Hostname: page-component-cd9895bd7-fscjk Total loading time: 0 Render date: 2024-12-20T20:12:56.421Z Has data issue: false hasContentIssue false

A direct fed microbial containing a combination of three-strain Bacillus sp. can be used as an alternative to feed antibiotic growth promoters in broiler production

Published online by Cambridge University Press:  14 May 2014

Yueming Dersjant-Li*
Affiliation:
Danisco Animal Nutrition, Market House, Ailesbury Court, High Street, SN8 1AA Marlborough, Wiltshire, UK
A. Awati
Affiliation:
Danisco Animal Nutrition, Market House, Ailesbury Court, High Street, SN8 1AA Marlborough, Wiltshire, UK
C. Kromm
Affiliation:
Danisco Animal Nutrition, Market House, Ailesbury Court, High Street, SN8 1AA Marlborough, Wiltshire, UK
C. Evans
Affiliation:
Danisco Animal Nutrition, Market House, Ailesbury Court, High Street, SN8 1AA Marlborough, Wiltshire, UK
*
Corresponding author:[email protected]
Rights & Permissions [Opens in a new window]

Summary

The objective of the study was to test the effect of a direct fed microbial (DFM) on the performance of broilers compared to an antibiotic growth promoter under large scale, commercial production settings. Three dietary treatments were tested in a completely randomized design including: 1) a control (C) diet containing 500 FTU/kg phytase and a mixture of xylanase, amylase, protease ; 2) C+ a specific three-strain combination of Bacillus spp. (DFM) and 3) C+ bacitracin methylene disalicylate (BMD). Six, similar commercial broiler houses (15,300 birds per house) were used to give two replicate houses per treatment. The birds (Hubbard x Cobb500) were fed pelleted and crumbled diets ad libitum throughout the 44 day trial period. Due to the large scale, commercial nature of the trial, no significant differences were observed in production parameters among treatments, except that DFM treatment resulted in significantly lower mortality numbers in the last two days (43 to 44d) compared to the control. However, the DFM treatment group showed numerically higher live bodyweight, lower feed conversion ratio (corrected for body weight and mortality) and lower total mortality weight compared to either the control or BMD groups, resulting in an improved production efficiency factor. When compared to control, using DFM resulted in a gross benefit of US$ 0.06 /bird, while using BMD was not cost effective. In conclusion, DFM containing a three-strain combination of Bacillus spp. may be used as an alternative to antibiotic growth promoters, resulting in economic benefit under commercial production settings in broilers fed commercial diets.

Type
Commercial Trial
Creative Commons
Creative Common License - CCCreative Common License - BY
The online version of this article is published within an Open Access environment subject to the conditions of the Creative Commons Attribution licence http://creativecommons.org/licenses/by/3.0/
Copyright
Copyright © Cambridge University Press (2014)

Introduction

In today's poultry production systems, disease challenges caused by various pathogens such as E. coli, Salmonella spp., Clostridium perfringens and Campylobacter spp. are of major economic concern (Jayaraman et al., Reference Jayaraman, Thangavel, Kurian, Mani, Mukkalil and Chirakkal2013). In some countries, antibiotic growth promoters (AGPs) are used to reduce the impact of these pathogens and control diseases. However, with increasing public concerns regarding bacterial resistance to antibiotics, AGPs have been banned in animal feed in Europe since 2006 and it is expected that in the near future their use will be eliminated from animal feed in other countries. Finding alternatives to AGPs has long been of interest to the feed industry.

Direct-fed microbials (DFMs) are defined as ‘live microorganisms which, when administrated in adequate amounts, confer a health benefit on the host’ (FAO/WHO. 2002). Many studies have shown that DFMs are potential alternatives to AGPs in animal feed (Applegate et al., Reference Applegate, Klose, Steiner, Ganner and Schatzmayr2010; Amerah et al., Reference Amerah, Jansen van Rensburg, Plumstead, Kromm and Dunham2013a). DFMs are effective in improving immune response and growth performance of broilers (Lee et al., Reference Lee, Lillehoj and Siragusa2010a,Reference Lee, Lee, Lillehoj, Li, Jang, Babu, Park, Kim, Lillehoj, Neumann, Rehberger and Siragusab; Lutful Kabir, Reference Lutful Kabir2009).

