Diets

For the experiment, four iso-energetic diets were formulated according to a 2 × 2 factorial design to create contrasts in DOD between diets (Table 1). The first factor was the DP:DE ratio, which was changed by modifying the dietary protein levels, ‘low DP:DE ratio’ (LP diets) v. ‘high DP:DE ratio’ (HP diets). It is assumed that fish fed diets with the low DP:DE ratio will have minimal use of protein as energy source, whereas at the high DP:DE ratio, a substantial amount of protein will be used as energy source⁽Reference LeGrow and Beamish²⁴⁾. Thus, the contrast in the DP:DE ratio between diets will cause a difference in the protein:fat deposition ratio in fish⁽Reference Lee and Putnam⁵⁾, and thereby generate a difference in DOD. The different DP:DE ratios (HP diets, 25 mg/kJ; LP diets, 14 mg/kJ) were created by exchanging an equal proportion (30 %) of protein ingredient mixture (fishmeal, wheat gluten, soya protein concentrate, pea protein concentrate and dl-methionine) by an equivalent amount of energy ingredient mixture (rapeseed oil, fish oil and gelatinised maize starch).

Table 1 Formulation, ingredient composition and analysed nutrient content of the experimental diets

HPF, high digestible protein (DP):digestible energy (DE) ratio diet with fat as non-protein energy (NPE) source; HPS, high DP:DE ratio diet with starch as NPE source; LPF, low DP:DE ratio diet with fat as NPE source; LPS, low DP:DE ratio diet with starch as NPE source.

* Gelatinised maize starch (Merigel^®100; Amylum Group).

† Fishmeal (999 LT Fish Meal – crude protein 72 %; Triple Nine Fish protein).

‡ Fish oil (999 Fish Oil; Triple Nine Fish protein).

§ Diamol (acid-insoluble ash, as inert marker for digestibility measurement) – Diamol GM; Franz Bertram.

¶ Mineral premix composition (to supply, mg/kg feed): 50, Fe (as FeSO₄.7H₂O); 30, Zn (as ZnSO₄.7H₂O); 0·1, Co (as CoSO₄.7H₂O); 10, Cu (as CuSO₄.5H₂O); 0·5, Se (as Na₂SeO₃); 20, Mn (as MnSO₄.4H₂O); 500, Mg (as MgSO₄.7H₂O); 1, chromium (as CrCl₃.6H₂O); 2, I (as CaIO₃.6H₂O). Vitamin premix composition (to supply, mg/kg feed): 10, thiamin; 10, riboflavin; 20, niacin; 40, pantothenic acid; 10, pyridoxine; 0·2, biotin; 2, folic acid; 0·015, cyanocobalamin; 1500, choline (as choline chloride); 100, ascorbyl phosphate; 3, retinyl acetate, 4·8, cholecalciferol (Rovimix^® D3-500; DSM, Inc.); 100 I, α-tocopheryl acetate; 10, menadione (as menadione sodium bisulfite, 51 %); 400, inositol; 100, antioxidant BHT (E 321); 1000, calcium propionate.

∥ Calculated as follows: total carbohydrates (starch, free sugars and NSP) = 1000 − (crude protein+crude fat+ash).

** Gross energy value measured including energy from added cellulose; values within parentheses represent energy value calculated excluding energy from added cellulose (15 %).

