One of the important factors determining the success in open sea floating cage farming is the availability of quality seeds of

appropriate size. The commercially available hatchery produced seeds should be further reared to appropriate size before

stocking in the sea cages. The Asian seabass, Lates calcarifer is an important candidate species for open sea floating cage

culture. Availability of seeds of required size is an important bottleneck in the sea farming of this species. To address this

issue, an experiment was conducted in 2007 off Visakhapatnam coast of India in the Bay of Bengal, to study the effect of

different stocking densities on the growth and survival rate of hatchery reared seabass fry. Asian seabass fry with a mean

total length of 23.9 ±3 mm and mean body weight of 0.45±0.05 g were stocked in 5 t FRP tanks with 3.5 t of filtered seawater,

at three different stocking densities viz., 1000, 1500 and 2000 nos. m-3 in triplicate. The fishes were fed with commercial dry

pellet feed (Godrej) at 6-8% of fish biomass. Feeding was done 6 times daily at 4 h intervals . The water quality parameters

were monitored and maintained within the favorable ranges for seabass culture. The growth and survival under different

stocking densities were monitored for a period of 90 days. Results observed from these experimental trials showed that the

specific growth rate (SGR) was inversely proportional to that of the stocking density (p<0.05), and no significant variation

was noticed in the survival rate. An overall biomass production of 1.11 kg day-1 was obtained at a high stocking of 2000 nos.

m-3. The results of the experiment indicated that these high stocking density techniques with proper feeding and water quality

management can be used to produce large numbers of seabass fingerlings of stockable size for open sea cage culture