Substrate supply is essential to maintain the beneficial bacterial population in the gut. Using feed enzymes, such as protease can reduce the indigestible protein which is a substrate for pathogenic bacteria. Carbohydrase can degrade indigestible non-starch polysaccharides (NSPs) and provide substrates for beneficial bacteria (Kiarie et al., Reference Kiarie, Romero and Nyachoti2013). Therefore, the combination of DFMs and multi-enzymes may have a synergic effect and result in better nutrient utilisation and gut health (Momtazan et al., Reference Momtazan, Moravej, Zaghari and Taheri2011). Previous studies have suggested that the combination of DFMs and enzymes (used in most commercial poultry diets) can be used as growth promoters in broilers (Reddy et al., Reference Reddy, Kondal, Kuhad, Shashi and Gnana2010).

Most of the studies have been carried out under research conditions and only limited studies have been reported under commercial settings. However, for poultry producers, the publication of data from large scale, commercial studies is highly relevant in providing information regarding the expected outcomes of using a DFM in their flocks. Therefore the objective of this study was to determine the performance of broilers fed a DFM product in comparison to AGPs in diets supplemented with multi-enzymes on a commercial farm in the United States.

Materials and methods

Three dietary treatments were tested in two replicate poultry houses, which were randomly assigned to treatments 1) a control (C) diet containing 500 FTU/kg phytase (Phyzyme® XP, Danisco Animal Nutrition/DuPont, Marlborough, Wiltshire, UK, and an enzyme mix containing xylanase, amylase, protease (Axtra® XAP, Danisco Animal Nutrition/DuPont, Marlborough, Wiltshire, UK); 2) C + DFM (containing spores of a three-strain combination of Bacillus sp., Enviva® PRO, Danisco Animal Nutrition/Dupont, Marlborough, Wiltshire, UK); 3) C+ Bacitracin Methylene Disalicylate (BMD) (Zoetis, 100 Campus Drive, Florham Park, NJ 07932, United States).

Diets were formulated to meet commercial recommendations for starter (0.7 kg/bird), grower (1.4 kg/bird), finisher 1 (1.8 kg/bird) and finisher 2 (until slaughter) and were based on corn and soyabean meal (SBM) and contained 5–12% distillers dried grains (DDGs). The composition of the control (C) diet is presented in Table 1. The treatment diets were produced by addition of the test material to the C diet as a replacement for corn (0.5 g/kg). All diets were pelleted (~90oC) and crumbled after pelleting. Feed and water were supplied ad libitum.

Table 1. Control diet composition and calculated nutritional values

1XAP is a mixed enzyme containing xylanase, amylase and protease (Axtra® XAP, Danisco Animal Nutrition/Dupont); 2Phytase is an E. coli phytase enzyme (Phyzyme® XP, Danisco Animal Nutrition/Dupont).

A total of 91,800 day-old mixed-sex broilers (Hubbard × Cobb 500) were distributed in equal numbers to six commercial broilers houses (15,300 chicks per house) with a stocking density of 12 birds/m2. The six houses were similar in construction, design, size, compass direction, insulation, heating, ventilation, lighting, watering system, feed equipment and management practices, to minimise residual variation due to housing. Each house had industry standard ventilation and temperature control systems. The birds received vaccination against Marek's, infectious bursal disease, Newcastle disease, infectious bronchitis, laryngotracheitis and coccidiosis (Coccivac B) at the hatchery. The birds were observed daily for clinical signs of disease. Birds were housed on built up litter, as is common commercial practice in the US.

Mortality and culls were recorded daily and calculated weekly. Body weights were measured at 0, 7, 16, 29, 38 and 44 d of the trial; weight gain, feed intake and feed conversion ratio were recorded or calculated for the whole 0–44 d period. At the end of the grow-out period all birds were slaughtered at the commercial farm via a certified practical processing procedure. The processed number and total live weight of birds were recorded.