The second factor was the type of NPE source: ‘starch’ v. ‘fat’. The oxygen demand of dietary starch and fat depends on whether it is used for ATP production through oxidation or deposited as an energy store (fat) in the body. The amount of oxygen required to deposit fat from dietary fat is lower than that required for lipogenesis from starch⁽Reference Blaxter^25, Reference Reeds, Wahle and Haggarty²⁶⁾. Therefore, diets were formulated to contain either starch (diets HPS and LPS) or fat (diets HPF and LPF) as the major NPE source at both dietary DP:DE ratios. For the fat diets, 10 % of rapeseed oil was added as the NPE source, whereas for the starch diets, it was exchanged by 25 % of gelatinised maize starch, assuming a similar DE content of 10 % rapeseed oil to that of 25 % gelatinised maize starch. Furthermore, in order to have identical nutrient and energy density between these diets, 15 % of cellulose was included in the fat diets. The final ingredient compositions of the diets are shown in Table 1. Diets were produced by Research Diet Services. The ingredient mixture of each diet, excluding the major part of the oils, were mixed and hammer-milled (Condux LHM20/16; Hanau) through a 1 mm screen. The diets were processed by extrusion using a Clextral BC45 laboratory-scale twin-screw extruder (Clextral) with a 3 mm die, resulting in a pellet size of about 3 mm. In the HPS and LPS diets, all oils were added to the mixture before extrusion. In the HPF diet, 6 % of the oils and in the LPF diet, 9·1 % of the oils were added to the mixture before extrusion. Following extrusion, pellets were dried in a tray dryer at 70°C for 3 h and cooled to ambient temperature. Finally, the HPF and LPF diets were coated with the remaining part of the oils (5 and 10 %, respectively) and stored at 4°C.

Fish stock and pre-experimental rearing conditions

A stock of 300 juvenile (mean body weight 5 g) male Nile tilapia (NMT Manzala Silver strain) was obtained from a commercial fish breeder (Til Aqua International) and reared at the experimental facilities (‘De Haar Vissen’) of the Wageningen University, The Netherlands. Fish were housed in six tanks (120 litres) at a stocking density of fifty fish per tank. These tanks were connected to a common water recirculation unit comprising a trickling filter, a settling tank and a pump. Initially, fish were fed with a commercial starter feed (1·0 mm, 57 % crude protein, 15 % crude fat, Skretting, F-10; MP Pro Aqua Brut) for about 6 weeks and thereafter with larger feed pellets (2·5 mm, 47 % crude protein, 14 % crude fat, Skretting, F-1P Classic) until fish reached a body weight of 40 g. During this pre-experimental period (10 weeks), fish were hand-fed twice daily with a ration of about 10 g/kg^0·8 per d. Fish were kept at optimal rearing conditions (water flow rate in tank, 6 litres/min; temperature, 28°C; DO, >5 mg/l; photoperiod, 12 h light–12 h dark).

Housing facility

The 48-d feeding trial was carried out in the Aquatic Metabolic Unit of Aquaculture and Fisheries group, Wageningen University, The Netherlands. This metabolic unit consists of twelve metabolic tanks (90 × 60 × 45 cm) in a series connected to a common water recirculation system consisting of a trickling filter, an oxygenation unit, a sump, a drum filter (Hydrotech 500®) and a cooling/heating system for maintaining uniform water quality throughout the study. Water was supplied to all tanks from a common inlet, thus ensuring identical water quality and drained through individual tank outlets into the system. The oxygenation unit maintained the concentration of DO in water by injecting pure oxygen into the common inlet, which was regulated by a mass flow controller (Brooks® Model 5850S; Brooks Instruments) and a microprocessor (Brooks® Read Out and Control Electronics Model 0154; Brooks Instruments). Each metabolic tank was equipped with a water flow meter (MAGFLOW® MAG 5000; Danfoss A/S) to regulate and monitor water flow. The volume of water within the tanks was kept identical (200 litres) by adjusting the standpipe. The water surface of each tank was covered with a water-resistant floating panel to prevent gas exchange between water and air. Within the floating panel, a circular feeding hatch (18·5 cm in diameter) with a removable floating lid was used to feed the fish. The inlet and outlet of each metabolic tank were linked to two separate sampling pipelines. One sampling pipe led to an auto-analyser (SANplusSYSTEM; Skalar) to continuously measure nitrite, nitrate, total-NH₃-N, urea and CO₂. The other sampling pipe led to a common measuring hub to continuously measure DO (WTW-Trioximatic® 700 IQ; WTW GmbH), pH (WTW-SensoLyt DW® (SEA) 700 IQ; WTW GmbH) and conductivity (WTW TetraCon325® 700 IQ; WTW GmbH) of water. The oxygen measurements from each metabolic tank were regulated by an electromagnetic valve (ASCO model 24/50 6 WFT; ASCO/Joucomatic), which controlled the water flow from the inlet and outlet of each tank to the common measuring hub. These electromagnetic valves were controlled by an algorithmic program via a user interface (HTBasic, version 9.5; TransEra Corporation), and the measured values of DO, water flow, pH and conductivity were automatically recorded in a personal computer.

