Implication
Fluctuation in poultry feed prices is challenging nutritionists to find ways of maintaining animal productivity while managing feed prices. In practice, including cheaper feed ingredients in the feed formulation is one of the solutions. However, inclusion of alternative protein sources such as sunflower meal (SFM) and rapeseed meal (RSM) is limited by the presence of indigestible non-starch polysaccharides. This work confirmed that high inclusion of SFM and RSM negatively influence broiler performance. However, enzyme supplementation could be used to improve feed conversion ratio at different levels of RSM and SFM inclusion.
Introduction
The price of the major raw materials used in poultry diets is a key element for profitability of the poultry production. However, weather conditions and the increase in global demand (Nardone et al., Reference Nardone, Ronchi, Lacetera, Ranieri and Bernabucci2010; Spiertz, Reference Spiertz2010) cause continuous changes in raw material prices. Fluctuation in raw material prices is challenging nutritionists to find ways of maintaining productivity while managing feed prices. In practice, one of the methods employed is to reformulate diets to include cheaper feed ingredients. However, inclusion of alternative protein sources such as sunflower meal (SFM) and rapeseed meal (RSM) is limited by the presence of indigestible non-starch polysaccharides (NSP; Knudsen, Reference Knudsen1997; Meng and Slominski, Reference Meng and Slominski2005; Rama Rao et al., Reference Rama Rao, Raju, Panda and Reddy2006; Khajali and Slominski, Reference Khajali and Slominski2012) and lower protein digestibility (Mathlouthi et al., Reference Mathlouthi, Saulnier, Quemener and Larbier2002; Lemme et al., Reference Lemme, Ravindran and Bryden2004). It is well known that NSP to be anti-nutrients that inhibit the digestion and utilisation of dietary nutrients by the animal and therefore reduce animal performance (Choct, Reference Choct2006). Senkoylu and Dale (Reference Senkoylu and Dale1999) stated that SFM cell wall contains NSP such as β-glucans, xylans, arabans, pectins and oligosaccharides which tend to increase the viscosity of the digesta, lower nutrient utilisation, and lead to depressed growth in chicks. Previous reports showed higher arabinoxylans in RSM and SFM compared with SBM (Knudsen, Reference Knudsen1997; Mathlouthi et al., Reference Mathlouthi, Saulnier, Quemener and Larbier2002).
In recent years there has been an interest in the importance of gizzard development and its effect on nutrient digestibility (Amerah et al., Reference Amerah, Ravindran, Lentle and Thomas2007; Svihus, Reference Svihus2011). Diluting the diet with low levels of coarse insoluble fibres was found to have positive effects on nutrient digestibility and bird performance (Amerah et al., Reference Amerah, Ravindran and Lentle2009; Mateos et al., Reference Mateos, Jimenez-Moreno, Serrano and Lazaro2012) which was attributed to the effect on gizzard development (Amerah et al., Reference Amerah, Ravindran and Lentle2009; Svihus, Reference Svihus2011). However, the effect of dietary fibre on gizzard development was found to depend on fibre source and its particle size (Hetland et al., Reference Hetland, Svihus and Choct2005; Amerah et al., Reference Amerah, Ravindran and Lentle2009; Svihus, Reference Svihus2011; Mateos et al., Reference Mateos, Jimenez-Moreno, Serrano and Lazaro2012).
The use of carbohydrase enzymes has been suggested as one of the strategies to improve the nutritive value of RSM and SFM in poultry (Kocher et al., Reference Kocher, Choct, Porter and Broz2000; Meng and Slominski, Reference Meng and Slominski2005; Khajali and Slominski, Reference Khajali and Slominski2012). The successful use of enzymes in viscous grain-based diets has initiated research for the use of enzymes for other ingredients, such as vegetable proteins high in NSP (Choct, Reference Choct2006). However, there is scarcity in the research studying the effects of the level of RSM and SFM in wheat-based diets and enzyme combination (endoxylanase and β-glucanase) on production performance, carcass quality, gizzard development and digesta viscosity of broiler chickens. The hypothesis for this study was that the increase in RSM and SFM inclusion will increase the NSP in the diets and consequently reduce broiler performance and that enzyme supplementation would recover the reductions in broiler performance with the highest response at the highest inclusion level of RSM and SFM.