Feed conversion ratio (FCR) was calculated as:

$${\rm FCR}= \displaystyle{{{\rm kg\; feed}} \over {{\rm kg\; weight\; gain}}}$$

Mortality and cull weight adjustment feed conversion ratio (FCRmc) was calculated as

$${\rm FCRmc} =\displaystyle{\hbox{kg feed} \over \hbox{kg of weight gain + weight gain of all mortality and culled birds}}$$

Body weight and mortality weight corrected feed conversion ratio (FCRbmc) was calculated by allowing three points reduction in FCRmc for every 100 g BW increase versus control:

$${\rm FCRbmc}={\rm FCRmc} - \displaystyle{{{\rm BWtr} - {\rm BWcontr}} \over {100}}*0.03$$

Where: BWtr: body weight of bird in treatment group; BWcontr : body weight of bird in control group.

Gross cost/benefit was calculated based on current prices of each feed and live weight at slaughter, assuming no difference in other production cost between the control and test groups. Production efficiency factor (PEF) was used to evaluate the live-bird performance of flocks (Shane, http://www.datapoul.co.uk/wp-content/uploads/ProductionEfficiencyFactor.pdf). PEF was calculated as:

$${\rm PEF}=\; \displaystyle{{{\rm liveweight\; }\left({{\rm kg}} \right){\rm \; *\; liveability\; }\left({\rm \percnt } \right)} \over {{\rm age\; at\; depletion\; }\left({{\rm days}} \right){\rm *FCR}}}\; * 100$$

PEF did not take into account the fact that deaths at different ages may have a different level of loss due to mortality (e.g. death early versus late in the production cycle). This discourages the use of PEF in commercial conditions to compare the effect of different additives. Therefore, the authors proposed a modified PEF (MPEF) which corrects for mortality weight and it is calculated as:

$${\rm MPEF} =\; \displaystyle{{{\rm liveweight\; }\left({{\rm kg}} \right){\rm \; *\; liveability\; }\left({\rm \percnt } \right)} \over {{\rm age\; at\; depletion\; }\left({{\rm days}} \right){\rm *FCRmc}}}\; \; * 100$$

House means were used to derive mortality, feed intake, body weight gain and feed conversion ratio data. Data were subjected to one way ANOVA using the JMP 10.0 software (SAS Institute Inc, 2012) and treatment means were separated by Tukey HSD test. Differences were considered to be significant at P < 0.05.

Results and Discussion

Due to the large scale production system used and low number of replicates, the only significant difference (P < 0.05) was found in mortality number in the last two days. However, as the trial was carried out at commercial scale with a large number of birds, numerical improvement on production parameters can be considered as relevant.

Weight gains were not significantly affected by dietary treatment, although the DFM diet resulted in numerically higher mean body weights, weight gains and total live bodyweight production when compared to the control and BMD groups (Table 2). Feed conversion ratio was numerically lower in the DFM treatment group compared to the control and BMD groups. The lowest (numerically) calorie conversion ratio (kcal/kg BWG) was observed with DFM treatment (Table 2). The weekly and cumulative mortality numbers were presented in Figure 1. Although no significant differences were seen for cumulative mortality numbers among treatments, the DFM diet reduced cumulative mortality by 22% compared to the control flocks. In the last two days of the trial (43 to 44d), both DFM and BMD groups had lower mortality numbers (P < 0.05) compared to the control (Figure 1). Over the whole trial period, feeding DFM or BMD numerically reduced mortality weight by 40% and 17% respectively compared to the birds fed the control diet (Table 2).

Figure 1. Effect of DFM and BMD on average number of mortality per period (left) and cumulative number per period (right) (15,300 chicks per replicate), significant difference was found in the last two days (43–44d, P < 0.05).

Table 2. Effect of DFM1 and BMD2 on growth performance, feed utilisation, mortality and economic benefit in broilers produced under commercial production settings

1 DFM: a three-strain combination of Bacillus sp.

2 Bacitracin Methylene Disalicylate (BMD) at inclusion level of 50 ppm.

3 Body weight and mortality weight corrected FCR.

4 Calculated based on 2013 US market price at US$1.8/kg live weight.

5 Feed cost based on 2013 commercial feed cost for a corn SBM based broiler diet in US market (Janet Remus, personal communication).

