IV. DISCUSSION - Shodhgangashodhganga.inflibnet.ac.in/bitstream/10603/371/11/11_chapter 4.pdf ·...
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IV. DISCUSSION
DISCUSSION
In recent years, pollution of water has become one of the most significant
environmental problems in the world. Today there is a great concern for rapidly
deteriorating quality of water. Most of the rivers and freshwater streams in India
are badly polluted by industrial wastes or effluents. The effluents produce physical,
chemical or biological changes in water. In order to recognise and predict hazardous
effect caused by human activities, effective and reliable monitoring systems are
required. Biological methods can be applied in predicting the impact of pollutants in
aquatic ecosystem
Algae are potential pollution indicators since they respond either by
stimulation or inhibition or by both to the toxicants affecting water quality (Rajendran
and Venugopalan, 1983). The factors that cause varied responses are concentration
of the toxicant, duration of exposure and sensitivity of the test species.
Algal assays were first proposed by Skulberg (1962) and in recent years,
have been used widely to evaluate nutrient status of a variety of water bodies
(Anon, 1969; Bartsch, 1971; Maloney etal., 1972; Tunzi, 1972; Forsberg, 1972,
Cain and Trainor, 1973; Chiaudani and Vighi, 1974; Miller et a/., 1974; Koltz et a/.,
1975). Since algae are the primary producers in the aquatic food chain and are
more sensitive to contaminants than fish or invertebrates, algal assays have an
indispensable role in water pollution monitoring (Wong, 1995). These assays are
considered as a supplement to chemical analysis in the assessment of pollution
and are more sensitive than Daphnia tests for monitoring toxicity in aquatic
environments (Baun et a/., 1998).
Acute toxicity tests are of short duration, typically representing a small
fraction of the life time of the organisms, hence do not picture the complete
consequences of the toxicants in the culture medium (Patin, 1982). Hence long-
term experiments for a period of 21 days were designed for the algal assays.
The present investigation was undertaken with an objective to assess
the impact of different industrial effluents on the growth and metabolism of selected
phytoplankters. in addition to this, the water quality monitoring of the waterways
that receive the effluent was also conducted. For the present study, the algal species
selected were Chlorella ellipsoidea Gerneck, Ankistrodesmus falcatus (Corda.)
Ralfs, Scenedesmus brjuga (Turp.) Lagerheim, Haematococcus laccustris (Girod.)
Rostafinski and Chlorococcum humicola (Naeg.) Rabenhorst. The effluents taken
were distillery effluent, pulp-paper mill effluent and petro-chemical factory effluent.
4.1 Distillery effluent
Analysis of physicochemical parameters of the distillery effluent revealed
that the pH of the effluent remained in the permissible range (pH 5.5 to 9.0; IS:
2490,1982; MOEF, schedule VI 1993). Ray (1961), David and Ray (1966),
Bhaskaran (1959), Verma and Mathur (1 974) and Gill and Toor (1976) reported low
pH values for distillery effluent. The colour of the effluent was dark brown and was
not according to the standards (MOEF, 1993). Dissolved oxygen (DO) was totally
absent in the effluent. The absence of dissolved oxygen indicates the poor quality
of the distillery effluent.
The biochemical oxygen demand (BOD) of the effluent was very high
1600 mg L-' which was significantly far above the tolerant limit (30 mg L-'; MOEF,
1993; IS: 2490, 1981). Similarly chemical oxygen demand (COD) of the effluent
was also very high (39,360 mg L-'), and was far ahead of the standards (250 mg L-';
MOEF, 1993; IS: 2490, 1981). The sulphate concentration was low in the distillery
effluent (24 mg L-') and was less than the effluent standards (400 mg L-I). The
chloride content, 5048.1 mg L-', was many fold higher than the tolerance limit (600 mg L-';
MOEF. 1993; IS: 2490, 1981; CPCB, 1979). Nitrites and nitrates were totally absent
in the effluent. In addition to nitrogenous compounds, phosphate was also not
detected in the effluent.
The concentration of silicate in the effluent was 9.0 mg L-'. Sodium was
absent in the effluent while 2.8 mg L ~ ' potassium was detected in the sample.
Concentration of magnesium and calcium were very high in the effluent and the
values were 1742.5 mg L ~ ' and 1138.28 mg L-' respectively. The total dissolved
solids estimated in the effluent sample was 56,800 mg L-'. The quantity of organic
carbon was very high and was 3000 mg L-'.
Cell multiplication pattern in the five microalgae recorded growth
stimulation in lower concentrations of the distillery effluent, while higher
concentrations arrested the population growth in all the phytoplankton species.
Among the algal species, Ankistrodesmus falcatus (Corda.) Ralfs exhibited
increased growth in concentrations ranging from 0.05% to 0.5% of distillery effluent,
while in the remaining four members, Chlorella ellipsoidea Gerneck, Scenedesmus
bijuga (Turp.) Lagerheim, Haematococcus laccustris (Girod.) Rostafinski, and
Chlorococcum humicola, (Naeg.) Rabenhorst growth enhancement was noticed up
to 0.25% effluent. The optimum concentration required for growth was 0.1%
concentration in the tested species. The decreased growth rate of test organisms
at higher levels of the effluent may be attributed to its high BOD, COD and other
characteristics that are detrimental to the growth of algae. Verma and Shukla (1969)
reported that high BOD. COD and low level of dissolved oxygen make the undiluted
sugar factory effluent unfit to support any form of life in them.
Presence of various elements viz. K, Mg, Ca, Si etc. can promote the
algal growth in lower concentrations. Magnesium is an important constituent of
photosynthetic pigment and the phytoplankton requires magnesium for the growth
(Venkataraman, 1969). Literature survey revealed that lower concentrations of
magnesium could intensify the growth in different algae (Rodhe, 1948 and Natarajan
1 960).
Another major nutrient present in the distillery effluent was calcium.
Calcium plays an important role in the maintenance of plasma membrane, cell wall
etc. Variations in calcium concentration found to affect the growth of algae (Hutner,
1948; Natarajan, 1960; Groves and Kostir, 1961; Rahimian, 1972; Kong eta/., 1999).
Lower concentrations stimulated the growth, while higher concentrations inhibited
the growth.
The distillery effluent sample was rich in organic carbon. The importance
of organic carbon sources in the algal metabolism has been discussed by Pearsall
and Bengey (l940), Doyle ,(1943); Algues, (1946); Myers, (1951); Fogg and Wotfe*
(1954) and Denforth, (1962). Along with other constituents organic carbon content
in the distillery effluent enhanced the growth in lower concentrations.
