic and
environmental factors such as season, rearing
history, and nutritional state (see Iwama
et al., 1992). Environmental stressors mainly
include adverse physical and chemical
conditions of the water. Extreme conditions
or changes in water quality such as dissolved
oxygen, ammonia, hardness, pH, gas
content, partial pressures, and temperature
can stress fish. Metals (e.g., copper, cadmium,
zinc, and iron) and other contaminants
(e.g., arsenic, chlorine, cyanide, various
phenols, and polychlorinated biphenyls)
in the water can cause severe stress
and death in fish. Other potential environmental
stressors include insecticides, herbicides,
fungicides, and defoliants. Industrial,
domestic, and agricultural activities
add much of these contaminants to the environment
that affect fish at all life stages.
Natural changes in water quality, as occurs
during low tide in tidepools, may stress the
organisms that live in such environments.
Pathophysiological stressors encompass a
wide range of potential stressors including
those that disturb the fish physically and
psychologically. Handling, crowding, confinement,
transport, or other forms of physical
disturbance to fish also have psychological
components. Many of these are
practiced in the intensive culture of fish for
both wild stock enhancement, and for the
commercial production of food. Chasing
fish to exhaustion, or holding them in a net
out of water for 30-60 sec have been common
protocols utilized to study acute stress
responses in fish. Angling also stresses fish
in this manner. Other psychological stressors
can be manifest in dominance hierarchies,
which develop between individuals
within confines such as experimental tanks
or possibly in natural environments. Pathogens
and parasites can also be considered
as biological stressors. Fish disease, and
outbreaks leading to massive mortalities,
occur in nature as well as in cultured stocks.
Plankton blooms can stress and kill fish in
the wild as well as in aquaculture facilities.
The plankton may kill the fish directly by
their toxins; irritate or severely damage the
gill epithelium with their spines; or kill the
fish indirectly by hypoxic conditions by either
lowering water oxygen levels directly
or by increasing the diffusion distance between
blood and water through the stimulation
of mucus production on the gill surface.