6 The gross benefit of DFM was calculated as US$917/15300*100 = 6 US$cent/bird when compared to control.

7 PEF: production efficiency factor.

8 MPEF: modified production efficiency factor.

This study showed clear advantage of using DFM compared to AGPs in a corn-soy broiler diet containing enzymes and reared in a commercial production system with built up litter. DFM treatment had a positive effect on reducing total mortality number and weight. It is well known that intestinal tracts of newly hatched birds are sterile and contain almost no microflora (Lee et al., Reference Lee, Lillehoj and Siragusa2010a). Microbes from the environment and feed gradually colonise the GI tract and form a stable microflora population over time (Lee et al., Reference Lee, Lillehoj and Siragusa2010a). Dietary DFMs have a positive impact on this process, by helping the birds to develop a beneficial and stable microflora population (Lee et al., Reference Lee, Lillehoj and Siragusa2010a). This may explain the lower mortality rate in the DFM fed birds, especially in the first week (12.5% reduction vs. control) when young birds are more susceptible to pathogens and in pre-slaughter period (36–44 days, 40% reduction vs. control) where birds are challenged by increased stocking density and the build up of environmental pathogens. The lower mortality in the DFM fed birds suggests improved intestinal health.

When cost benefit was calculated based on income from live weight and feed cost, DFM treatment resulted in 2.3% higher gross benefit when compared to control (Table 2). This corresponded to the highest Production Efficiency Factors (PEF & MPEF) being observed with the DFM treatment (Table 2). The MPEF was estimated as 329.4, 321.3 and 321.5 respectively for DFM, control and BMD treatments.

The DFM used in this study consisted of the spores of a three-strain combination of Bacillus spp., which is suitable for use in animal feed as a live microbial product due to its long shelf life and retained viability during distribution, feed processing and storage (Cartman et al., Reference Cartman, La Ragione and Woodward2008). Cartman et al. (Reference Cartman, La Ragione and Woodward2008) observed that these spores were able to germinate rapidly within the animal, and vegetative cells were detected throughout the GI tract of chickens 20 h after dosing, when the product was administrated to day- old chicks. Furthermore, it has been found that spore forming probiotics can survive heat treatment (Amerah et al., Reference Amerah, Quiles, Medel, Sánchez, Lehtinen and Gracia2013b) and are compatible with coccidiostats (Kampf et al., Reference Kampf, Rovers and Nakamura2012).

The numerically improved growth performance and feed utilisation efficiency due to DFM supplementation observed in this commercial scale study is in agreement with previous studies (Lee et al., Reference Lee, Lee, Lillehoj, Li, Jang, Babu, Park, Kim, Lillehoj, Neumann, Rehberger and Siragusa2010b; Amerah et al., Reference Amerah, Jansen van Rensburg, Plumstead, Kromm and Dunham2013a; Sen et al., Reference Sen, Ingale, Kim, Kim, Kim, Lohakarea, Kim, Kim, Ryu, Kwon and Chae2012). It has been reported that the use of a DFM containing Bacillus spp. has a positive effect on the performance and immune system of broiler chicks (Teo and Tan, Reference Teo and Tan2007; Kim et al., Reference Kim, Ingale, Kim, Kim, Sen, Ryu, Lohakare, Kwon and Chae2012; Amerah et al., Reference Amerah, Jansen van Rensburg, Plumstead, Kromm and Dunham2013a). Timmerman et al. (Reference Timmerman, Veldman, van den Elsen, Rombouts and Beynen2006) observed that chicken specific DFM preparations reduced mortality in broilers.

Timmerman et al. (Reference Timmerman, Veldman, van den Elsen, Rombouts and Beynen2006) suggested that the effects of DFMs are inversely related to production index i.e., DFMs are more effective when the production index is low. It was estimated that production index (which ranged between 170 and 310) improved by 1.8 to 31.6% due to addition of DFMs. In the current study, DFM treatment increased PEF by 3% and MPEF by 2.5%, which was associated with a high PEF index (327 vs. 318 for the control) observed in this study. MPEF gives a good indication on productivity, as this calculation considers weight gain, survival and mortality corrected feed conversion. However, this calculation does not include feed cost. The gross profit was calculated based on incomes from live weight of birds and feed cost, when compared to the control diet. This calculation demonstrated that using DFM resulted in US$0.06/bird gross benefit compared to the control-fed birds, while AGP treatment did not give any economic benefit. This suggests that it may be more cost effective to use DFMs rather than AGPs in broiler production.