Anbarasu, M

Dash, Biswajit

Imelda, Joseph

Mojjada, Suresh Kumar

Pattnaik, Phalguni

CMFRI Digital Repository

71Effect of  stocking density on growth and survival of hatchery rearedfry of Asian seabass, Lates calcarifer (Bloch) under captive conditionsSURESH KUMAR MOJJADA1, BISWAJIT DASH2, PHALUGUNI PATTNAIK2,M. ANBARASU1 AND IMELDA JOSEPH31Veraval Regional Centre of Central Marine Fisheries Research Institute, Matsya Bhavan, Bhidiya,Veraval - 362 269, Gujarat, India2Visakhapatnam Regional Centre of Central Marine Fisheries Research Institute, Pandurangapuram,Visakhapatnam -530 003, Andhra Pradesh, India3Central Marine Fisheries Research Institute, Ernakulam North P. O, Kochi - 682 018, Kerala, Indiae-mail: sureshkumar.mjd@gmail.comABSTRACTOne of the important factors determining the success in open sea floating cage farming is the availability of quality seeds ofappropriate size. The commercially available hatchery produced seeds should be further reared to appropriate size beforestocking in the sea cages. The Asian seabass, Lates calcarifer is an important candidate species for open sea floating cageculture. Availability of seeds of required size is an important bottleneck in the sea farming of this species. To address thisissue, an experiment was conducted in 2007 off Visakhapatnam coast of India in the Bay of Bengal, to study the effect ofdifferent stocking densities on the growth and survival rate of hatchery reared seabass fry.  Asian seabass fry with a meantotal length of 23.9 ±3 mm and mean body weight of 0.45±0.05 g were stocked in 5 t FRP tanks with 3.5 t of filtered seawater,at three different stocking densities viz., 1000, 1500 and 2000 nos. m-3 in triplicate. The fishes were fed with commercial drypellet feed (Godrej) at 6-8% of fish biomass. Feeding was done 6 times daily  at 4 h  intervals . The water quality parameterswere monitored and maintained within the favorable ranges for seabass culture. The growth and survival under differentstocking densities were monitored for a period of 90 days. Results observed from these experimental trials showed that thespecific growth rate (SGR) was inversely proportional to that of the stocking density (p<0.05), and no significant variationwas noticed in the survival rate. An overall  biomass production of 1.11 kg day-1 was obtained at a high stocking of 2000 nos.m-3. The results of the experiment indicated that these high stocking density techniques with proper feeding and water qualitymanagement can be used to produce large numbers of seabass fingerlings of stockable size for open sea cage culture.Keywords: Asian seabass, Captive condition, Lates calcarifer, Stocking densityIntroductionThe Central Marine Fisheries Research Institute(CMFRI) has been undertaking open sea floating cageculture experimens since 2007 off Visakhapatnam coast ofIndia in the Bay of Bengal. Among the finfish species, theAsian seabass, Lates calcarifer is considered as one of themost important candidate species suitable for farming inponds and cages in freshwater, brackishwater and marineecosystems (Kungavankiu et al., 1986; Rimmer andRussell, 1998; Anil et al., 2010). The success in open seafloating cage farming depends on the availability of seedsof appropriate size  for stocking. The commerciallyavailable hatchery produced seabass seeds  need to befurther reared before stocking in sea cages. Increasedstocking density during the nursery rearing phase isessential to meet the high demand for advanced seabassfingerlings for farming operations. Density is one of themost deterministic factors in larviculture, affecting socialIndian J. Fish., 60(1) : 71-75, 20131interactions such as aggressiveness (Kaiser et al., 1995;Sakakura and Tsukamoto, 1998; 1999), hierarchicalphenomena (Schreck, 1981) and cannibalism (Hecht andPienaar, 1983; Katavic et al., 1989; Moore and Prange,1994), resulting in variations in size, survival and growthperformance in fish populations (Suteemechaikul andPetchrid, 1987; Papoutsoglou et al., 1998; Hatziathanasiouet al., 2002). The present study was undertaken to estimatethe effect of different stocking densities on the growth andsurvival rate of hatchery reared Asian sea bass,Lates calcarifer.Materials and methodsAsian seabass fry with a mean total length of23.9 ±3 mm and mean body weight of 0.45±0.05 g werestocked in 5 t FRP tank with 3.5 t of filtered seawater atthree different stocking densities  viz.,-1000, 1500 and2000 nos m-3 in triplicate. The fishes were fed with72commercial dry pellet feed (Godrej) at 6-8% of fishbiomass. The feeding was done  6 times daily at  4 hintervals. The tanks were provided with continuous aerationand water was changed daily before feeding. Tanks werecleaned and the uneaten feeds were collected 2 h after thefeeding. Collected uneaten feeds were dried