Patil (1998) reviewed the impact of spent wash on the growth of the
algae. He reported that lower concentrations of the spent wash stimulated the growth
in Spirulina species and Oscillatoria species while higher concentrations inhibited
the growth. Rao and Vidyakumari (1979) documented that high level of chloride
content adversely affects the algal growth. Earlier literatures indicate the reduced
growth of Chlorella vulgaris exposed to raw cane sugar effluent (Benitez, 1979;
Travieso et a/. 1996).
The enhanced growth of test organisms in lower concentrations of
distillery effluent may be due to the stimulatory effect exerted by the different
ingredients present in the effluent. Travieso et al. (1999) reported a similar result in
Chlorella vulgar~s Tanti-Charoen et a/. (1993) and Thangaraj and Kulandaivelu
(1994) supported the same view. Lefe bvre et a/. (1996) observed that fish farm
effluents stimulated the growth in marine diatoms. Growth stimulation in
phytoplankters with low concentrations of latex concentrate effluent was studied
by Yusoff e l a/. (1996). Studies of Aidar et al. (1997) and Smith et al. (1997) also
145 .-
revealed growth stimulation in algae at lower concentrations of different effluents.ln
a similar report, Gopinathan et al. (1994) recorded the growth enhancement in
Tetraselmis gracilis in the beginning of the assay with lower level of thermal effluent.
Bioassays of fish with distillery effluent confirmed that concentrated
elfluent is toxic to fish because of the low pH, low DO values etc. (Gill and Toor,
1976). Shinde and Trivedi (1983) in their studies on the higher plants noticed the
adverse effect of higher concentrations of distillery effluent on the agronomical
characteristics of Abelmoschus esculentus and Zea mays along with the hazardous
changes in the soil.
The results obtained with the distillery effluent in the present investigation
are in accordance with earlier reports. Chlorella ellipsoidea Gerneck showed initial
growth stimulation up to 1 .O% concentration. Reduction in cell muliplication in higher
levels of effluent might have been due to colour, low pH, low dissolved oxygen and
high concentration of other organic and inorganic components observed in the
distillery effluent.
Phytoplankters are the most important primary producers of aquatic
ecosystem. Considering the fresh water environment, algae carry out 60% of the
total carbon production. Discharge of different effluents alters the productivity of
the receiving water bodies.
Distillery effluents slowed down the carbon production in all the
concentrations in the beginning of the experiment in Chlorella ellipsoidea Gerneck,
Ankistrodesmus falcatus (Corda.) Ralfs and Haematococcus laccustris (Girod.)
Rostafinski. However, an enhancement of carbon production was noticed in the
later part of the studies. An induction in carbon fixation was recorded in
Scenedesmus bijuga (Turp.) Lagerheim and Chlorococcum humicola, (Naeg.)
Rabenhorst in lower concentrations at the early stages itself. In all the tested species
stimulation in carbon production was limited to lower concentrations, while higher
concentration lowered the productivity. Aidar et al. (1997) observed an inhibition of
primary production in phytoplankton at higher concentrations of laundry effluent.
Treatment with latex concentrate effluent showed significantly higher
productivity than the control in lower concentrations (Yusoff et a/., 1996). Laundry
effluent also recorded same trend in primaly production (Aidar et al. , 1997). Schwartz
and Gruendhing (1985) opined that high organic carbon content could enhance the
productivity of phytoplankton. The distillery effluent selected in the present study
contained high concentration of organic carbon, which in turn might have contributed
thehigh rate of carbon production.
The photosynthesising cells are characterized by the presence of green
pigments. These coloured organic compounds are the most important component
of the chloroplast lamella. The pigment content of the microalgae has great
importance in productivity studies.
Wide variations in the concentrations of chlorophyllous pigments were
revealed by the test algae treated with different concentrations of the effluent during
the present investigation. Lower concentrations of the distillery effluent stimulated
pigment production in the algal cells than the control. In Chlorella ellipsoidea
Gerneck, stimulation in chlorophyll a occurred, after an initial inhibition. Almost
similar pattern of enhancement in chlorophyll a was noticed in Ankistrodesmus
falcatus (Corda.) Ralfs, Scenedesmus bijuga (Turp.) Lagerheim, Haematococcus
laccustris (Girod.) Rostafinski and Chlorococcum humicola, (Naeg.) Rabenhorst.
In all the microalgae reduction in chlorophyll a content was depicted in higher
concentrations of the distillery effluent.
In the present investigation, an enhancement of the accessory pigments
chlorophyll b, chlorophyll c and carotenoids was recorded in lower concentrations,
while higher concentrations imparted reduction.
Smith et al. (1988), Kobbia et a/. (1995), Yusoff et a/. (1996) and Aidar et al.
(1997) reported the enhancement of pigment content in lower concentrations of
latex concentrate effluent. However Benitez,(1979) and Travieso et a/. (1996) noticed
the reduction in chlorophyll content at higher concentrations of cane sugar effluent.
Aidar et a/. (1997) documented the retarding effect of higher concentrations of the
laundry effluent in the synthesis of chlorophyll a. Inhibitory effect of higher level of
calcium on the formation of chlorophyll a was revealed by Zhang and Prepas (1996).
The biochemical compounds vit. the protein and carbohydrate exhibited
varied responses with different concentrations of the distillery effluent. Reduction
in protein content was observed towards the end of the bioassay in Ankistrodesmus
falcatus (Corda.) Ralfs, Scenedesmus bijuga (Turp.) Lagerheirn and Haematococcus
laccustris (Girod.) Rostafinski. Reduction in protein content was not recorded in
Chlorella ell~psoidea Gerneck and Chlorococcum humicola (Naeg.) Rabenhorst.
Carbohydrate content in the microalgae of the control as well as the
treated cells showed increasing trend till the last day in Chlorella ellipsoidea Gerneck,
Ankistiodesmus falcatus (Corda.) Ralfs, Haematococcus laccustris (Girod.)
Rostafinski and Chlorococcum humicola (Naeg.) Rabenhorst. In Scenedesmus
bijuga (Turp.) Lagerheim the carbohydrate content showed reduction on the final day.
: 14%
Both protein and carbohydrate content of the algae showed enhancement
similar to cell number, carbon production and pigment content in lower
concentrations. Protein and carbohydrate content in 1 .O% and 1.5% concentrations
of the distillery effluent showed shoot up in the beginning. Since the distillery effluent
is rich in organic carbon and other minerals, the cells may have showed the tendency
of absorption of more nutrients from the medium quickly after the exposure.
