Ecological Engineering a b s t r a

Ecological Engineering a b s t r a c t
In search of low-cost eco-tech for the reclamation of municipal domestic wastewater, tomato plants
(Lycopersicum esculentum) were cultivated on the floating bed of pulp-free coconut fiber over four different
concentrations of wastewater (25%, 50%, 75% and 100%) and groundwater as control, in 10 L plastic bucket
for two months. The study revealed that PO4-P was removed by 58.14–74.83% with maximum removal
at 50% wastewater. More than 75% removal of NO3-N was observed in all treatments. Both COD and
BOD were reclaimed highest at 100% wastewater by 61.38% and 72.03%, respectively. Ammonium-N
concentration was subsided below the toxic level in all the treatments. The population of coliform bacteria
(Escherichia coli) was reduced to 91.10–92.18% with maximum efficiency at 100% wastewater. Growth
performance was observed relatively better at 100% wastewater. Crop production as the value addition
of this technology was also recorded maximum at 100% wastewater. The bioaccumulation of Cd and Ni
in tomato crop was far below the threshold level, but the bioaccumulation of Pb and Cr was above the
safe level by 80 times and 660 times, respectively. The aquaponically reclaimed water can be reused in
agriculture, aquaculture and industrie

1. Introduction
Wastewater reclamation by low-cost ecotechnology is one of
the challenging issues at present in wastewater management. In
wastewater-fed agriculture, nutrients flow from wastewater into
plants that expedite nutrient removal from wastewater coupled
with the production of crop, leaf or flower as a value addition for
human consumption or human aestheticism.
Many economically important vegetables and flowering plants
can utilize the major nutrients (NO3-N, NH4-N and H2PO4/HPO4-
P) for their growth from the nutrient-rich wastewater upon proper
management or suitable amendments. Plant growth and crop and
flower yield eventually may lead to nutrient removal from the
wastewater that results in the reclamation of sewage water. This
concept may be applied as a method for ecological treatment of
wastewater.
Traditional hydroponics has been primarily used for increasing
crop production under controlled conditions by supplying balanced
nutrients in solutions. A large number of vegetables and crops such
as beets, radishes, carrots, potatoes, cereal crops, fruits, ornamentals
and seasonal flowers can be grown on inert supportingmedium
instead of soil (gravel, sand, peat, rock-wool, perlite, vermiculite,
coconut fiber, sawdust, crushed rock or bricks, shards of cinder
blocks and even Styrofoam) wetted with nutrient media prepared
by mixing all essential elements and water (Jensen and Collins,
1985; Runia, 1995).
Domestic wastewater is potentially rich in nutrients and has
traditionally been used as an important source of fertilizers for
either agriculture or aquaculture in many developed and developing
countries (Edward, 2000; Jana, 1998; Jana and Jana, 2002).
Boyden and Rababah (1996) used a commercial hydroponic system
for the cultivation of lettuce, capsicum, corn and tomatoes in settled
primary domestic wastewater but no attempt has so far been
made to couple the processes of eco-reclamation of wastewater
with biological production of some economically important vegetables
and crops that will not only reduce the cost of wastewater
treatment process but also yield some revenues in the form of agricultural
crops. The beauty of this approach is due to the fact that
wastewater provides all the essential elements required for plant
growth, and the wastewater, in turn, is reclaimed by the removal
of excess nutrients through the bio-process of crop production.
The net outcome of this modified system is the reduction of fertilizer
cost for crop production as well as the cost of wastewater
treatment. As a result, a large number of eutrophic wetlands and
water bodies which remain unutilized can be exploited by farmers
for the cultivation of various economically important crops using
wastewater. Morin (1996) has provided different strategies for
the cultivation of commercial greenhouse crops in sewage water.
However, the probability of infection for a single ingestion event
of NFT (Nutrient Film Technique) in growing lettuce on primary
treated municipal effluent was about 1.7% for viruses (Rababah and
Ashbolt, 2000).
The infestation of faecal coliform bacteria is a great concern in
wastewater agriculture and aquaculture. The strain of Escherichia
coli (0157: H7) can cause serious illness in human. A recent
outbreak of colitis disease by this strain generated much public
disquiet. Though most of the cases were reported from eating
under cooked hamburger (New York State Department of Health,
2005), yet there is a possibility of transmission of the strain through
the plant parts. Drinking water contaminated by this bacterium
through water supplies is rare (New York State Department of
Health, 2005).
