The hydroponic production of lettuc

The hydroponic production of lettuce (Lactuca sativa L) by using hybrid catfish (Clarias macrocephalus×C. gariepinus) pond water: Potentials and constraints
3. Results
The average maximum daily air temperature was 35.7±2.8 ◦C while the average minimum daily air temperature was 22.7±3.2 ◦C (Fig. 2). The average relative humidity was 69.8±7.3% while solar radiation was 17.6±2.9 MJm−2 (Fig. 2). The experiment was con- ducted during the dry season (February to March) and no rainfall was recorded during the experiment period.
3.1. Catfish pond water quality
Water temperature varied within a narrow range of 28.9–30.9 ◦C throughout the experimental period. The mean concentration of TSS was 70.2±3.6mgL−1 and DO content at dawn ranged from 0.40 to 1.24mgL−1 (Tables 2 and 3). Mean TAN, NO3− nitrogen, TP and SRP concentrations of fishpond water during the experiment are presented in Tables 2 and 3. Thus 90 L of unfiltered pond water per irrigation supplied on average 218, 275, 67 and 4.5mg of TAN, NO3 − nitrogen, TP and SRP per hydroponic unit, respectively.The average concentration of K, Ca, Mg, Mn, Fe, Zn and Cu in the catfish pond water is presented in Table 2. There was a decreasing trend of NO3-nitrogen and dissolved oxygen content in the pond water with time, however, dissolved oxygen increased towards the end of the experiment. Total alkalinity and total hardeness fluctuated but pH remained stable throughout the experiment (Table 2). TAN and total phosphorus increased as the experiment progressed.
3.2. Effect of filtration on concentration of nutrients
Filtration reduced total phosphorus and total suspended solid concentrations by 32 and 61%, respectively, (Table 3) and this resulted in a relatively lower TP content of the filtered water. Contrary, filtration increased SRP content of water significantly (P < 0.05). It was calculated that 90 L of pond water per irrigation supplied on average 205, 327, 19 and 34mg of TAN, NO3-nitrogen, SRP and TP per hydroponics unit, respectively. Concentration of NO3-nitrogen, TAN and TKN were not significantly different between filtered and unfiltered pond water (Table 3).
3.3. Fish growth
Since the primary objective of this experiment was to develop design protocols for an integrated catfish–vegetable hydroponic system, catfish growth trial was not replicated. Results showed that hybrid catfish grew steadily over the 233 days from an individ-ual initial weight of 6.58±1.72 g to a final mean body weight of 247.23±108.7 g. The gross and net yields of catfish from 226m2 pond were 7.01 and 6.78 kgm−2, respectively. Specific growth rate (SGR %), % survival rate (SR %) and food conversion ratio (FCR) of fish were 1.56% day−1, 80.09% and 2.29, respectively (Table 4).
3.4. Lettuce yield
The statistical analysis revealed that there was no interactive effect between water filtration and growth media but the main effects of these parameters on lettuce yield and head weight were significant. Treatments supplied with filtered catfish pond water had significantly higher yields (P < 0.05) than those supplied with unfiltered pond water (Table 5). Filtration increased lettuce yields by 87, 63 and 52% in the control, gravel, and sand treatments, respectively. The highest head weight and lettuce yield (P < 0.05) were observed in the sand treatment followed by gravel and the control treatments respectively (Table 5).
3.5. Nutrient content of lettuce plants
Phosphorus content in the lettuce plant tissue was significantly higher (P < 0.05) in plants supplied with unfiltered pond water. However, nitrogen content of lettuce was significantly higher in plants supplied with filtered pond water (Table 6). Lettuce grown on sand growth medium had significantly higher P content than plants grown in the control and gravel treatments (P < 0.05; Table 6). Lettuce plants grown in gravel growth medium had significantly higher nitrogen content (P < 0.05) than plants in control and sand treatments. Calcium and zinc content in the lettuce plants were not different between plants supplied with filtered and unfiltered catfish pond water, while potassium, iron, manganese and copper were higher in lettuce plants supplied with filtered catfish pond water than unfiltered treatments (P < 0.05; Table 6). Potassium and zinc contents were not different in lettuce plants grown in sand and gravel media but were higher than in control treatment. Contents of calcium, iron, manganese, zinc and copper in the lettuce plant were higher (P < 0.05) in plants grown in sand medium than control and gravel treatments (Table 6).

