Research Article
Optimum Growth Determination of Heterobranchus bidorsalis in Earthen Ponds
Department of Fisheries, Faculty of Science, Lagos State University, Ojo, P.M.B. 001 LASU Post Office, Ojo Badagry Express Way, Lagos, Nigeria
Intensification of aquaculture practices in Nigeria has been identified as one of the tools that can help in closing the gap between demand and supply of fish and fisheries products (Owodeinde and Ndimele, 2011). This is particularly important in the culture of acceptable fish species (Clarias gariepinus and Heterobranchus sp.) in commercial quantities (Ojutiku, 2008; Ndome et al., 2011). The clariid catfishes constitute an excellent food fish of high commercial value in Nigeria and some other countries of the world (Adebayo and Popoola, 2008; Huda et al., 2002). Heterobranchus bidorsalis is one of the two main genera of the African mud catfish (Clarias and Heterobranchus) widely cultured in Africa, Asia and Europe (Adewolu and Adoti, 2010; Kori-Siakpere et al., 2006). This is due to their outstanding culture characteristics such as ability to withstand unfavourable environmental conditions, efficient in utilizing various types of locally formulated fish feed, resistance to diseases, high economic potential and simple techniques in the propagation of their fingerlings (Fagbenro and Sydenham, 1988; Dada and Olarewaju, 1996; Owodeinde and Ndimele, 2011).
A lot of Nigerians have demonstrated their interest in catfish consumption. This feeding habit of Nigerians tends to support the commercial propagation of clariid catfishes and this trend became noticeable since the late 1980s. This was when it became apparent that commercially exploited clariid populations in the wild were declining but their commercial value was increasing. This situation triggered off interest in the culture of clariid catfishes as commercial food fish. Its value as food fish is reflected in the wholesale prices in the local markets which ranged from $4.00 to 6.00 kg-1 depending on the size, location and season of capture. This high demand of the clariids resulted in generally high prices which serve as an added inducement to would-be fish farmers or groups interested in commercial fish culture.
Studies on Heterobranchus species in Nigeria focused on stock and chromosome manipulations, performances of intraspecific hybrids and growth performances at different dietary compositions in indoor and outdoor concrete tanks (Madu et al., 1991, 1993; Aluko and Aluko, 1998; Aluko et al., 1999, 2000; Madu and Aluko, 1999). However, none had detailed investigation on the growth and survival of this clariid species-Heterobranchus bidorsalis under semi-intensive pond conditions. This study is aimed at evaluating the potentials for culturing Heterobranchus bidorsalis to commercial size and using simple regression technique equation to determine the relationship between the body weight of Heterobranchus bidorsalis and the number of weeks of growth with a view of determining the optimum growth and the best time to crop under maximum utilization of feed in semi-intensive pond condition.
Collection and acclimation of experimental fish: Fingerlings of Heterobranchus bidorsalis used in this study were obtained from the Hatchery Complex of the Department of Fisheries, Lagos State University (LASU) Ojo, Nigeria. Upon arrival at the Omague Fish Farm Ijotun, in the Badagry Local Government of Lagos State, Nigeria, where the experiment was conducted. The fish were kept in the rearing tanks to allow them recover from stress due to transportation and acclimatized them to their new environment. They were in the rearing tanks for two weeks, during which they were fed on compounded diet.
Experimental procedure: Three rectangular earthen ponds of 20 m in lengthx10 m in width (0.02 hectare) each were stocked between 1st February, 2010 and 30th August, 2010, with 330 randomly selected artificially reared fingerlings of Heterobranchus bidorsalis (mean weight 8.5±1.5 g). Two weeks before stocking, the ponds were filled with water from the farm bore-hole, fertilized with complete in-organic fertilizer (N15P15K15) at the rate of 112 kg ha-1 and poultry manure at the rate of 200 kg ha-1, then seeded with plankton collected from a culture farm pond by pumping pond water through plankton net.