Material and methods
Birds and housing
A total of 960 1-day-old male Ross 308 broiler chickens were used in a study evaluating the response of broilers to three different diet types containing different levels of RSM and SFM and two levels of enzyme inclusion, resulting in six treatments. Each treatment was replicated eight times.
At day 1, broilers arrived at the poultry facility of Schothorst Feed Research (Lelystad, the Netherlands) and were housed in floor pens of 2 m2. On arrival, broilers were vaccinated against coccidiosis (Paracox-5; Intervet Nederland BV, Boxmeer, the Netherlands) and randomly allotted to the floor pens. Fresh wood shavings were used as bedding material. Birds were housed in the floor pens until the end of the experiment at day 42. Ambient temperature was gradually decreased from 32°C at the start of the experiment to 21°C at 28 days of age. After 28 days of age, the temperature was kept constant on 21°C until the end of the experiment. Light was continuously on during the first day. The next day a schedule of 22 h light and 2 h dark was used. During the remaining experimental period a schedule of 14 h light, 4 h dark, 4 h light, 2 h dark was used. Feed and water were supplied ad libitum throughout the entire experiment. The Institutional Animal Care and Use Committee approved the experimental protocol.
Diets and conduct of the trial
The diets contained low (L), medium (M) or high (H) levels of RSM and SFM. The L treatment contained 50 g/kg RSM and 0 g/kg SFM in the starter period and 80 g/kg RSM and 0 g/kg SFM in the grower/finisher period. The M treatment contained 50 g/kg RSM and 50 g/kg SFM in the starter period and 80 g/kg RSM and 80 g/kg SFM in the grower/finisher period. The H treatment contained 80 g/kg RSM and 60 g/kg SFM in the starter period and 120 g/kg RSM and 100 g/kg SFM in the grower/finisher period. The two levels of enzyme inclusion were 0 or 100 g/tonne diet (Table 1). Experimental diets were supplied from day 0 until day 42. For both the starter period and the grower/finisher period first three large batches of the basal diets with the different levels of SFM and RSM were produced and mixed. Subsequently each batch was split into two sub-batches. To one of the sub-batches 100 g/tonne enzyme was added on top (Axtra™ XB 101 TPT containing 1220 U xylanase and 152 U β-glucanase per kg according to the manufacturer). The final mixes of each diet were then thoroughly mixed again. The starter diets were fed as a 2.5 mm pellet and the grower/finisher diets were fed as a 3.0 mm pellet. All diets met or exceeded nutrient requirements of broilers according to Dutch standards (CVB, 2007) or Ross 308 nutrient recommendations (2012).
AME=apparent metabolizable energy.
1 Supplied per kilogram of diet: vitamin A, 12 000 IU; vitamin D3, 2400 IU; vitamin E, 50 mg; vitamin K3, 1.5 mg; vitamin B1, 2.0 mg; vitamin B2, 7.5 mg; vitamin B6, 3.5 mg; vitamin B12, 20 mcg; niacin, 35 mg; d-pantothenic acid, 12 mg; choline chloride, 460 mg; folic acid, 1.0 mg; biotin, 0.2 mg; Fe, 80 mg (as Fe SO4. H2O); Cu, 12 mg (as CuSO4.5 H2O O); Mn, 85 mg (as MnO); Zn, 60 mg (as ZnSO4.H2O); Co, 0.4 mg (as Co SO4.7 H2O); I, 0.8 mg (as KI); Se, 0.15 mg (as Na2SeO3).