According to Pistocchi et a/. (1997) increased carbohydrate production at higher
concentrations could be attributed to extracellular rather than intracellular
carbohydrate.
4.2 Pulp-paper mill effluent
The physico-chemical analysis of the pulp- paper mill effluent showed
that the effluent was slightly alkaline (pH 7.4), which occupied in the permissible
limit (pH 5.5 to 9.0; IS: 2490, 1981, MOEF Schedule VI, 1993). The effluent was
brown in colour and was against the standards (MOEF, 1993). Dissolved oxygen in
the pulp-paper mill effluent was very low, 2.5 mg L-l and was below the standards
(CPCB, 1979).
The biochemical oxygen demand (BOD) of the effluent sample was 270 mg L-',
which was fairly above the tolerance limit (MOEF 1993; IS: 2490, 1981). The
chemical oxygen demand (COD) recorded was 640 mg L-'. This too was above the
tolerance limit (250 mg L1, MOEF 1993; IS: 2490, 1981). However, the sulphate
content in the effluent was 98 mg L-I and was lower than the permissible liml(400 mg L-',
CPCB, 1979). In the pulp-paper mill effluent the chloride content was 294.2 mg L-'
and below the standards 1000 mg L-' (MOEF, 1993) and 600 mg L-' (CPCB, 1979).
Nitrite and nitrate was not detected in the sample, while the effluent contained
phosphates and silicates. Sodium and potassium were obsewed in the effluent
sample. There are no specific standards for sodium and potassium. The
concentrations of magnesium and calcium in the sample were 26.42 mg L-' and
61.72 mg L 1 respectively. Total dissolved solids was 850 mg L-' that was lower
than the standards. The effluent contained 0.014 mg L-' mercury, which was slightly
above the standard (0.01 mg L-'). The pollution load from the pulp-paper mill was
found to be very high and contained biodegradable organic substances and other
pollutants (Klein, 1957; Todd, 1970; Hunter and Faust, 1971; Yen, 1996).
The pulp-paper mill effluent added to the medium recorded stimulation
as well as inhibition to the microalgae. The five different unialgal cultures tested
with the pulp-paper mill effluent reacted differently with different concentrations of
the effluent. All the algal species exhibited optimum population growth in 0.1% of
the effluent. In the case of Ankistrodesmus falcatus (Corda.) Ralfs and
Scenedesmus bijuga (Turp.) Lagerheim, 0.5% concentration was growth stimulating
while in Chlorella ellipsoidea Gerneck, Haematococcus laccustris (Girod.)
Rostafinski and Chlorococcum humicola, (Naeg.) Rabenhorst, concentrations higher
than 0.25% retarded the growth. Common characteristic feature noticed was the
inhibition of growth in all the test species at higher concentrations of the effluent.
Growth is an orderly increase of all the components of an organism. It
was observed that the microalgal cells with smaller size had the capacity to grow
faster,thus agreeing with the observation of Raymond (1980). The increase in
algal biomass over a particular, usually a period of week or month may be referred
as "growth or new production" (Eppley and Peterson, 1979). Thus growth is the
increase in the pool size of particulate organic carbon tied up in the phytoplankton.
Earlier investigators like Palmer and Maloney (1955), Rachlin and Farran
(1974). Cain et a/. (1979), Anita etal. (1991) and Berman and Chava (1999) proved
the growth stimulation of the algae at lower concentrations of various effluents.
Schmager (1979) commented that lower concentrations of chlorine could induce
growth, while higher concentrations inhibited the growth in a heterogenous algal
culture. Rao and Vidyakumari (1979), Travieso etal. (1996) and Patil(1998) reported
the reduction of algal growth with higher concentrations of distillery effluent.
The pulp-paper mill effluent contains sodium. Allen (1952) found the
need of sodium for the growth of various blue green algae. The phosphate present
in the effluent is also a growth-inducing factor. Rodhe (1948), Lund (1950), and
Goldberg et al. (1951) revealed the luxurious consumption of phosphorus by algae.
An (2003) commented that phosphorus is a potential limiting element for algal growth.
Most of the organic and inorganic components present in the pulp-paper
mill effluent at lower concentrations might have favoured the cell multiplication. But
at higher concentrations of the effluent, the mineral composition of the effluent
increased and these might have reacted adversely with cell multiplication. Verma
and Shukla (1969) too shared this view.
Results of the present investigation made it clear that the pulp - paper
mill effluent has a significant effect on both GPP and NPP of treated algae. In
Chlorella ellipsoidea Gerneck. Scenedesmus bijuga (Turp.) Lagerheim and
Chlorococcum humicola. (Naeg.) Rabenhorst, lower concentrations intensified both
:: 151 ..
GPP and NPP. Simultaneously, reduction in carbon production was recorded in
higher concentrations. This is in accordance with the reports of Asma and Mathew
(1995),Yusoff et a/. (1996), Aidar et a1.(1997) and Valsamma Joseph (2000). 1
Ankistrodesmus falcatus (Corda.) Ralfs and Haematococcus laccustris
(Girod.) Rostafinski exhibited reduction in GPP and NPP in all cocentrations. The
reduction in carbon production may be attributed to the toxic effect developed in
the photosynthetic pigment. Wong et al. (1994) reported structural damages in the
chloroplast of Chlorella fusca treated with the petrochemical factory effluent.
Reduction in carbon production of treated cells was recorded by earlier workers
like Mac farlane etal. (1972), Subramanian et a/. (1979), Rajendran and Venugopbn (1983).
Carbon production showed an increase with the age of culture. This
may be due to the increased cell number in the aged culture. The increased number
of photosynthesising cells could lead to more primary production.
The photosynthesising cells contain large amount of pigments. These
include chlorophyllous pigments like chlorophyll a, chlorophyll b, chlorophyll c and
non- chlorophyllous pigments like carotenoids. Photosynthetic rate per unit
chlorophyll is often used as an indicator of the physiological state of algal
assemblage (Perry et al. 1981). If chlorophyllous and non- chlorophyllous pigments
are altered by the treatment, it will adversely influence the rate of photosynthesis
and will decrease oxygen production of microalgal cultures. Thus changes incur in
the pigment could lead to an unbalanced physiological state.
Great fluctuations in the concentration of the chlorophyllous pigments
were recognrzed throughout the experimental period, in relation to various
152
concentrations of the effluent. In most cases, the lower concentrations of the effluent
displayed an increased pigment content than the control, as noticed in Scenedesmus
bijuga, (Turp.) Lagerheim, Haematococcus laccustris (Girod.) Rostafinski, and
Chlorococcum humicola (Naeg.) Rabenhorst. Stimulation in pigment content was
observed in all concentrations in Chlorella ellipsoidea Gerneck and Ankistrodesmus
falcatus (Corda.) Ralfs.