Two times daily, the fish were fed 3% of their body weight with compounded artificial feed containing 45% crude protein, prepared by using the following ingredients fish meal (15.8%), soybean meal (59.4%), yellow maize (18.2%), blood meal (5.1%) vegetable oil (1.0%) and vitamin premix (0.5%). At two weeks interval, the fish were sampled with a 2.0 cm mesh size bag seine net 25 m long to monitor growth. Fish were not fed 24 h before the samples were collected to allow the intestinal contents to be digested. To avoid sampling error at least 30% of the experimental fish species were weighed and the length measured bi-weekly. To avoid stress due to handling, the randomly selected fish were subjected to mild anesthetization in a 20 mg L-1 solution of MS-222 (tricaine methanesulfonate) purchased from Sigma Chemical, St. Louis Missouri, USA. They were measured for the Standard Length (SL), Total Length (TL) (to the nearest 0.1 mm); and wet weight (to the nearest 0.1 g) using graduated long ruler and top loading sensitive scale (Model, 1500). After all measurements, the fish were revived in fresh water and then returned to the ponds. On the 30th of August 2010, the ponds were drained; all the fish were removed, counted and weighed to determine the survival rate and standing crops. They were held in three 6 m3 concrete tanks.
Determination of water quality parameters: The following water quality parameters were measured during the study period; temperature, dissolved oxygen, pH and total ammonia-nitrogen. Temperature was monitored with a simple mercury-in-glass thermometer graduated in 0.01°C. Dissolved oxygen was usually measured between 0700-0800 h with a YSI model-57 DO meter and further authenticated by alkaline-azide-modification of Winklers method (Boyd, 1981). pH values were determined using a Griffin pH meter (Model 400) while total ammonia-nitrogen were determined by the standard method described by Boyd (1981).
Analysis of growth: The linear regression relationship between body weight and the number of weeks of growth of Heterobranchus bidorsalis was calculated using this formula (Uzoagulu, 1998):
Y = BO+B1 X1 or Y = a+b X1 |
where, Y is mean weight of the fish (g); BO and B1 are all constant. BO is the intercept on Y-axis; B1 is the slope of the line or gradient and X1 is no of weeks of growth. With this equation one can determine the size/weight of the study fish at any point in time.
Mean specific (instantaneous) growth rates (SGR) estimated as percentage increase in weight per growth period of Heterobranchus bidorsalis was calculated at the end of each growth period using the formula:
where, SGR or G is specific growth rate, Wt is the weight (g) at the end of the interval (end of the period), Wo is the weight (g) at the beginning of the period and t is time (i.e., the duration between initial and final sampling) in days. The calculation of SGR which accounts for both initial and final sizes is useful in comparing growth of the fish species at different sizes (Brown, 1946, 1957). This formula estimated the percentage increase in weight per growth period.
Condition factor (K) to determine the relative robustness (i.e., the state of well being of the fish), was calculated for each growth period according to the equation (Lagler, 1956):
where, W is the fresh weight in (g) and L the standard length (mm).
The experimental fish species were fed 3% of their body weight throughout the study period. The amount of food dispensed (kg) to the fish stocked in the three experimental ponds were adjusted bi-weekly by sub-sampling the population of the fish species in order to reflect the fortnightly increase in biomass using the following (Stickney, 1979):
where, W1 is the weight of the fish at day 1, Wo is the weight of the fish at day zero, F is the percentage feeding rate and C is the Food Conversion Ratio (FCR).
Several investigators have recently demonstrated that Heterobranchus bidorsalis can be grown to commercial size in various types of culture systems (Madu et al., 1991, 1993; Madu and Aluko, 1999). The present study yielded the best growth and production rates yet published in Nigeria on H. bidorsalis grown to commercial size in commercial quantities in earthen ponds and serves as a further indication of the potential of H. bidorsalis for commercial culture.
Growth, survival and production: During the period of study after the initial stocking of 330 fish per 0.02 ha, in the experimental ponds (16,500 fish ha-1), the mean body weight increased from 8.5 to 850 g (ranged between 600 to 1050 g) (Table 1) and a mean growth rate of 3.3 g day-1. Growth was rapid from May to August wish coincides with the raining season. The relationship between the body weight and the number of weeks of growth is shown in Fig. 1. The graphical representations and the statistical computations of the body weight against the number of weeks of growth of the study fish showed that they were highly correlated. The computation of the data provides the following:
Y = -61.00+31.50X1 r = 0.9, N = 250 |
A geometric growth curve was observed when the relationships between the two variables were plotted against each other. The observed growth curve shows the best time to harvest H. bidorsalis for maximum gain in terms of good growth and when maximum profit on feed utilization can be achieved.