2 Values based on feed ingredients analysis in Table 2.
Carcass traits
On day 42, two randomly selected birds per pen were individually weighed, wing marked and delivered to a slaughter house. At the slaughter house, the broilers were electrically stunned, exsanguinated, defeathered and eviscerated. Carcass weight, fillet weight and weight of abdominal fat were determined. Carcass percentage was calculated as percentage of live weight, and fillet weight and abdominal fat weight were calculated as percentage of the carcass weight.
Digesta viscosity and gizzard weight measurements
On day 42, two randomly selected birds per pen were euthanized by intracardiac injection with T61 (0.1 ml/kg BW; Intervet Nederland BV), and jejunal digesta samples were taken for viscosity measurement and gizzards were collected. Jejunal digesta samples of two birds per pen were pooled and mixed thoroughly. Samples were centrifuged for 10 min (3500×g, 4°C, centrifuge model SL40R; Thermo Scientific, Thermo Fisher Scientific, Langenselbold, Germany). Viscosity of the filtered supernatant (0.5 ml) was measured at 6 r.p.m. at 20°C using a viscometer (Model LVCP; Brookfield Eng Labs Inc., Stroughton, MA, USA). The results of the viscosity measurements are reported in Cps. Full and empty gizzard weight were determined.
Chemical analysis
The basal diet was analysed for moisture (ISO 6496), ash (NEN 3329), CP (ISO/CD 15670), crude fat (ISO DIS 6492) and crude fibre (ISO 6865:2001) by Schothorst Feed Research. NSP and their constituent sugars determined by gas–liquid chromatography (Englyst et al., Reference Englyst, Quigley and Hudson1994).
Statistical analysis
The performance data were analysed by two-way ANOVA using the GLM procedure of SAS (2004) using cage as an experimental unit. A probability value of P<0.05 was described to be statistically significant, although P-values between 0.05 and 0.10 are shown and described as a trend. When a significant F-test was detected, means were separated using the LSD.
Results
Diets
The mean proximate composition and calculated nutrient contents of the diets are presented in Table 1. The types and levels of monosaccharides and non-NSP present in the feed ingredients are shown in Table 2. The total NSP level (g/100 g as fed) of the feed ingredients was as follows: 29 (SFM)>21.6 (RSM)>14.6 (SBM)>10.8 (wheat). Xylanase recovery was above target but within an acceptable range (mean 1700 XU/kg of diet for the starter phase and 1500 XU/kg of diet for the finisher phase). β-Glucanase recovery in the diets was not measured in this study.
1 NSPs and their constituent sugars were analysed by gas–liquid chromatography (Englyst et al., Reference Englyst, Quigley and Hudson1994).
2 Analysed.
Bird performance
During the starter period (1 to 21 days), birds fed the H levels of RSM and SFM (H) treatment had lower (P<0.05) BW gain (BWG) compared with those fed the L and M level treatments (Table 3). Diet type also influenced (P<0.05) feed intake (FI). Feeding the H treatment reduced (P<0.05) FI compared with the M treatment. Diet type and enzyme supplementation had no effect (P>0.05) on feed conversion ratio (FCR). During the grower/finisher phase (22 to 42 day) and over the entire period (1 to 42 day) birds fed the H treatment diet had lower (P<0.05) BWG and higher (P<0.05) FCR compared with those fed the L and M treatment diets. The main effect of enzyme supplementation improved (P<0.05) FCR compared with those fed the unsupplemented diets. No interactions (P>0.05) were observed for any of the measured parameters at any period.
a,b,cMeans in a column not sharing a common superscript are significantly different (P<0.05).
1 Each value represents the mean of eight replicates (20 birds per replicate).
2 Pooled standard error of mean.
Carcass traits and gizzard weight measurements
The effects of diet type and enzyme supplementation on carcass recovery, abdominal fat pad and breast meat yield are shown in Table 4. Diet type and enzyme supplementation had no effect (P>0.05) on carcass recovery, abdominal fat pad and breast meat yield. Diet type influenced (P=0.05) relative empty gizzard weight where the H treatment had higher relative empty gizzard weight compared with the L treatment. Enzyme supplementation tended (P=0.10) to increase relative empty gizzard weight. No interactions (P>0.05) between RSM and SFM inclusion level and enzyme supplementation were observed for gizzard and carcass parameters.
a,bValues in a column with different superscripts differ significantly at P<0.05.