In addition, the outlet of each tank was connected to a swirl separator (44 cm in height, 24·5 cm in diameter; AquaOptima AS) to collect faeces for the determination of nutrient digestibility. The faeces were collected in a detachable 250 ml bottle at the bottom of the swirl separator. To minimise the bacterial decomposition of faeces, the bottle was kept under ice. During feeding, another set of bottles were used in the swirl separator to collect the uneaten feed pellets flushed out from the tanks.

Experimental procedure

At the start of the experiment, 240 fish (mean body weight 40 g) from the stocking tanks (unfed for about 36 h) were taken out, anaesthetised (0·2 g tricaine methane sulfonate/l (MS-222, Finquel®; Argent Chemical Laboratories) with 0·4 g sodium bicarbonate/l as buffer), weighed individually and randomly distributed among the twelve metabolic tanks (twenty fish per tank). The respective diets were assigned randomly to triplicate tanks. Then, twenty fish were killed with an excess dose of anaesthesia (0·8 g tricaine methane sulfonate/l with 1·6 g sodium bicarbonate/l as buffer) for initial body composition, kept in plastic bags, sealed and stored at − 20°C until further analysis.

During the experimental period (48 d), fish were hand-fed with their respective diets twice daily to apparent satiation for an hour (09.00–10.00 and 16.00–17.00 hours). At the end of each feeding session, the uneaten pellets were collected and counted to determine FI accurately. Feed fed and uneaten feed were recorded for each feeding. From the second week of the trial, 30 min before each feeding, faeces were collected from the swirl separator and transferred to aluminium trays and stored at − 20°C until further analysis. A representative sample (50 g) of each diet was collected twice weekly and stored at 4°C.

Fish were kept under optimal water quality parameters during the entire study period with photoperiod (12 h light–12 h dark), temperature (27·7 ± 0·29°C), pH (6·8 (sd 0·11)), DO at tank inlet (8·8 (sd 0·75) mg/l) and outlet (5·6 (sd 0·58) mg/l), conductivity (2821 (sd 99) μS/cm), nitrite (0·02 (sd 0·01) mg N/l), nitrate (85 (sd 0·5) mg N/l) and total-NH₃-N (0·12 (sd 0·06) mg N/l). After 20 d from the start of the experiment, as the DO level in tank outlets dropped below 5 mg/l, especially during postprandial hours, pure oxygen was injected into the common inlet until the end of the experiment, in order to ensure sufficient DO availability to the fish.

The volume of water and water flow were kept constant at 200 litres and 7 litres/min, respectively, in all tanks. Thus, the rate of replenishment (volume of water/water flow) of the entire tank water is achieved in about 30 min. The water was sampled for a duration of 5 min from the common inlet and outlet of each tank and flushed over the oxygen electrode for measuring oxygen concentration. Thus, within an hour, oxygen was measured twice in the common inlet and outlet of four tanks. Oxygen measurements were performed in a continuous cycle of 2 d (48 h; from 08.00 to 08.00 hours) in a set of four tanks consisting of all dietary treatments. Consequently, in 6 d, oxygen measurement was undertaken in all twelve tanks. This procedure was repeated until the end of the experiment resulting in five cycles of 48 h oxygen measurements for each tank. The oxygen electrode was calibrated once every week.

At the end of the experiment, fish were starved for about 36 h before handling. Fish from each tank were anaesthetised and weighed individually for the final body weight. From each tank, eight fish were randomly sampled for the analysis of the final body composition and handled in a similar way as the initial body composition samples.