Non-chlorophyllous pigments like carotenoids may also serve as a
potential light harvesting pigment. These accessory pigments in algae and higher
plants increase the absorption spectrum over wider wavelength, than would exist if
chlorophyll was the sole absorbing pigments (Harris, 1978). Changes in the
caroteniod content of the microalgae will affect the photosynthetic process.
The treated cells showed inhibition of pigment content and photosynthetic
rate. In some cases the activity of the pigment was inhibited. Abou-waly et al.
(1991 b) reported that chlorophyll activity was inhibited more than the chlorophyll
content when treated with the toxicant. In the present study, the quantity of pigment
was estimated in all cases and in some cases decrease in the carbon production in
contrary to the increased chlorophyll content was observed in some cases. This
suggests the detrimental effect of the effluent on the chlorophyll activity than on its
production.
Gopinathan et al. (1994) documented colinearity between carbon
production and photosynthetic pigments. The colinearity in pigment content and
primary productivity was observed in Chlorella ellipsoidea Gerneck and
Scenedesmus bijuga (Turp). Lagerheim. It was not noticed in Ankistrodesmus
falcatus (Corda.) Ralfs and Naematococcus laccustris (Girod.) Rostafinski.
The protein and carbohydrate content of the five different algal species
exhibited wide variations with different concentrations of pulp-paper mill effluent.
The biochemical compound, protein enhanced in most of the concentrations tried.
After an initial inhibition in protein production, Chlorella ellipsoidea Gerneck showed
stimulation in all treated cells. In Ankistrodesmus falcatus (Corda.) Ralfs,
Scenedesmus bijuga (Turp.) Lagerheim, Haematococcus laccustris (Girod.)
Rostafinski and Chlorococcum humicola (Naeg.) Rabenhorst higher concentrations
inhibited the protein content. Decrease in protein content was noticed on 21stday,
in control as well as in treated cells
Carbohydrate content enhanced in lower concentrations of pulp - paper
mill effluent in Chlorella ellipsoidea Gerneck, Haematococcus laccustris (Girod.)
Rostafinski and Chlorococcum humicola. (Naeg.) Rabenhorst, while higher
concentrations reduced it. In Ankistrodesmus falcatus (Corda.) Ralfs and
Scenedesmus bijuga (Turp.) Lagerheim the carbohydrate content accelerated in
all concentrations. The effluent may undergo biodegradation and and the resulting
compounds may act as nutrients in the medium. Naturally, the treated algal cells
may have absorbed more nutrients that resulted in high carbohydrate content in
the treated cells
4.3. Petrochemical factory eff luent
Analysis of physico-chemical parameters of the petrochemical factory
effluent revealed that the effluent was alkaline with a pH of 8.33, which was within
the permitted range (IS: 2490, 1981, MOEF 1993, Schedule VI). The effluent was
colourless. The dissolved oxygen in the petrochemical factory effluent was 8.7 mg k'
which was better than the other two effluents, and was above the standards
(CPCB, 1979).
The biochemical oxygen demand (BOD) of the effluent was 10.4 mg L-'
and below the tolerance limit (30 mg L-', MOEF 1993; IS: 2490, 1981). The chemical
oxygen demand of the petrochemical effluent was also very low 48 mg L-', and was
lower than the tolerance limit (250 mgL-l, MOEF 1993; IS: 2490, 1981). Though
BOD and COD of the effluent were low, the concentration of sulphate was very
high in the effluent sample. The sulphate content was 2420 mg L-', which exceeded
the tolerance limit (1000 mg L-l; MOEF, 1993; 600 mg L-l; CPCB, 1979). The chloride
and phosphate content in the effluent were 49.63 mg L-I and 0.4 mg L-1 respectively.
The quantity of silicate was found to be 0.04 mg L-l.
The sample contained 1.38 mg L-I nitrate, while nitrite was not detected
in the sample. Sodium and potassium were also present in the effluent. The amount
of total dissolved solids in the sample was higher than the permitted limit (2100 rng L-',
MOEF, 1993, IS: 2490, 1981). Mercury was present in the sample and it recorded
0.013 mg L ' which was above the permissible limit (0.01 mg L-l, MOEF, 1993). The
presence of phenol was detected in the sample and was 0.85 mg L-' that was below
the tolerance limit (1 .O mg L-', MOEF, 1993; 2.0 mg L-l, CPCB, 1979).
Growth pattern in the five test species indicated a negative impact with
higher concentrations of the effluent. The algal assays revealed that the lower
concentrations could stimulate the growth in the test species. The most appropriate
growth was observed in 0.1% of the effluent. Chlorella ellipsoidea Gerneck was the
most tolerant species, while Haematococcus laccustns (Girod.) Rostafinski was
susceptible to petrochemical factory effluent, which showed growth stimulation only
upto 0.25% concentration. In Chlorella ellipsoidea Gerneck growth stimulation was
observed even in 0.75% of effluent, where as 0.5% concentration was the highest
concentration which showed growth enhancement in other test species viz.
Ankistrodesrnus falcatus (Corda.) Ralfs and Chlorococcum humicola (Naeg.)
Rabenhorst. The higher concentrations, 1 .O% and 1.5% inhibited cell multiplication.
Walsh and Garnas (1979) opined that the stimulation of algal growth by
the petrochemical effluent is due to its organic content. Industrial effluents can
cause stimulation or toxicity and structural damages to algae (Walsh etal., 1980;
Wong et a/., 1994, 1995). Low molecular weight hydrocarbons were found to
stimulate phytoplankton growth depending upon the species (Dunstan, 1975).
Decrease in growth with increasing concentrations of the petrochemical factory
effluent was recorded by Soto et a/. (1977), Dahl etal. (1983), Zachleder et al.
(1983), Vandermeulen and Lee (1986), El-Dib et a1 (1 997) and Joseph and Joseph
(2001). Ghosh (1983) studied the toxic effect of phenol on fish. Phenols have a
highly variable effect on aquatic plants. Some phenolic compounds may actually
stimulate the growth at low concentrations, where as others are consistently toxic
(Moore and Ramarnoorthy, 1984). In OscIllatoria quadripuctulata. and Chlorella
pyrenoidosa lower concentrations of phenol stimulated the growth,however higher
concentrations were reported to be inhibitory to the algae (Valsamma Joseph, 2000).