Maintaining a stable population of beneficial microflora is important for improving intestinal health and reducing the nutrient and energy cost for gut maintenance. The benefits of using DFM in combination with enzymes have been reported in number of studies (Murugesan, Reference Murugesan2013; Romero et al., Reference Romero, Indrakumar and Ravindran2013). In the current study, the basal diet contained phytase, xylanase, amylase and protease, which can reduce the anti-nutritional effect of phytate, increase digestibility of protein and carbohydrates and reduce the endogenous secretions, resulting in increased energy utilisation (Cowieson and Ravindran, Reference Cowieson and Ravindran2008). The result being that the activities of the enzymes limit the substrates available for pathogenic bacteria, and can provide substrates for beneficial bacteria (Bedford and Cowieson, Reference Bedford and Cowieson2012). Therefore, enzymes may stimulate the growth of the DFM and result in a synergistic, positive effect on poultry performance. The results from the current study demonstrate that it is beneficial to use DFM in broiler diet supplemented with multi-enzymes under commercial settings.

Conclusions

Supplementation of a three-strain combination of Bacillus spp. to broilers diets reduced mortality and improved production efficiency. The results from this study indicated that DFM may be used as alternative to AGP and can result in economic benefits under commercial production settings with broilers fed commercial diets containing multi-enzymes.

Acknowledgments

The authors would like to thank Du Pont/Danisco Animal Nutrition, UK Ltd for their financial support of this research.

Declaration of Interest

Yueming Derjant-Li, Ajay Awati and Ceinwen Evans are employees of Du Pont/Danisco Animal Nutrition, UK Ltd.