Analytical procedure

Frozen fish samples were homogenised twice through a 4·5 mm die in a meat mincer (Gastromaschinen, GmbH model TW-R 70; Feuma) and subsamples were taken immediately for DM and protein analysis. The rest of the homogenised fish samples and faeces (pooled per tank) were then freeze-dried and finely ground using a blender. Before fat analysis, feed and faecal samples were hydrolysed by boiling for 1 h with 3 M-HCl. The proximate composition of feed, fish carcass and faeces was analysed in triplicate for DM, protein (Kjeldahl method), fat (Soxhlet method), ash, acid-insoluble ash, energy (bomb calorimeter) as described elsewhere⁽Reference Santos, Schrama and Mamauag²⁷⁾. Starch content was determined as glucose, using the amyloglucosidase/hexokinase/glucose-6-phosphate dehydrogenase method after ethanol (40 %) extraction and starch decomposition in dimethylsulfoxide/HCl⁽²⁸⁾.

Calculations

Weight-gain rate of fish (g/d) was calculated as the difference between the average individual final (W _f) and initial (W _i) body weight of fish per tank divided by the duration of the experimental period (t). The geometric mean body weight (W _G; in g) was calculated as √(W _i × W _f). Growth rate of metabolic body weight (in g/kg^0·8 per d) was calculated as (W _f − W _i)/(MBW_G × t), where MBW_G is the mean metabolic body weight of fish (in kg^0·8), which was calculated as (W _G/1000)^0·8 and t, the duration (days) of the growth study. The lean body growth of fish (in g/d) was calculated as the difference between (W _f − W _f − fat) and (W _i − W _i − fat) divided by (t), where W _f − fat and W _i-fat are the crude fat content of the final and initial fish carcass, respectively, expressed on a fresh weight basis. Daily growth coefficient (in %/d) was calculated as 100 × (W _f^1/3 − W _i^1/3)/t.

Daily absolute FI (FI_ABS; g DM/fish per d) was calculated on a DM basis as FI_tot/(n × t), where FI_tot is the total FI per tank (in g DM) over the experimental period corrected for dead fish and uneaten pellets, n is the number of fish per tank, and t is the experimental period. FI as-fed (g/fish per d) was calculated in a similar way as FI_ABS but on an as-fed basis. FI of fish expressed as a percentage of body weight (g DM/100 g fish per d) was calculated as (FI_ABS/W _G) × 100 and FI per metabolic body weight (FI_MBW; g DM/kg^0·8 per d) was calculated as FI_ABS/MBW_G. The feed:gain ratio (FGR; DM intake/wet-weight gain) was calculated as FI_MBW/MBW_G.

Apparent digestibility coefficient (ADC; in %) of DM, protein, fat, total carbohydrate, gross energy and ash was calculated for each tank according to Tran-Duy et al. ⁽Reference Tran-Duy, Smit and van Dam⁸⁾, using acid-insoluble ash as an inert marker. Digestible nutrient intake (g or kJ/kg^0·8 per d) was calculated as FI_MBW × Feed_Z × (ADC_Z/100), where Feed_Z is the nutrient content in feed on a DM basis (in g), ADC_Z is the apparent digestibility of nutrients (in %) and Z represents DM, protein, fat, total carbohydrate, energy and ash.