Table 1: | Final length-weight relationship, correlation coefficient and condition factor of study fish |
Fig. 1: | Relationship between mean body weight and number of weeks of growth in Heterobranchus bidorsalis |
The study shows that H. bidorsalis could better be harvested at 26 weeks from fingerling stage. Beyond this time there was decreased efficiency of feed utilization and a decline in growth rate set in (Fig. 1).
At the final harvest survival was 75.75% of all the fish stocked and the mean standing crop was 10,580 kg ha-1. Since no physical mortality was recorded during the study period, piscivorous birds and poaching contributed to the mortality. Over 95% of H. bidorsalis were considered marketable (≥500 g) and the weight distributions of the samples in May, June, July and August indicated that about 50, 65, 80 and 95%, respectively were marketable at those ages (5, 6, 7 and 8 months, respectively). Because about 65% of the fish in the present study were considered commercially harvestable by mid-June (age 6 months) and over 95% had attained that status by mid-August (age 8 months), they could have been selectively harvested and sold during the period when prices were at premium (Fig. 2-4 showed the clusters exhibited by each of these figures).
Fig. 2: | Relationship between mean body weight and mean standard length of Heterobranchus bidorsalis in June |
Fig. 3: | Relationship between mean body weight and mean standard length of Heterobranchus bidorsalis in July |
This practice would allow consolidation of smaller fish into fewer ponds for additional growth. The removal of larger fish would also provide early cash return and eliminate the need of looking for buyers for a large percentage of the Heterobranchus bidorsalis which would have been commercially marketable in the restaurant trade (Fig. 2-4).
Fig. 4: | Relationship between mean body weight and mean standard length in Heterobranchus bidorsalis |
Specific growth rate (SGR) and condition factor (K): Daily specific growth rate declined from a maximum of 4.35 per day during the first month of study to as low as -0.67 per day. High initial specific growth rates that decrease with increasing age and individual fish biomass (and consequent increased metabolic costs) followed typical pattern of fish growth (Kerby et al., 1987). Mean condition factor (K) for fish sampled was 1.24, however, all the fish in the ponds had condition factor greater than 1.10 which appeared to represent desirable levels as most fish were healthy and robust. Fish that were sacrificed after the harvest contained appreciable quantities of abdominal fat.
Water quality: Water quality parameters were generally within acceptable limits. Bore-hole water with an alkalinity of 27.6 mg L-1 as CaCO3 was used to fill the ponds. Water quality values were generally satisfactory for the growth and health of the experimental fish species (Ndimele and Kumolu-Johnson, 2011; Ndimele et al., 2011; Ndimele, 2012). Values for total ammonia nitrogen did not exceed 0.08 mg L-1 and were normally in a range from 0.02-0.06 mg L-1. The pH ranged between 7.3 to 8.7. temperature 25-27°C, dissolved carbon dioxide ranged between 6-9 mg L-1 and dissolved oxygen concentrations 5.5-9.3 mg L-1 remained within acceptable limits. All these water quality parameters fall within the range reported by Huet (1979) as good for pond fish culture.
Food conversion ratios: Food Conversion Ratio (FCR) (expressed as weight of dry feed/wet weight of fish) was 3.22±0.01. Though, the FCR in most fishes e.g., catfishes vary from less than 1.5 to 5.0 (Jensen, 1989), the FCR is a little on the high side in the present study. The reason for this high FCR is not known. Since sinking pelleted feed was used, significant amount of feed might be wasted, this could account for high FCR observed in this study. We believe that feeding practices can be refined to provide more efficient conversion ratios without reducing growth rates.
In conclusion, this study has shown clearly that optimum growth and the best time to crop Heterobranchus bidorsalis under maximum utilization of feed can be determined in semi-intensive pond.
We thank Mr. Austin Anetekhai and Mr. Pascal Opuehi for their assistance in the collection of data and for taking care of the fish. We also give thanks to Omague Fish Farm, Ijotun in the Badagry Local Government of Lagos State for the use of the three experimental ponds. We express our gratitude to the Department of Fisheries Lagos State University, Ojo, Nigeria for providing the juveniles of H. bidorsalis.