But the heavy metals in wastewater (Cd, Pd, Cr, Ni, etc.) can be
accumulated within leaf and crop tissue as organo-metallic compounds
that can create metal toxicity in human body when the
leaves and crops are consumed. Even this accumulation depends
directly upon the concentration of heavy metal in wastewater. So,
the feasibility of implementing this eco-tech for wastewater reclamation
massively must be cautions of heavy metal accumulation
in leaf and crops{AQ clarity}.
The present experiment was conducted to evaluate the efficiency
of the eco-tech “tomato plant aquaponics” in wastewater
reclamation coupled with crop yield as a by-product.
2. Materials
2. Materials and methods
The present study was performed in fifteen 10 L plastic buckets
(4 treatments and one control in triplicate). Buckets were filled
with several concentrations of domestic wastewater (25%, 50%, 75%
and 100%). Concentrations were prepared with groundwater. The
domestic grey wastewater was collected from the Grit Chamber of
Sewage Treatment Plant of Kalyani Municipality.
The tomato plant was selected for the study because the
crop tomato was enriched with anticancer compound “lycopene”.
Healthy tomato plants (Lycopersicum esculentum) of ten days old
were procured from a local nursery and were then implanted in
the matrix of pulp-free coconut fiber (3 in.×3 in.×1 in.) as per one
plant in one bed and three plants in one bucket. Mats were supported
with rectangular piece (4 in.×4 in.×2 in.) of thermocol as a
float. Plants were allowed to float on the surface of bucket water.
The growing plants were supported externally by bamboo sticks to
hold the shoot upright. Thus the tomato plants were cultured for
two months (December, 2004–January, 2005) outdoors under natural
conditions. After two months, the crops were harvested from
the plants. Index leaves and roots were collected and finally all the
plants were removed from treatment water.
Dead leaves that fell on the treatment water were removed
instantly. Algal slag and Spirogyra that grew during culture were
also removed carefully. Water loss due to sampling and evaporation
was replenished with the addition of distilled water. The water
level was monitored to keep it constant at every moment during
the period of investigation.
The growth performance and yield of the tomato plant were
investigated by measuring biomass, number of leaves, chlorophyll
content in index leaf, number of twig, stem length, shoot–root
ratio, nitrate reductase (NR) activity in root, crop number and crop
mass. Nutrient removal from different treatments by the capacity of
tomato plant was determined by monitoring the different nutrient
quality parameters (PO4-P, NH4-N, NO2-N, NO3-N) of bucket water
before and after tomato plantation. The state of ion absorption and
respiration in root was reflected from the water quality of temperature,
pH, alkalinity and dissolved oxygen (DO). Ion arrest through
adsorption by organic matter in wastewater has been assessed by
the quantification of chemical oxygen demand (COD). Possibility
of faecal coliform transmission from wastewater to human and
colitis disease in human have been investigated through the quantification
of population size of E. coli in wastewater as it is the
major species in the faecal coliform group and is the best indicator
of faecal pollution and possible presence of pathogens. Heavy
metals were estimated from crop to depict the potency of bioaccumulation,
whether it is safe for human consumption.
Parameters were measured following standard methods cited
in Appendix A. Heavy metals (Cd, Cr, Pb and Ni) were estimated
using a Flame Atomic Absorption Spectrophotometer (Company:
Varian, Australia and Model: AA 240).
All tabulated data were represented as arithmetic mean (x−)
of three samples (n = 3) for water quality and of nine samples
(n = 9) for biological parameters. The error due to sampling was
measured as standard error of mean (±SE). The variances among
different treatments were analyzed by one way ANOVA and their
multiple comparisons were analyzed by Tukey’s test. One way
ANOVA and Tukey’s test were performed in statistical package
(SPSS-10.0). Variances were accepted when the probability of variance
(P) < 0.05.
3. Results
The reclamation efficiency of the eco-tech is the direct function
of the growth performance of tomato plants. So all findings have
been taken from the aspect of growth performance of plant, pollutant
reclamation efficiency and the feasibility (pathogenic and
heavy metal bioaccumulation) for human consumption of its products
(crop).
3.1. Plant growth
3.1.1. Shoot length
The average shoot length of tomato plants grown in different
strengths of wastewater ranged from 11.81±1.07cm (in control)
to 55.0±2.38cm (in 100% wastewater) (Table 1). Shoot length
increased with the rise of strength of wastewater. The maximum
length observed in 100% wastewater was 4.7 times of that of
control. The variances in shoot length in all pair combination of
treatments were statistically signific