References

Amerah, A.M., Jansen van Rensburg, C., Plumstead, P.W., Kromm, C. and Dunham, S. (2013a) Effect of feeding diets containing a probiotic or antibiotic on broiler performance, intestinal mucosa-associated avian pathogenic E. coli and litter water-soluble phosphorus. Journal of Applied Animal Nutrition, Vol. 1; e7; page 1 of 7. doi:10.1017/jan.2013.4.Google Scholar
Amerah, A.M., Quiles, A., Medel, P., Sánchez, J., Lehtinen, M.J. and Gracia, M.I. (2013b) Effect of pelleting temperature and probiotic supplementation on growth performance and immune function of broilers fed maize/soy-based diets. Animal Feed Science and Technology, 180: 5563.CrossRefGoogle Scholar
Applegate, T.J., Klose, V., Steiner, T., Ganner, A. and Schatzmayr, G. (2010) Probiotics and phytogenics for poultry: Myth or reality? Journal of Applied Poultry Research, 19:194210.Google Scholar
Bedford, M.R. and Cowieson, A.J. (2012) Exogenous enzymes and their effects on intestinal microbiology. Animal Feed Science and Technology, 173: 7685.Google Scholar
Cartman, S.T., La Ragione, R.M. and Woodward, M.J. (2008) Bacillus subtilis Spores Germinate in the Chicken Gastrointestinal Tract. Applied and Environmental Microbiology, 74: 52545258.Google Scholar
Cowieson, A.J. and Ravindran, V. (2008) Effects of exogenous enzymes in maize-based diets varying in nutrient density for young broilers: growth performance and digestibility of energy, minerals and amino acids. British Poultry Science, 49: 47–44.CrossRefGoogle ScholarPubMed
Jayaraman, S., Thangavel, G., Kurian, H., Mani, R., Mukkalil, R. and Chirakkal, H. (2013) Bacillus subtilis PB6 improves intestinal health of broiler chickens challenged with Clostridium perfringens-induced necrotic enteritis. Poultry Science, 92:370374.Google Scholar
Kiarie, E., Romero, L.F. and Nyachoti, C.M. (2013) The role of added feed enzymes in promoting gut health in swine and poultry. Nutrition Research Reviews 26: 7188.CrossRefGoogle ScholarPubMed
FAO/WHO. (2002) Guidelines for the evaluation of probiotics in food. Report of a joint Food and Agriculture Organisation (FAO)/World Health Organisation (WHO) working group on drafting guidelines for the evaluation of probiotics in food. World Health Organisation. http://www.who.int/foodsafety/fs_management/en/probiotic_guidelines.pdf.Google Scholar
Kampf, D., Rovers, M. and Nakamura, N. (2012) Spore forming probiotic Bacillus subtilis C-3102 in pig and poultry diets. http://www.orffa.com/site/products-probiotics-calsporin-uk/$FILE/Kampf-ea-2012-ATA-abstract-Spore-forming-probiotic-Bacillus-subtilis-C3102-in-pigs-and-poultry.pdf.Google Scholar
Kim, J.S., Ingale, S.L., Kim, Y.W., Kim, K.H., Sen, S., Ryu, M.H., Lohakare, J.D., Kwon, I.K. and Chae, B.J. (2012) Effect of supplementation of multi-microbe probiotic product on growth performance, apparent digestibility, cecal microbiota and small intestinal morphology of broilers. Journal of Animal Physiology and Animal Nutrition (Berl), 96: 618626.Google Scholar
Lee, K.W., Lillehoj, H.S. and Siragusa, G.R. (2010a) Review: direct-fed microbials and their impact on the intestinal microflora and immune system of chickens. The Journal of Poultry Science 47: 106114.Google Scholar
Lee, K.W., Lee, S.H., Lillehoj, H.S., Li, G.X., Jang, S.I., Babu, U.S., Park, M.S., Kim, D.K., Lillehoj, E.P., Neumann, A.P., Rehberger, T.G. and Siragusa, G.R. (2010b) Effects of direct-fed microbials on growth performance, gut morphometry, and immune characteristics in broiler chickens. Poultry Science 89: 203216.Google Scholar
Lutful Kabir, S.M. (2009) The role of probiotics in the poultry industry. International Journal of Molecular Sciences, 10: 35313546.Google Scholar
Momtazan, R., Moravej, H., Zaghari, M. and Taheri, H.R. (2011) A note on the effects of a combination of an enzyme complex and probiotic in the diet on performance of broiler chickens. Irish Journal of Agricultural and Food Research, 50: 249254.Google Scholar
Murugesan, G.R. (2013) Characterisation of the effects of intestinal physiology modified by exogenous enzymes and direct-fed microbial on intestinal integrity, energy metabolism, body composition and performance of laying hens and broiler chickens. Ph. D. Thesis, Iowa State University.Google Scholar
Reddy, P.V.M., Kondal, R.K., Kuhad, R.C., Shashi, K.M. and Gnana, P.M. (2010) Effect of supplementation of enzymes and probiotics on performance of broiler chicken. Indian Journal of Poultry Science, 45: 361363.Google Scholar
Romero, L.F., Indrakumar, S.E. and Ravindran, V. (2013) Influence of combinations of a direct-fed microbial and exogenous enzymes on the nutrient digestibility in broilers at 11 d and 21 d of age. Poultry Science 92(E-Suppl. 1):88.Google Scholar
Sen, S., Ingale, S.L., Kim, Y.W., Kim, J. S., Kim, K. H., Lohakarea, J. D., Kim, E. K., Kim, H. S., Ryu, M. H., Kwon, I. K. and Chae, B.J. (2012) Effect of supplementation of Bacillus subtilis LS 1–2 to broiler diets on growth performance, nutrient retention, caecal microbiology and small intestinal morphology. Research in Veterinary Science 93: 264268.Google Scholar
Shane, S. What's your ‘PEF’? Live Production Management. http://www.datapoul.co.uk/wp-content/uploads/ProductionEfficiencyFactor.pdfGoogle Scholar
Teo, A.Y. and Tan, H.M. (2007) Evaluation of the Performance and Intestinal Gut Microflora of Broilers Fed on Corn-Soy Diets Supplemented With Bacillus subtilis PB6 (CloSTAT). Journal of Applied Poultry Research, 16: 296303.CrossRefGoogle Scholar
Timmerman, H.M., Veldman, A., van den Elsen, E., Rombouts, F.M. and Beynen, A.C. (2006) Mortality and growth performance of broilers given drinking water supplemented with chicken-specific probiotics. Poultry Science 85:13831388.Google Scholar
Figure 0

Table 1. Control diet composition and calculated nutritional values

Figure 1

Figure 1. Effect of DFM and BMD on average number of mortality per period (left) and cumulative number per period (right) (15,300 chicks per replicate), significant difference was found in the last two days (43–44d, P < 0.05).

Figure 2

Table 2. Effect of DFM1 and BMD2 on growth performance, feed utilisation, mortality and economic benefit in broilers produced under commercial production settings