1 Each value represents the mean of eight replicates (20 birds per replicate).
2 Pooled standard error of mean.
Digesta viscosity
Jejunal digesta viscosity was not affected (P>0.05) by diet type or enzyme supplementation. No interaction (P>0.05) was observed for jejunal digesta viscosity.
Discussion
The total NSP levels of wheat, SBM, RSM and SFM analysed in this study are comparable to those previously reported (Kocher et al., Reference Kocher, Choct, Porter and Broz2000; Meng and Slominski, Reference Meng and Slominski2005; Choct, Reference Choct2006; Khajali and Slominski, Reference Khajali and Slominski2012; Mikulski et al., Reference Mikulski, Jankowski, Zduńczyk, Juśkiewicz and Slominski2012). The level of arabinose and xylose together comprise around 3.8%, 6.5% and 9.8% for SBM, RSM and SFM, respectively. The level of crude fibre in the M and H diets increased by 30% and 43% in the starter and by 35% and 56% for the grower/finisher diets, respectively, compared with the L diets. The level of arabinoxylan in the M and H diets increased by 2% and 4.6% in the starter and by 3.5% and 6.6% for the grower/finisher diets, respectively, compared with the L diets.
The high inclusion of RSM and SFM in the H diets reduced weight gain and increased FCR compared with L and M inclusion levels of RSM and SFM. The negative effects of high inclusion of RSM and SFM may be related to the increased level of NSP which is known to possess anti-nutritional effects (Choct, Reference Choct2006). On the other hand, inclusion of M levels of SFM had no negative effect on any of the measured parameters which suggests that SFM can replace part of SBM, and birds can tolerate this increase in crude fibre without any negative effects on broiler performance or carcass quality. Previous studies showed that RSM and SFM could replace SBM (Rad and Keshavarz, Reference Rad and Keshavarz1976; Leeson et al., Reference Leeson, Atteh and Summers1987) without negative effects on performance when lysine was added as the limiting amino acid. In the current study all diets were formulated to contain the same level of digestible lysine. It should be noted, however, that the genetics of the birds in this study were different from these earlier reports. Rama Rao et al. (Reference Rama Rao, Raju, Panda and Reddy2006) reported no effect on BWG when replacing SBM (318 and 275 g/kg in the starter and grower/finisher periods, respectively) completely with SFM but feed efficiency was depressed progressively with increasing SFM (33%, 67% and 100% SFM replacement of SBM) and this depression reached significance at 67% level compared to the control. Senkoylu and Dale (Reference Senkoylu and Dale1999) concluded that SFM can successfully be added to broiler diets to replace 50% to 100% of SBM, depending on the type of diet and the nature of the other ingredients. In a maize based diet, Kalmendal et al. (Reference Kalmendal, Elwinger, Holm and Tauson2011) reported that weight gain between 15 and 31 days of age was increased linearly with high-fibre sunflower cake inclusion at levels of 0%, 10%, 20% and 30%. However, feed conversion was negatively affected by the 30% inclusion but not the 20% inclusion. Similarly, Khajali and Slominski (Reference Khajali and Slominski2012) concluded that broiler diets could contain up to 20% of RSM without any adverse effects on performance. These inconsistent results may be explained by the different broiler genetics, the basal diets (wheat or corn), feed form (mash or pellet), oil extraction method and the NSP levels of the RSM and the SFM. However, in general, it appears from this trial and previous reports that moderate inclusion of SFM does not have negative effects on broiler performance.