Tadros et a1 (1994) suggested that the growth in Chlorella ellipsoidea Gerneck
was affected by 0.5%, 01% and 0.2% of phenol.
The present investigation also supports the view that lower
concentrations of petrochemical effluent have a growth stimulatory effect.
The high algal biomass formation was reported with refinery effluent.
The stimulatory effect is due to its organic fraction (Walsh and Garnas, 1979).
The petrochemical factory effluent altered the carbon production in all
the treated algal species. All the treated cells of Chlorella ellipsoidea Gerneck,
Scenedesmus bijuga (Turp.) Lagerheim and Chlorococcum humicola (Naeg.)
Rabenhorst exhibited enhanced gross and net carbon production in all treated
concentrations ranging from 0.05% to 1.5%. Carbon production in Ankistrodesmus
falcatus (Corda.) Ralfs and Haematococcus laccustris (Girod.) Rostafinski showed
enhancement in lower concentrations of petrochemical factory effluent. Higher
concentrations retarded the carbon production.
The Increase in carbon production observed in the higher concentrations
of the effluent in Haematococcus laccustris (Girod.) Rostafinski may be due to
acclimation. In a study on the acclimation of algal community to zinc toxicity, it was
concluded that the acclimation of the test organism to a toxicant has an important
effect on its response to toxicity (Wang, 1986). The tolerance of algae to
petrochemical factory effluent was found to be species specific. The mechanism
involved may be e~ther storage or metabolic utilization (Karydis, 1979).
Decrease in gross and net carbon production in Ankistrodesmus falcatus
(Corda.) Ralfs and Haernatococcus laccustris (Girod.) Rostafinski showed similarity
with the investigations of Asma and Mathew (1995) Yusoff ef a/. (1996) and Aidar
et a/. (1997).
The photosynthetic pigments, chlorophyll a and chlorophyll c retarded
in Chlorella ellipso~dea Gerneck on exposure to higher concentrations, while
chlorophyll b and carotenoids recorded enhancement. Higher concentrations of
the effluent lowered the photosynthetic pigments in Ankistrodesmus falcatus (Corda.)
Ralfs, Chlorococcum humicola (Naeg.) Rabenhorst, Scenedesrnus bijuga (Turp.)
Lagerheim and Haematococcus laccustr~s (Girod.) Rostafinski.
The observed toxicity in the pigment production may be explained by
the bioavailable contaminants absorbed by the algal cells from the effluent. Wong
et al. (1994) recorded that the stress effect of organic toxicants on the fine structure
of algae is the abnormal build up of large starch grains and mass destruction of
organelles. The interference with the oxidative phosphorylation, photosynthesis,
respiration, protein and nucleic acid synthesis were detected in Chlorella cells when
exposed to toxicants such as DDTor PCB (Fedtke, 1982; Hoagland and Duke, 1982).
The decrease in chlorophyll a pigment of phytoplankton with the increase
in concentration of the toxicant was reported by Bharati et a/. (1979), Tukaj (1987),
Morales-Loo and Goutz (1990), Herman ef a1 (1991) and El-Dib eta/. (1997). Lemee
et al. (1997) suggested that ecotoxicity could reduce chlorophyll a content. Contrarily
Hein and Rieman (1995) noticed that chlorophyll a pigment remained unchanged in
the higher concentrations of toxicants. At higher concentration of the effluent the
mineral contents will increase considerably and this may interact adversely with
the physiological condition necessary for the synthesis of chlorophyll.
The blochemica1 compounds protein and carbohydrate content showed
variations when treated with petrochemical factory effluent. Lower concentrations
stimulated the protein content in Chlorella ellipsoidea Gerneck, Ankistrodesmus
falcatus (Corda.) Ralfs and Scenedesmus bijuga (Turp.) Lagerheim. All the
concentrations administered enhanced the protein content in Haematococcus
laccustris (Girod.) Rostafinski and Chlorococcum humicola. (Naeg.) Rabenhorst.
Carbohydrate content showed higher values in the lower concentrations exposed
Chlorella ellipsoidea Gerneck, Scenedesmus bfjuga (Turp.) Lagerheim,
Haematococcus laccustris (Girod.) Rostafinski and Chlorococcum humicola (Naeg.)
Rabenhorst cells. All the concentrations stimulated the carbohydrate content in
Ankistrodesmus falcatus (Corda) Ralfs.
The effluent may undergo biodegradation and the resulting compounds
may act as nutrients in the medium. Naturally, the treated cells may absorb more
nutrients during the exponential growth phase resulting in the increased protein content.
Cochrane (1958) reported that the increase in total protein- nitrogen is
a real sign of increase in cytoplasm. Collyer and Fogg (1955), Lewin and Guillard
(1963) were of the opinion that the decrease in protein level was caused by an
insufficient nitrogen level in the nutritive medium. In the present investigation, protein
content in Chlorella ellipsoidea Gerneck, treated with higher concentrations showed
reduced protein content though the control and the treated cultures were provided
with same quantity of nutrients. At higher concentrations, perhaps due to external
stress treated algal cells might not have performed well in the medium. This might
be resulted in the reduction of protein and carbohydrate content.
Inverse relationship between concentration of effluent and biochemical
compounds in algae was investigated by Tukaj (1987). The effects of petroleum
hydrocarbons on the modification of physiological and biochemical processes were
reported by Zachleder et a/. (1983), Vander meulen and Lee (1986).
The present investigation revealed that the effect of effluents on the
algae was highly different. The three effluents affected the growth in the five species
which varied with the concentration of the effluent as well as with the age of the
phytoplankton. The perturbation of the aquatic environment by a variety of pollutants
causes disturbances to the abiotic as well as biotic characters. Since algae are
representing the lower trophic level, these disturbances could be reflected in the
whole ecosystem.
4.4 Muvattupuzha river
Muvattupuzha river is one of the major perennial rivers in Central Kerala.
Muvattupuzha river empties into Cochin estuary which has a permanent opening,
Cochin bar mouth, through which tides affect the inland water courses. The pulp-
paper mill factory, Hindustan Newsprint Limited situated on the bank of the
Muvattupuzha river, discharges its effluents into the river.
The pulp-paper mill effluents carry heavy load of biodegradable organic
substances (Hunter and Faust, 1971) and other pollutants (Klein, 1957; Todd, 1970).
The major by-products of this industry consist of the breakdown products of lignin
and some amount of cellulosic material (Dugan, 1972). The effluents from the pulp
paper factories cause water pollution and affect the riverine biota.