and weighedfor calculating the feeding rate. Water quality parameterssuch as temperature, pH, salinity and dissolved oxygen,were monitored daily using portable instruments, whilecritical parameters such as total ammonia (NH3) and nitrite(NO2) were measured on alternate days following standardmethods (APHA, 1998). The growth and survival underdifferent stocking densities were monitored for a period of90 days.The main performance variables were calculated usingthe following formulae:Survival (%) = (number of fish harvested/number offish stocked) × 100.Specific growth rate (SGR) = [lnWt2-lnWt1 × (t2-t1)-1]× 100 where: Wt2=final weight (g), Wt1=initial weight (g)and t2-t1=number of days.Feed conversion ratio (FCR) = total amount of feedconsumed (kg) / biomass increase (kg)Data from each treatment were subjected to one-wayanalysis of variance (ANOVA). Means were compared  byTukey’s test (p=0.05). The level of significance was chosenat p<0.05, and the results are presented as mean±standarderror of the mean (S.E.M.).Results and discussionIngredients and proximate composition of the pelletdiet (Godrej) used in the present study are provided inTable 1. The effects of stocking density on survival (%),specific growth rate (SGR) and feed conversion ratio (FCR)are presented in Fig. 1, 2 and 3 respectively. The fishesadapted well to the experimental system, and no disease orwater quality problems were observed during the studyperiod. The water temperature ranged from 27.5 to31.5 °C, pH 7.4 to 7.8, salinity 28.5 to 33.5 ‰, dissolvedoxygen (DO)  5.8 to 6.2 mg l-1 and nitrite (NO2) 0.01 to0.03 ppm in different treatments. The total ammonia (NH3)varied from 0.01 to 0.07 ppm in treatment with a stockingdensity of   1000 nos m-3, 0.01 to 0.15 ppm in 1500 nos m-3 and 0.01 to 0.63 ppm in 2000 nos m-3 stocking density.The water quality parameters were within the limits citedby Rimmer and Russel (1998) for the rearing of Asianseabass nursery and grow-out. This is also one of the reasonsthat all the stocks in the treatments yielded almost 100%survival rate.Overall survival rates  recorded wree: 98.3, 97.6 and98.7% at stocking densities  of 1000 nos. m-3, 1500 nos. m-3and 2000 nos. m-3 respectively (Fig. 1). Statistical analysisshowed no significant differences in survival rates up tothe 30 days  of experimental period, at 1000 nos. m-3,1500 nos. m-3 and  2000 nos. m-3  (p>0.05). But significantdifferences were noticed in the survival rates after 90 daysof culture period at  1000 nos. m-3 as compared to1500 nos. m-3 and 2000 nos. m-3 stocking densities (p<0.05)(Fig. 1). Kailasam et al. (2001) observed a survival rate of65% in higher stocking densities of 20 and 30 nos. l-1.Kailasam et al. (2002) opined that seabass fry are highlycarnivorous, voracious feeders and development of fast-growing individuals (shooters) during the larval phasedrastically reduces the survival rate mainly throughcannibalism. But, in the present study, higher percentageof survival was obtained  at high stocking density of 2000nos. m-3 and also very less amount of fast-growingSuresh Kumar Mojjada  et al.Table 1. Ingredient and proximate composition of the commercialpelleted diet (Godrej) used (g 100 g-1 dry weight).Ingredients (g 100 g-1)Muscle fish meal 58.57Krill meal 11.14Cod liver oil 13.28Lecithin 1.00Gelatin 6.50Corn starch 3.00Mineral premix 3.75Vitamin premix 2.75Antioxidant premix 0.01Proximate composition: (g 100 g-1 dry weight)Crude protein 61.8Crude lipid 21.5Ash 6.1NFE + crude fiber 10.6Gross energy (kJ g-1): 24.9Fig. 1. Survival (%) of Asian seabass Lates calcarifer culturedat three different stocking densities for a study period of90 days (All values are mean ± S.E.M)73individuals (shooters) were noticed in high stocking densitythan in the low stocking densities. There was no significantinteraction between size distribution, stocking density,survival, cannibalism and natural mortality. High stockingdensity (2000 nos. m-3) and initial size distribution withoutinteraction influenced the survival of juveniles in the presentinvestigation.Weight gain per day during the initial period rangedfrom 0.16 to 0.38 whereas the SGR ranged from 7.11 to4.41. This agrees with the previous report by Katersky andCarter (2005), where SGR was 5.6% per day at 27 °C in a20 days experiment using 5 g fish. In the present study,SGR decreased from 4.51 to 4.41 in 1000 nos. m-3, 6.36 to5.39 in 1500 nos. m-3 and 7.11 to 6.89 in 2000 nos. m-3stocking density after the 90 days rearing period (Fig. 2).There is an inverse relationship between SGR and fishweight and therefore, SGR decreases as fish weightincreases (Jobling, 1994; Catacutan and Coloso, 1997;Eusebio and Coloso, 2000). Results observed from theseexperimental trials showed that the SGR was inverselyproportional to that of the stocking density (p<0.05), butnot much variation was noticed in the survival rate.allow the subordinates to feed properly (Alanärä andBrännäs, 1996). However, when European seabass wasreared up to the age of 6 months, high densities enabledthe highest growth rates from 6.6 to 27.6 g (Papoutsoglouet al., 1998).Seabass fry reared under controlled conditions facecompetition among individuals for feed and space resultingin uneven growth causing cannibalism (Mackinnon, 1985;Van Damme et al., 1989; Sukumaran et al., 2011). Hechtand Pienaar (1993)  stated that cannibalism is also aphenomenon believed to be caused due to genetics andbehaviour of the fish. Cannibalism due to size variationcaused by genotypic differences dictates individual growthrate (De Angelis et al., 1979). Several environmental factorslike food availability, population density, refuges, waterclarity, light intensity, feeding frequency and the frequencyat which alternative prey is presented are found to influencethe behavioural pattern of larvae and juveniles whichultimately lead to cannibalism (Braid and Shell, 1981;Li and Mathias, 1982). In the present investigation, suchphenomenon was noticed to some extent in low stockingdensity groups whereas in high stocking density group itwas almost nil.  Kailasam et al. (2002) reported that socialdominance is one of the causes of size variation, whichleads to hierarchical territoriality and associated behaviouralpatterns. In high stocking density, there was very lesschances for social dominance and hierarchical territorialityand associated behavioural patterns, which lead to efficientutilisation of  the available space and feed in the cultureenvironment.The results of the present study indicate that highstocking density (up to 2000 nos. m-3) with proper feedingrate, feeding frequency and water quality can help to reducecannibalism and to obtain maximum survival rate andgrowth in seabass. The technique can be used to producelarge numbers of seabass juveniles for open sea cagefarming of Asian seabass.Effect of  stocking density on growth and survival of Lates calcariferFig. 2. Specific growth rate (SGR) of Asian seabass Latescalcarifer cultured at three different stocking densities(All values are mean ± S.E.M)Philipose et al. (2010) reported  FCR of 1.15 in45 day nursery rearing of Asian seabass in indoor cementtanks. In the present study, the FCR recorded at the threestocking rates were, 0.86, 0.85 and 0.90 for 1000 nos. m-3,1500 nos. m-3 and 2000 nos. m-3 respectively during theculture period of 90 days (Fig. 3). Significant differences(p<0.05) between 2000 nos. m-3 and the other two stockingrates were recorded, but on the other hand  1000  nos. m-3and 1500 nos. m-3 did not differ significantly (Fig. 3). TheFCR values indicate that  2000 nos. m-3 stocking densitygroup utilised the feed most efficiently and showed betterfeed conversion than the other two groups, resulting in anoverall biomass production of 1.11 kg day-1. In the case ofrainbow trout (Oncorhynchus mykiss), it has beendemonstrated that social interactions affect fish growthnegatively, because dominant fish monopolise and do notFig. 3. Food conversion ratio (FCR) of Asian seabassLates calcarifer cultured at three different stockingdensities (All values are mean ± S.E.M).74AcknowledgementsThe authors express their gratitude to the Ministry ofAgriculture, Government of India for the financial supportprovided to carry out the work. The authors are grateful tothe Head, Mariculture Division, CMFRI, for hisencouragement during the study. We are thankful to all thestaff of Visakhapatnam Regional Centre of CMFRI for theirhelp in field work.References Alanärä, A. and Brännäs, E. 1996. Dominance in demand-feedingbehaviour in Arctic charr and rainbow trout: the effect ofstocking density. J. Fish Biol., 48: 242– 254.Anil, M. K., Santosh, B., Jasmine, S., Saleela, K. N., George, R.M., Kingsley, H. J.,  Unnikrishnan, C.,  Hanumanta Rao, G.and Syda Rao, G. 2010.  Growth performance of the seabassLates calcarifer (Blotch) in sea cage at Vizhinjam Bay alongthe south-west coast of India. Indian J. Fish., 57(4): 65-69.APHA 1998. 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P., Appelbaum, S. and Hecht, T. 1989. Siblingcannibalism in koi carp, Cyprinus carpio, L., larvae andjuveniles reared under controlled conditions. J. Fish. Biol.,34 (6): 855-863.Date of Receipt : 31.05.2012Date of Acceptance : 09.11.2012

Effect of stocking density on growth and survival of hatchery reared

fry of Asian seabass, Lates calcarifer (Bloch) under captive conditions

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Effect of stocking density on growth and survival of hatchery reared fry of Asian seabass, Lates calcarifer (Bloch) under captive conditions

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