3. Results and discussions3.1. Lead

3. Results and discussions
3.1. Lead
Table 3 summarizes the concentrations of Pb in the wastewater
samples collected from in-let, out-let and different cells of CW. In
the wastewater samples, Pb concentrations ranged from 0.78 to
1.56 mg/L and exceeded the permissible limit (0.5 mg/L) set for
industrial and sewage wastewater (Pak-EPA, 2000). The ANOVA
analyses showed that the concentration of Pb in the out-let
wastewater samples was significantly lower (P < 0.001) than in-let
of the CW, indicating that the wetland has efficiently removed Pb
from the wastewater. Pb concentrations ranged from 1.0 to 2.9 mg/
kg in the sediment samples (Table 4). In the sediment samples, Pb
concentrations were decreased as the distance increased from the
in-let and the interaction between concentrations and distancewas
significant (P < 0.01) only for in-let and out-let samples. A strong
decrease in Pb concentrations in the sediments was also reported
by Lesage et al. (2007). The removal performance of the CW was
different for all selected HMs. The Pb removal efficiency of the CW
was 50%, higher than those (33%) reported in the literature (Terzakis
et al., 2008). In the study conducted by Lesage et al. (2007), Pb
removal efficiency of a CW was 81%. This can be attributed to the
difference in type of wastewater (domestic) and its basic characteristics,
including high concentrations of nutrients. Pb concentration
was 3 folds higher in the in-let samples and reduced to
0.78 mg/L, slightly above from the permissible limit set for industrial
wastewater in Pakistan. The macrophytes used for industrial wastewater treatment, showed variable degrees of uptake and
accumulation of Pb. As CW is a bioremediation mechanism based
system, its metal removal efficiency depending on phytoaccumulation,
sedimentation, microbial accumulation, and the nature of
the plant species (Kadlec and Knight, 1996). Plants (Echornia crassipes)
are helping to prevent precipitation to the bottom and metals
are sorbed by macrophytes (Maine et al., 2009). Furthermore,
emergent plants contribute to reclamation of wastewater through
a variety of physical, chemical and biochemical processes which
enhance metal retention by the sediment (Brix, 1997; Kadlec et al.,
2000). Plant uptake and accumulation of Pb varied from species to
species and metal concentration in plant tissue was higher in roots
than in aerial parts (Table 5). Concentrations of Pb ranged from 3.8
to 7.2 mg/kg in the root tissues, while varied from 1.5 to 3.2 mg/kg
in the aerial tissues. These results are generally comparable with
those previously reported in the literature (Vymazal et al., 2007).
The highest Pb concentration (rootþ aerial tissues) was found in
the Pistia stratiotes species with RCF and ACF of 4.8 and 2.2,
respectively (Table 6). This plant species is assumed to be hyperaccumulator
for Pb, therefore, can be use for removal of Pb from
wastewater.