The parameters of N balance, fat balance and energy balance were calculated per tank and expressed in mg N/kg^0·7 per d, mg/kg^0·9 per d and kJ/kg^0·8 per d, respectively. The gross N intake (GN) was calculated as the product of total FI (g DM/kg^0·7 per d) and N content of feed (mg/g). The digestible N intake (DN) was calculated as the product of GN and ADC of N (%). Faecal N loss (FN) was calculated as the difference between GN and DN. The retained N (RN) was calculated as the difference between the N content of the final and initial fish carcass. Branchial and urinary N loss (BUN) was calculated as the difference between DN and RN. Parameters of the fat balance were calculated as follows: gross fat intake (GF) was calculated as the product of total FI (g DM/kg^0·9 per d) and the fat content of feed (mg/g). The digestible fat intake (DF) was calculated as the product of GF and ADC of fat (%). Faecal fat loss (FF) was calculated as the difference between GF and DF. The retained fat (RF) was calculated as the difference between the fat content of the final and initial fish carcass. Parameters of the energy balance were calculated as follows: gross energy intake (GE) as the product of FI (g DM/kg^0·8 per d) and the energy content of the diet; DE intake as the product of GE and ADC of energy; branchial and urinary energy loss as the product of NH₃-N and urea-N with their corresponding energy value of 24·9 and 22·5 kJ/g N⁽Reference Bureau, Kaushik and Cho²⁹⁾. NH₃-N and urea-N were calculated from BUN based on the measured averaged ratio NH₃-N:urea-N excretion of 9:1 over the diets (S. Saravanan et al., unpublished results). Metabolisable energy intake (ME) as the difference between DE and branchial and urinary energy loss; RE as the difference between the energy content of the final and initial fish carcass; and heat production as the difference between ME and RE; RE as protein (RE_p) as the product of retained protein (RN × 6·25) and 23·7, where 23·7 is the energy content of 1 g protein⁽Reference Brafield³⁰⁾; RE as fat as the difference between RE and RE_p, assuming total RE only in the form of fat and protein.

The oxygen consumption of the fish was calculated per tank and expressed as mg O₂/kg^0·8 per min, adopting the formula used for calculating NH₃ excretion in fish⁽Reference Kaushik³¹⁾: OX_t = ((V _L × ΔC)+(C _t × ΔW))/(t × W _mean), where OX_t is the VO₂ of fish per unit time (mg O₂/kg^0·8 per min), V _L is the volume of water in the metabolic tank (in litres), ΔC is the variation in O₂ concentration in the outlet between two consecutive measurements (C _i − C _i − t), C _t is the mean O₂ concentration of the inlet minus the outlet between two consecutive intervals (C _i − C _i − t/2), ΔW is the water flow per unit time (litres/min), t is the unit of increment in time (min) between two consecutive oxygen measurements, and W _mean is the average predicted metabolic body weight of fish (kg^0·8) during the measurement days. W _mean was calculated as (W _p/1000)^0·8, where W _p is the predicted daily body weight of individual fish, estimated as W _i⁽Reference Fletcher^1–Reference Boujard, Gélineau and Covès⁴⁸⁾+DFI_i⁽Reference Fletcher^1–Reference Boujard, Gélineau and Covès⁴⁸⁾/FGR_tank, where DFI_i⁽Reference Fletcher^1–Reference Boujard, Gélineau and Covès⁴⁸⁾ is the daily FI per fish per tank (in g/fish), W _i is the average initial body weight of fish, i is the ith day of the experiment, and FGR_tank is the feed:gain ratio of each tank calculated for the entire experimental period.

DOD (mg O₂/kJ or mg O₂/g) for each diet was calculated by dividing mean daily oxygen consumption (mg O₂/kg^0·8 per d) of fish in each tank by their respective DE (kJ/kg^0·8 per d) or daily dry FI (g DM/kg^0·8 per d). Similarly, efficiency of oxygen utilisation for energy retention (i.e. oxygen efficiency; kJ RE/mg O₂ consumed) was calculated by dividing RE (kJ/kg^0·8 per d) of fish within each tank by their respective mean daily oxygen consumption (mg O₂/kg^0·8 per d).

Statistical procedures

Statistical analyses were performed using SAS 9.1 (SAS Institute). The homogeneity of variances among the groups was checked by Levene's F test (PROC ANOVA). All variables met the assumption of equal variances (P>0·05). The parameters related to FI, oxygen consumption, growth and nutrient utilisation were subjected to a two-way ANOVA in order to test the effect of DP:DE ratio, type of NPE and their interaction (PROC GLM). Normal distribution of the residuals was verified using the Kolmogorov–Smirnov test (PROC UNIVARIATE). The total digestible carbohydrate intake and RF overruled the assumption of normal distribution (P < 0·05) and logarithmic data transformation satisfied the assumptions. When the interaction between DP:DE and NPE was significant (P < 0·05), comparison of means was performed using the Tukey–Kramer test. A linear regression (PROC REG) analysed the relationship between DOD or oxygen efficiency and DE intake of each treatment unit.