Temperature values were minimum during post-monsoon season and
maximum during pre-monsoon period. The temperature fluctuation observed was
mainly due to the discharge of effluents and atmospheric variations. Menon et a/.
:: 160 ::
(1977) and Ramesha et a/. (1992) reported the temperature fluctuations in the
surface waters of Mangalore. The variations in temperature affect the rate of reactions.
In all the four stations, fluctuations in pH were observed. pH was \OW
during post monsoon season. pH variation in Muvattupuzha river was investigated
by Balchand and Nambisan (1986) who reported that these fluctuations in pH
occurred due to the discharge of effluent. Desirable public water supply should
have a pH as close to 7 as possible (Nelson, 1978). Webb (1982) commented the
undesirable nature of both acidic and alkaline wastewaters from paper mills for
recreation and rearing of fish and other aquatic life.
Hardness in the river water in all the stations showed low values during
monsoon. Alkalinity in station I was lower than the other stations. High values for
alkalinity at station 11, Ill, and IV were due to the impact of the elT?uents.
Salinity values were high during pre-monsoon period and low during
monsoon period. According to Abe eta/. (1996) salinityvariations in the downstream
showed correlation with tides, while upstream showed less correlation with tidal
fluctuations in Muvattupuzha river.
Free carbon dioxide produced in the natural unpolluted water can cause
acidity. In the present investigation, the concentration of free CO, was low.
Comparatively higher values were observed during post-monsoon period. Total
solids, both the suspended and dissolved solids were low in the river water as
compared to standard values. Total dissolved solids were higher during pre-monsoon
period and high values for totakuspended solids were observed in post-monsoon period.
Dissolved oxygen in all the sampling stations exhibited decreased values
and was comparatively higher during monsoon. Balchand and Nambisan (1986)
reported the same trend in Muvattupuzha river. The effluents discharged into the
river had low dissolved oxygen content, which in turn lowered the dissolved oxygen
of the river water. The current observations are in accordance with that of Votintsev
(1993) who noticed that effluents from pulp paper plants lower the oxygen content
of water. The concentration of dissolved oxygen in natural water depends on various
factors such as temperature, partial pressure of oxygen in the atmosphere, salinity,
biological processes like oxidation and reduction, degradation of organic matter,
respiration etc. Rate of depletion of oxygen has been used to investigate the quality
of water bodies Wahby et a/., 1978). In the opinion of De Sousa and Sen Gupta, (1986)
studies on salinity dependent oxygen solubility may help to elucidate the various
physical, chemical and biological processes taking place in estuarine waters.
The carbon production in the river water fluctuated seasonally. Both grass
and net production revealed higher values during monsoon period, while the values
were low during pre-monsoon period. Seasonal variations in productivity were
reported by Schallenberg and Bums (1997), Postma (1954) and Tillmann et a/. (2000).
Biochemical oxygen demand (BOD) in thesampling stations 11. Ill and IV
were comparatively higher than station I. BOD was minimum during monsoon months
and was higher during pre-monsoon period in these sites. The high BOD recorded
in the sampling stations indicates the pollution intensity of the effluent. High BOD
values in Muvattupuzha river, as a result of effluent discharge were earlier noticed
by Balchand and Nambisan (1986).
162 , .
Chemical oxygen demand (COD) values were lower during monsoon
season and higher during pre-monsoon season in all the sampling stations. The
high values of COD recorded in the Muvattupuzha river were due to the effluent
discharge from the pulp-paper mill. During monsoon month, the rainwater diluted
the effluents and it resulted in the decreased COD values from June to December.
The silicate values exhibited fluctuations during the present study. Wide
variations in salinity were also noticed during the period of study.
Nitrate and nitrite contribute about 65% of soluble form of nitrogen
(Martin, 1970). Thermodynamically nitrate is considered as the most stable form of
nitrogen in seawater (Sillen, 1961; Grasshoff. 1983). In the present investigation,
the concentration of nitrite was found to be low while higher values were noticed in
the case of nitrate. However, increased nitrite and nitrate concentration was
observed in Muvattupuzha river by Balchand and Nambisan (1986).
Phosphate content in all sampling stations showed higher values. The
increase in phosphate content observed in the river water was mainly due to effluent.
Another factor that contributed to the enhanced phosphate content was the inputs
from detergents. Balchand and Namb~san (1986) reported four, eight and three
fold increase in nitrate, nitrite and phosphate respectively in Muvattupuzha river
before and after the installation of pulp-paper mill factory. Hydrolysis of condensed
phosphates such as polyphosphates and metaphosphates produces
monophosphates. Production of monophosphates from hydrolysis is expected in
estuaries as a result of pollution from detergents (Koroleff, 1983 b).
4.5 Chitrapuzha river
Industrial effluents are one of the important sources of water pollution.
The disposal of industrial effluents without affecting the biota of the surrounding
system has become a serious concern. The limits of use and abuse of rivers and
estuaries, which supply freshwater and receive effluents from industries, are
determined by biogeochemical cycles, which can affect the water quality. Chitrapuzha
river, a subsidiary of Periyar river is a part of Cochin estuary. It receives effluents
from a major fertilizer plant, an oil refinery, and a petrochemical factory.
Analysis of physical parameters of Chitrapuzha river revealed the lowest
temperature during post monsoon period followed by monsoon period. Temperature
values were high during pre-monsoon period. Similar observations in temperature
were made by Pillai et a/. (1975) and Balakrishnan and Shynamma (1976). The
variation in temperature was mainly due to the atmospheric temperature and due
to the influence of effluents.
The pH at all the four stations showed low values during post monsoon
and pre-monsoon period. Variations in pH of any water body depend on
photosynthetic activity, discharge of industrial effluents, nature of dissolved
materials, rainfall etc. Changes occurring in pH due to chemical and other industrial
effluents render a stream unsuitable not only for recreational purpose but also for
the rearing of fish and other aquatic life (Webb, 1982). The major factor which
altered the pH in Chitrapuzha river is the discharge of effluents from the major
factories located on the banks of the river. Close monitoring of pH values enables
the identification of zones of pollution (Clark eta/., 1977). Under extreme conditions
survival of the aquatic biota becomes a serious problem. Since the tolerance level
of most organisms to alterations in the pH is quite narrow (George, 1979), the
extreme conditions would cause serious problems to the survival of the biota.
Hardness of the water exhibited high values during pre-monsoon period, compared
to other seasons, but it was not too high to cause adverse impact on the biota.