A study on the optimal hydraulic loading rate and plant ratios in recirculation aquaponic system
The result
3. Results and discussion
3.1. Effect of hydraulic loading rates Specific growth rates (SGRs), feed conversion ratio (FCR) and fish production did not differ significantly between hydraulic loading rates (Table 2). FCR values are in the range of 1.23–1.39. In our study, the same feed is used and the ration is fixed similarly in all culture tanks. Stocking at hydraulic loading rate of 1.28 m/day gives the best production performance (Table 2). The FCR recorded (1.23–1.39) is not far above the ideal value of 1.0 for culture of African catfish in recirculation system and FCR value 0.85 reported in the culture of African catfish by Eding and Kamstra (2001). However the recorded FCR are better than the range 1.1–1.7 reported in recirculation system of African catfish as reported by Akinwole and Faturoti (2007). HLR did not affect growth rate or feed conversion ratio.Plants grew actively in the hydroponic trough and did not identify any nutritional deficiencies or mineral imbalances. Plant production increased as the hydraulic loading rate increased from0.64 m/day to 1.28 m/day, whereas an increase in the HLR from 1.28 m/day to 3.20 m/day did not result in a higher plant production.At the end of the growth period (20–28 days), the plants reached the market size at average height of 45–50 cm. Whole plant water spinach growth rate and yields differ significantly between hydraulic loading rates (Table 2). Plant growth rate and productions differ significantly between HLR. The growth decreased significantly with increasing in HLR supported the development of aerobic conditions in the hydroponic trough and hindered denitrification processes. Nevertheless, low HLR with lower out flowing oxygen contents promoted denitrification and highest NO 3 —N elimination is observed in lower hydraulic loading rate (0.64 m/day and 1.28 m/day). Average plant productions are 17.63 kg, 17.90 kg, 17.53 kg, 17.03 kg and 16.83 kg for HLR 0.64 m/day, 1.28 m/day, 1.92 m/ day, 2.56 m/day and 3.20 m/day, respectively. The decrease in production corresponded strongly concludes that insufficient N in the influent could be a limiting factor for a further increase in plant production. An increasing of HLR might diminish the contact time for nitrate and denitrifying bacteria, thus decreasing the performance of hydroponic trough for denitrification (Endut et al., 2009). Snow and Ghaly (2008) evaluated the use of barley for the purification of aquaculture wastewater in a hydroponic system and reported the crop yield was significantly influenced by the seed quantity. The major growth-limiting mineral is usually nitrogen and highest growth rates and yields are generally seen when nitrogen is supplied as combination of ammonium and nitrate. Continuous flow operation of the aquaponic system was initiated with a low HLR of 0.64 m/day. The mean value and percentage removal of water quality variables at various HLR are shown in Table
3. It is found that removal percentage of BOD5, TSS, TAN and Nitrite–N increased with increasing in HLR. In contrast to BOD5, TSS, nitrite–N and TAN, removal percentage of nitrate–N and TP increased with increasing in HLR from 0.64 m/day to 1.28 m/day and decreased with increasing in HLR from 1.28 m/day to 3.2 m/day. Statistically, there were significant differences in all water quality parameters by HLR (p < 0.05) as shown in Table 3. The whole treatment, RAS basically showed effective nutrient removal with average reduction efficiency range from 47% to 89.5%. Values of TSS, BOD5, TAN, nitrite–N, nitrate–N and total phosphorus in final effluent from this study are in accordance with the previous studies (Eding and Kamstra, 2001; Schulz et al.,2003; Franco-Nava et al., 2004; Lin et al., 2005; Snow and Ghaly,2008). The optimum hydraulic loading rate can be determined by a compromise between fish and plant productions and removal efficiency. Similar to previous studies (Cottingham et al., 1999; Jamieson et al., 2003), the improvement in TAN removal is paralleled by the increase in NO 3 —N. It can be concluded that the improvement in ammonia removal is due to increased nitrification activity. The accumulation of NO 3 —N in the system indicates that after NH3– N is nitrified, subsequent denitrification is limited. Possible factors that could limit denitrification include inadequate residence/retention time for the sump to denitrify NO 3 —N, the presence of DO, or lack of available carbon in the system. A number of mechanisms are responsible for the removal of NO 3 —N from the wastewater. One mechanism for the removal of NO 3 —N is plant uptake through the root system from the growth medium. A second mechanism for the removal of dissolved solids is microbial assimilation. It may also be assimilated by microorganisms in the water column or by biofilms associated with the root mats of plants (Vaillant et al., 2004). Denitrification activity is reduced if available carbon supplies were low and proceeds only when the oxygen supply was inadequate for microbial demand (Hamlin et al., 2008). In this study, carbon availability may have been inadequate to support high levels of denitrification due to the lack of an established litter layer in the system. If, on the other hand, the influent wastewater itse