High inclusion level of RSM and SFM in this study negatively influenced the weight gain. Enzyme supplementation did not recover this negative effect on weight gain as indicated by the lack of main effect of enzyme supplementation or the interactions. However, enzyme supplementation improved FCR regardless of the levels of RSM and SFM included in this study as indicated by the lack of significant interactions between RSM and SFM inclusion level and enzyme supplementation. In contrast, Kocher et al. (Reference Kocher, Choct, Porter and Broz2000) reported no effect of enzymes on broiler performance in diets with RSM or SFM. In an in vitro study, Malathi and Devegowda (Reference Malathi and Devegowda2001) found that a combination of xylanase and cellulase was superior in SFM. In their review on the effect of RSM inclusion in poultry diets Khajali and Slominski (Reference Khajali and Slominski2012) concluded that enzymes have proven to improve nutrient utilisation and consequently poultry performance when RSM was included in the diets. It should be noted, however, in the current study birds in all treatments exceeded the performance objective of this breed (Ross, 2012) which suggests that enzymes can be beneficial even in well performing broiler chickens. Exogenous enzymes degrade cell wall components such as soluble and insoluble arabinoxylans and β-glucans, releasing encapsulated nutrients inside the cell wall at the same time as reducing digesta viscosity caused by soluble fibre (Choct, Reference Choct2006). In the current study, jejunal digesta viscosity was not influenced by diet type or enzyme supplementation. The lack of enzyme effect on digesta viscosity may be explained by the already low digesta viscosity which is comparable to values reported in birds fed corn based diets (Amerah et al., Reference Amerah, Quiles, Medel, Sánchez, Lehtinen and Gracia2013). Therefore, the mechanism of releasing encapsulated nutrients may explain the positive effect of enzyme supplementation. Other mechanisms have also been proposed, including decreased endogenous enzyme production, reduced energy expenditure on intestinal cell turnover rate and shifting production of volatile fatty acids and absorption of energy-yielding monosaccharides in the proximal intestine (Adeola and Cowieson, Reference Adeola and Cowieson2011).
High inclusion of RSM and SFM in the H diets increased the relative empty gizzard weight. Previous studies in broiler chickens or turkeys have shown that higher inclusion of RSM and SFM increased the relative gizzard weight (Rama Rao et al., Reference Rama Rao, Raju, Panda and Reddy2006; Mikulski et al., Reference Mikulski, Jankowski, Zduńczyk, Juśkiewicz and Slominski2012). Insoluble NSP is known to stimulate gizzard function and increase gizzard size (Svihus, Reference Svihus2011) and this was found to depend on the particle size of the insoluble NSP (Amerah et al., Reference Amerah, Ravindran and Lentle2009). Unfortunately, the feed particle size was not analysed in this study to compare between treatments. But, the analysed level of the insoluble NSP in the current study for SFM was found to be more than double the amount present in SBM, and the level in the RSM is in the middle between the two. Therefore, the H level of the insoluble NSP in RSM and SFM may explain the relative higher gizzard weight in the birds fed the high SFM and RSM inclusion diets. More developed gizzard is known to have beneficial effects on gut function and nutrient digestibility values (Svihus, Reference Svihus2011) which may explain the good performance relative to the breed objectives in the birds fed high SFM and RSM inclusion diets. Inclusion of RSM and SFM had no effect on carcass recovery, breast meat yield and abdominal fat. Similar results were observed in broilers and turkeys (Ghorbani et al., Reference Ghorbani, Fayazi and Chaji2009; Mikulski et al., Reference Mikulski, Jankowski, Zduńczyk, Juśkiewicz and Slominski2012). Rama Rao et al. (Reference Rama Rao, Raju, Panda and Reddy2006) reported no effect of low inclusion of SFM on carcass recovery but high inclusion depressed carcass recovery. These data suggest that moderate inclusion of RSM and SFM does not influence carcass characteristics of broiler chickens.
In conclusion, the present data suggest that moderate inclusion of SFM has no negative effect on broiler performance and carcass characteristics. In contrast, high inclusion of SFM and RSM negatively influenced broiler performance. Enzyme supplementation improved FCR at all levels of RSM and SFM included in this study, but did not recover the reduction in weight gain caused by high inclusion of RSM and SFM.