Determination of alkalinity of water is significant in many of its uses and
treatment of natural waters and wastewaters. Alkalinity showed higher values during
post-monsoon season. In all stations it was lower than 100 mg L-I, which is the
desirable limit in drinking water.
Salinity in all the stations showed increased values during pre-monsoon
season. Similar variations in salinity due to monsoon and influxes of seawater were
reported by Gopinathan (l972), Quasim and Sankaranarayanan (1972) and Mathew
and Nair (1980).
Free carbon dioxide which is formed mainly due to the activity of
microbes, was found to be low during pre-monsoon period in Chitrapuzha river.
The total suspended and dissolved solids alter the water quality, for the suspended
solids cut down the light transmission, while total dissolved solids elevate the density
of water and also retard the palatability of water. The river exhibited increased
values for total dissolved and suspended solids during pre-monsoon season.
Dissolved oxygen in fresh water is low and only 10.66 mg L-' at 30°C
under normal atmospheric pressure. The depletion of oxygen content in water leads
to the undesirable obnoxious odour in the aquatic system (Doudoroff Shumway
.- 165 ~,
and Peter, 1970; Nelson, 1978) and damage to aquatic life. Adequate dissolved
oxygen is necessary for the survival of flora and fauna. The decomposition of organic
waste and oxidation of inorganic waste may reduce the dissolved oxygen to
extremely low levels, which may prove harmful to organisms in the aquatic
environment. Johannessen and Dahl (1996) have reported a decline in dissolved
oxygen as a result of nutrient load.
In the present investigation the dissolved oxygen was low in all Stations
during pre-monsoon due to the combined effects of temperature, photosynthetic
action and biochemical oxidation of wastes entering the environment. Similar
observations were made by Babu Jose (2000) in Chitrapuzha river. Bandyopadhyay
and Dutta (1986) and De Sousa and Sen Gupta (1986) noticed the decreasing
solubility of oxygen in water with increasing salinity and temperature. The results of
the present investigation also tally with the earlier observations.
Productivity in the present work showed variations with changing
seasons. Productivity was high during post monsoon period and low during pre
monsoon period. Increased primary production during post monsoon was reported
by Chellappa (1990). Two specific features which promote high and stable
photosynthetic production are incident solar radiation and light saturation for
photosynthesis (Lewis, 1978) and high water temperature that enhanced the specific
production at optimum depth (Harris. 1978).
Eventhough BOD of the effluent discharged by petrochemical factory
remained in the tolerance limit, the high BOD values were observed in all the
sampling stations. This increased BOD values may be due to the adverse effect of
the effluent released from a major fertilizer plant and the refinery situated nearby
the petrochemical factory. The increased BOD values indicate the high degree of
pollution of the aquaticsystem.
Similar to BOD, chemical oxygen demand in four stations showed
enhanced values. The COD values were comparatively low during monsoon period
indicating the dilution occurred as a result of rainwater.
The nutrients in Chitrapuzha river showed greater values during the
present work. The silicate concentration showed higher values during pre-monsoon
and lower values were observed in post monsoon period. Fluctuations in silicate
concentrations by effluent were reported by Krishnamoorthi (1985) and Katti et al.
(2001). Similar results were obtained in the present investigation too, where silicate
content in all the stations exhibited high degree of variations.
The concentration of various forms of nitrogen is controlled by factors
like input rates, interconversion reactions occurring within the water column,
denlrification, deposition etc. Nitrates enter into the waterway through anthropogenic
sources, fertilizers and some industrial effluents. Nitrate-nitrogen in all the four
stations showed fluctuations. Manikoth and Salih (1974) recorded the variations in
nitrate-nitrogen in Cochin estuarine complex.
Industrial effluents mainly contribute to the changes in the concentration
of nitrite nitrogen. The effluent discharge from the fertilizer factory is the major
cause for the enhancement of nitrogen compounds in Chitrapuzha river. Higher
values of nitrate nitrogen in the sample stations contributed to the abundant
phytoplankton growth in these regions.
- 167
Phosphate availability in water stimulates the growth of phytoplankton.
Phosphate abundance causes phytoplankton boom, a phenomenon known as
eutrophication (Rand et al. 1986). Subsequent decay of phytoplankton causes
oxygen depletion. Relatively high concentration of phosphate during pre-monsoon
period indicates the intensity of pollution. Comparatively lower values were observed
during monsoon in the present investigation. Several workers have made similar
observations in Cochin estuary (Joseph, 1974; Lakshmanan et a/., 1987 and
Anirudhan, 1988). Babu Jose (2000) reported high concentration of phosphate at
certain part of Chitrapuzha river during monsoon period because of leaching from
land drainage.
4.6 Cochin estuary
Cochin estuary, a semi enclosed coastal body of water has free access
with open sea and within which the seawater is measurably diluted with fresh water
derived from land drainage and hence it is in full agreement with the definition of
Pritchard (1967). Cochin estuary is a tropical estuary with a chain of brackish water
lagoons and swamps and is rich in aquatic life. The major sources of fresh water
are Periyar river and its tributaries viz. Chitrapuzha and Kadambaripuzha river in
the South. A channel, about 450 m wide at Cochin gut is a permanent link with
Arabian sea which transmits the tidal energy and saline water into the estuary. The
barmouth at Azhikode also helps the estuary to interact with the sea, though the
influence is only to a lesser extent due to the shallow nature of the channel. Rainfall
and fresh water discharge influence the penetration effect of saline water into the
estuary. During southwest monsoon the estuary is virtually converted into a fresh-
water basin except in areas around the barmouth.
The effluents released into Periyar and Chitrapuzha by most of the
industries situated on their banks finally reach Cochin Estuary. On the southern
part of the estuary, a distillery (Mc Dowells Distillery) is situated, which is emptying
the effluent directly into the estuary. Distillery effluents are having low pH, high
BOD, COD, total dissolved solids and other organic and inorganic components. It
is darkly coloured
Temperature of estuaries affects the physical properties of water and
can cause stratication in ambient water. The distribution of temperature in estuaries
depends on the mixing of tidally influenced sea water (Ramamirthan and Jayaraman,
1963), flow of fresh water from rivers (Sankaranarayanan and Qasim, 1969) and
processes like exchange of heat from atmosphere and other localised phenomena.
In the present study, temperature values were low during postmonsoon
and monsoon periods and high values were observed during pre-monsoon.
