Abstract:
Acute toxicity of 19 mixtures of iron, zinc, lead, nickel and manganese were determined in
terms of 96-hr LC 50 and lethal concentrationsfor five fish species viz.Catla catla, Labeo
rohita, Cirrhina mrigala,Ctenopharyngodon idella and Hypophthalmichthys molitrix under
laboratory conditionsat constant pH (7), total hardness (200mg/L) and water temperature
(30°C).The extent of metals bio- accumulation in fish body organs viz. gills, liver, kidney,
fins, bones, muscle and skin at both 96-hr LC 50 and lethal concentrations were also
determined. In the 2 nd phase, growth responses of five fish species were determined,
separately, under chronic exposure of 19 mixtures of metals at sub-lethal concentrations
(1/3 rd of LC 50 ) for 12 weeks. The bioaccumulation of metals in the fish body organs viz.
gills, liver, kidney, fins, bones, muscle and skin were also determined before and after
growth trails under the stress of 19 mixtures.
All the five fish species showed significantly variable tolerance limits in terms of 96-hr
LC 50 and lethal concentrations against 19 mixtures of five metals. Amongst 19 mixtures /
treatments, the mixture of five metals (Fe+Zn+Pb+Ni+Mn) caused significantly higher
toxicity to the fish, in terms of 96-hr LC 50 and lethal concentrations of 46.23±11.54 and
73.46±14.18mgL -1 , respectively. However, Pb+Mn and Zn+Pb mixtures were significantly
least toxic to the fish with the mean LC 50 and lethal concentrations of 83.48±11.34 and
134.70±26.77mg L -1 , respectively. Regarding overall sensitivity of five fish species,
Hypophthalmichthys molitrixwere significantly more sensitive to metals mixtures with a
mean LC 50 value of 59.63±11.01mgL -1 while Labeo rohita showed significantly least
sensitivity (81.73±12.73mgL -1 ).This significantly higher sensitivity of Hypophthalmichthys
molitrix towards metal mixtures was followed by that of Cirrhina mrigala, Catla catla,
Ctenopharyngodon idella and Labeo rohita. However, the difference between Catla catla
and Cirrhina mrigala, for their tolerance limits (LC 50 ), were statistically non-significant.
The overall sensitivity of all the five fish species, determined in terms of lethal
concentrations, against various metals mixtures varied significantly. Regarding overall
response of fish towards 19 mixtures, mean sensitivity of fish to the mixture of five metals
(Fe+Zn+Pb+Ni+Mn) was significantly high (P<0.05), followed by that of four
metalsmixtures
(Fe+Zn+Pb+Mn)
with
statistically
significant
difference.
Hypophthalmichthys molitrix were significantly more sensitive to metals mixture with themean lethal concentration of 97.85±16.20mgL -1 , followed by that of Catla catla, Cirrhina
mrigala, Ctenopharyngodon idella and Labeo rohita with the mean lethal concentrations of
101.70±16.70, 105.80±12.80, 122.40±23.77 and 128.80±19.95mgL -1 , respectively.
Amongst five fish species, Labeo rohita showed significantly least sensitivity towards
Zn+Pb mixture (170.00±0.60mgL -1 ) while Hypophthalmichthys molitrix showed
significantly higher sensitivity to Pb+Mn with the mean lethal concentrations of
18.53±0.61mgL -1 . The overall sensitivity of five fish species varied significantly for 19
mixtures with the mean higher and lower lethal concentrations of 134.70±26.11 and
73.56±14.18mgL -1 for Zn+Pb and Fe+Zn+Pb+Ni+Mn mixtures, respectively.
The exposure of four (Fe+Zn+Pb+Mn) and five (Fe+Zn+Pb+Ni+Mn) metal mixtures, at
sub-lethal concentrations (1/3 rd of LC 50 ), caused significantly lesser growth to all the five
fish species. Amongst 19 mixtures, Fe+Zn+Pb+Ni mixture (#17) caused significantly
pronounced impacts on the growth performance of all the five fish species, followed by
thatof Fe+Zn+Pb+Ni+Mn (#19) and Fe+Zn+Pb+Mn (#18) mixtures. Under chronic
stress, Cirrhina mrigala and Hypophthalmichthys molitix attained significantly higher
weights, followed by that of Catla catla, Labeo rohita and Ctenopharyngodon idella.
However, the growth of all the five metals mixture exposed fish species was significantly
lesser than that of control fish (un-stressed). Significantly variable condition factor values
reflected the degree of fish well-beings that correlated directly with fish growth. The
metallic ion loads (under the exposure of different mixtures) of the culture media correlated
inversely with fish growth due to significant effects of metal’s stress on fish body. The
growth performance of fish did not vary significantly due to change in feed intake while
significantly positive change in the feed conversion efficiency had affected the fish growth
significantly due to the impacts of various mixtures in reducing fish metabolism and
activity. Any significant change in feed intake, due to stress, is reflected in terms of fish
growth showing the impacts of various mixtures on fish growth were either additive or
antagonist / synergistic. Physico-chemistry of the test media (water) used for different
treatments exerted significant impacts on fish growth, feed intake, and condition factor and
feed conversion efficiency of fish also. Significantly better feed intake enhanced the
ammonia production and excretion by the fish resulting into non-significantly positive
relationship of fish weight increments with ammonia contents of the test media.
Significantly higher feed intake resulted in excessive excretion of ammonia by the fish to
cause significant impact on its growth. Sodium and potassium showed significantlypositive correlation with ammonia concentrations of the test media, indicating excessive
release of sodium and potassium by the fish under stress of various mixtures that resulted
in significantly more excretion of ammonia by the fish. Organ-wise distribution of residual
metals viz. iron, zinc, lead, nickel and manganese reveals liver as the prime site of their
accumulation with significantly higher persistence, followed by kidney, gills and fins of
metals mixture exposed fish. The fish muscle tissues accumulated significantly (P<0.05)
lower metals than liver, kidney and gills. The exposure of metals mixture at higher
concentrations resulted in escalated levels of these metals in fish body that followed the
general order: zinc >iron >nickel >lead >manganese which can be regarded as an indicator
of cumulative response of five fish species. Accumulation of all the metals in fish body
followed the general order: liver>kidney>gills>fins>muscle>skin>bones. The level of
various metals in gills of fish, exposed to different sub-lethal concentrations of mixtures,
was significantly higher (P<0.05) than the levels found in all other organs except liver and
kidney.