Balakrishnan and Shynamma (1976) reported high water temperature in Cochin
estuary during pre-monsoon period. Similar variations in temperature were
documented by Gopinathan (1972), Pillai eta)., (1975) Kumaran and Rao (1975),
Ramamirthan et a/., (1986), Joseph (1988) and Siadasan (1996). Sankaranarayanan
and Qasim (1969) stated that influx of fresh water into the estuarine system is not
the sole factor influencing the water temperature in a estuary, but the influx of cold
water from the sea may also be a significant factor.
Low pH values were noticed in all sampling stations and these decreased
values were in correlation with the discharge of acidic distillery effluent. Earlier
workers noticed pronounced seasonal variations in pH in Cochin estuary. Anirudhan
169 .:
(1988) reported neutral pH values during monsoon months. The pH values increase
seasonally upto post monsoon period and may be attributed to the excessive
photosynthetic activity of the algae. High phytoplankton production during post-
monsoon period in Cochin estuary was recorded by Silas and Pillai (1975). Nair et al.
(1983) observed decrease in pH from marine to freshwater zone in Ashtamudy
estuary.
Hardness and alkalinity in all sampling stations showed higher values
during pre monsoon and lower values in monsoon as well as post monsoon period.
Salinity in all sampling stations exhibited very high values during the present
investigation. A comparative decrease in salinity was noticed in all stations from
June onwards. The high salinity in pre monsoon season was due to closure of the
shutters of Thannermukkam bund on the southern side of the Cochin estuary. The
opening and closing of the shutters of this bund alter many of the physical properties
of the water.
Salinity variations in Cochin estuary were reported by Quasim and
Sankaranarayanan (1972), Haridas et a/. (l973), Gopinathan (1975), Balakrishnan
and Shynamma (1976:I, Sivankutty (1972) and Gopakumar (1991). Maqbool(1993)
reported wide fluctuations in salinity at tropical estuaries due to the extreme
conditions of drought and monsoon affecting the estuarine environment. A distinct
seasonal pattern of salinity in the Ashatamudi during pre monsoon and declining
values from estuarine mouth to the riverine zone were reported by Nair et.al. (1983).
Free CO, values in all the four stations displayed lower values during
monsoon and post monsoon periods. Free CO, values were high during pre-
monsoon. The fluctuation in free CO, was due to the impact of effluents as well as
microbial respiration (Maiti, 2001 ).
Total dissolved and suspended solids were high in all stations during
pre-monsoon period and lower values were observed during monsoon and post
monsoon periods. Dissolved oxygen values highly fluctuated during the sampling
period. Stations 11, Ill and IV showed absence of dissolved oxygen during pre
monsoon season. High concentration of distillery effluent and closure of the shutters
of the Thanneermukam bund resulted in the depletion of dissolved oxygen. Another
major factor, which led to the anoxic condition, was retting of coconut husks in
these areas. According to Aziz and Nandan (1995) and Arjinkit (2000) the hypoxic
as well as anoxic condition can be resulted due to the retting of coconut husks.
Nandan (1996) reported hypoxic and anoxic conditions in the backwaters of Kerala.
Anoxic condition leading to fish death was reported recently in Cochin estuary
(Malayala Manorama. 2004). Reduction in dissolved oxygen during pre-monsoon
season in Cochin estuary was documented by earlier workers like Pillai et.al. (1975)
and Kumaran and Rao (1975).
The gross and net carbon production in all the four stations displayed
seasonal variations. In the present investigation, stations 11, Ill and IV recorded
very low carbon production. Decrease in productivity shows the depletion of biota
in these areas. Destruction of flora and fauna in the backwaters due to organic
pollution was reported by Nandan (1995). Seasonal variations in primary production
were also revealed in the present study.
Silas and Pillai, (1 975) and Nair et a/. (1975) suggested high phytoplankton
production during post monsoon period in Cochin estuary and this agrees with the
current observation. Gopinathan eta/. (1984) reported correlation between primary
productivity and factors such as phosphate, nitrate, dissolved oxygen and
temperature in Cochin estuary.
Seasonal fluctuations were observed in BOD values in the four stations
studied. Higher values were observed during pre-monsoon period. The high BOD
in these sampling stations was contributed by distillery effluent, retting of husk, the
periodical closure of bund shutters, water transport services etc. Pre-monsoon
period recorded higher values for COD and lower values were registered in the
monsoon and post monsoon period. The factors which are contributing high BOD
can promote the COD values also.
Wide fluctuations were observed in silicate concentration, which was
higher during pre-monsoon period and lower during monsoon and post monsoon
period. Gopinathan (1975) reported high silicate concentration during monsoon
period in Cochin estuary.
Nitrite and nitrate concentrations in the stations were high during pre-
monsoon season followed by monsoon and post-monsoon seasons. Increased or
decreased nitrite and nitrate content in Cochin estuary were recorded by
Sankaranarayanan and Quasim (1969), Manikoth and Salih (1974), Gopinathan
(1975), Lakshmanan et a1 (1987), and Anirudhan (1988).
Phosphate concentration in all the sampling stations showed great
variations during the period of investigation. Biogeochemistry of phosphorus in
estuaries is controlled by a combination of physical, chemical and biological processes
like addition of phosphorus to the system, by input, decomposition of particulate
matter, removal of phosphorus from the system by precipitation and up take (Martin 1970).
Rivers are the major source of phosphorus input into estuaries. The
riverine influx of phosphorus in estuaries may be substantially modified by
precipitation or dissolution, causing changes in the concentration of phosphorus
(Fox etal., 1985). The weathering of insoluble calcium and fenic phosphate rocks and
land drainage especially from agricultural run off also deliver phosphorus to estuaries
(Martin 1970). The other sources are domestic sewage and industrial effluents.
Stud~es relating to phosphate content in Cochin estuary were done by
many scholars and they observed marked seasonal variations with high phosphate
content during pre monsoon ( Qasim and Sankaranarayanan, 1972; Joseph, 1974;
Lakshmanan et a/. , 1987; Anirudhan, 1988; and Balchand etal., 1990).
During the present investigation species diversity of phytoplankton
showed considerable seasonal variations. Chlorophycean members were noticed
throughout the period of study. Cyanophycean members dominated in the pre
monsoon period of maximum pollution. In the monsoon and post monsoon seasons,
diatom communitiis predominated and this may be attributed to the increased salinity
of these seasons (Gopinathan.1975).
Dumping off the effluents into the waterbodies could create severe threat
to the aquatic environment. In the present investigation a systematic and
comprehensive study on the physico-chemical characteristics was made to assess
the water quality of Muvattupuzha river, Chitrapuzha river and Cochin estuary. It
was found that the intensity of pollution was higher in Cochin estuary and
Chitrapuzha river compared to Muvattupuzha river.