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Archivos de Zootecnia

On-line version ISSN 1885-4494Print version ISSN 0004-0592

Arch. zootec. vol.62 n.238 Córdoba Jun. 2013

https://dx.doi.org/10.4321/S0004-05922013000200011 

 

Effects of inulin and a probiotic mixture on nutrient digestibility and nitrogen balance in piglets

Efeito da inulina e de probióticos sobre a digestibilidade dos nutrientes e balanço do nitrogênio em leitões

 

 

Rodrigues, M.1*; Pozza, P.C.2; Pozza, M.S.S.3A; Possamai, M.3B; Bruno, L.D.G.3C; Richart, E.3D; Wochner, M.O.3E and Pereira Júnior, J.M.3F

1Universidade Estadual Paulista. Faculdade de Medicina Veterinária e Zootecnia. Departamento de Produção Animal. Botucatu, SP. Brasil. *mayara_rodriguez@yahoo.com.br
2Universidade Estadual de Maringá. Departamento de Zootecnia. Maringá, PR. Brasil. pcpozza@yahoo.com.br
3Universidade Estadual do Oeste do Paraná. Marechal Cândido Rondon, PR. Brasil. Amagaspozza@hotmail.com; Bdm_maikel@hotmail.com; Cldgbruno@gmail.com; Dedson_richart@hotmail.com; Emanomw@hotmail.com; Fjoao_morais@zootecnista.com.br

Acknowledgments to ITAIPU-Binacional for the financial support to develop the research.

 

 


SUMMARY

This study aimed to evaluate different inulin and probiotic levels as supplement in diets for piglets on nutrient digestibility and nitrogen balance. Twenty four crossbred barrows (Pietráin x Landrace x Large White), with initial average weight of 18.00 ± 0.38 kg, were individually housed in metabolic cages. The experimental design was a completely randomized block, in a 2 x 3 factorial scheme (probiotic levels: 0.30 and 0.60 %; inulin levels: 0.00, 0.25 and 0.50 %), with four replications. The probiotic used was a mix of Lactobacillus acidophillus, Streptococcus faecium and Bifidobacterium bifidum. The inulin was the prebiotic used in this study, characterized as an indigestible carbohydrate formed by fructooligosaccharides. Inulin levels provided a quadratic effect (p<0.05) on the digestibility coefficients of dry matter, organic matter and ether extract, and the better responses were obtained supplementing 0.194, 0.185 and 0.188 %. Quadratic effects were observed for the nitrogen excreted in feces, total nitrogen excretion, nitrogen efficiency use and nitrogen digestibility. The inulin levels of 0.194 and 0.216 %, in piglet diets, were the better for dry matter digestibility and total nitrogen excretion, respectively.

Key words: Bifidobacterium bifidum. Digestibility. Oligosaccharides.


RESUMO

O objetivo deste trabalho foi avaliar o efeito de níveis de inulina e probióticos em rações para leitões sobre a digestibilidade dos nutrientes e balanço do nitrogênio. Foram utilizados 24 suínos mestiços (Pietráin x Landrace x Large White), machos castrados, com peso médio inicial de 18,00 ± 0,38 kg, alojados individualmente em gaiolas de metabolismo. O delineamento experimental utilizado foi o de blocos ao acaso em esquema fatorial 2 x 3, representado por dois níveis de probiótico (0,30 e 0,60 %) e três níveis de inulina (0,00; 0,25 e 0,50 %), com quatro repetições. O probiótico utilizado foi composto por Lactobacillus acidophillus, Streptococcus faecium e Bifidobacterium bifidum. A inulina foi o prebiótico utilizado, caracterizada como um carboidrato não digerível composto por frutoligossacarídeos. A inulina proporcionou efeito quadrático (p<0,05) nos coeficientes de digestibilidade da matéria seca, matéria orgânica e extrato etéreo, e as melhores respostas foram obtidas com a suplementação de 0,194; 0,185 e 0,188 %. Efeitos quadráticos foram observados para o nitrogênio excretado nas fezes, excreção total de nitrogênio, eficiência de uso do nitrogênio e digestibilidade do nitrogênio. Os níveis de 0,194 e 0,216 % de inulina, na ração de leitões, foram os melhores para a digestibilidade da matéria seca e excreção total de nitrogênio, respectivamente.

Palavras chave: Bifidobacterium bifidum. Digestibilidade. Oligossacarídeos.


 

Introduction

Alternative ingredients to substitute growth promoters in swine diets are studied and developed based on new concepts of food safety, such as prebiotics and probiotics that, when used together and with specificity, establishes the symbiotic concept and can be used in swine diets.

Probiotics are live cultures of organisms supplemented in pig diets that can beneficially affect the host animal by improving the microbial balance in the gut (Fuller, 1989), and may influence digestive process by increasing the population of beneficial microorganisms and activity of microbial enzymes, as well as improving nutrient digestibility and use.

Prebiotics are defined as a non-digestible food ingredient that beneficially affects the host by selectively stimulating the growth and/or activity of one or a limited number of bacteria in the colon (Gibson and Roberfroid, 1995). These compounds are indigestible oligosaccharides (Delzenne, 2003) not necessarily grouped by the structure, but according to their capacity to promote growth of certain beneficial bacteria (probiotics) in the gut (Kelly, 2008). Inulin is known as a prebiotic and consists of a mixture of fructan chains with a polymerizing degree varying from 2 to 60 (Roberfroid, 1993), is resistant to digestive enzymes, due to its glycoside β bonds (2→1), and is believed to increase growth of beneficial bacteria (Zentek et al., 2003).

The use of prebiotics, probiotics or its combination as a simbiotic is an alternative to replace growth promoters without impairing the swine performance (Chiquieri et al., 2006). Using a symbiotic in diets for weaned piglets, Shim et al. (2005) reported an increased villous height in the small gut, which is an indicative of improved nutrient absorption. Pierce et al. (2005) observed an improvement in gross energy digestibility in piglet diets containing 1.50 % of inulin and a low lactose level.

Prebiotics may also reduce the nitrogen excretion to the environment. Besides, Lynch et al. (2007) reported that supplementing inulin in piglet diets may favor the bifidobacteria growing in the cecum, increase fecal nitrogen content and reduce the nitrogen amount in urine.

Therefore, the prebiotic's effect on the nitrogen contained in the diet occurs due to fermentation in the large gut, which induces changes in urine nitrogen excreted as urea (Zervas and Zijlstra, 2002). According to Nahm (2003), the result is a decrease in ammonia emision during waste storage and field application.

This study aimed to evaluate the effects of inulin and probiotic on nutrient digestibility and nitrogen balance in piglets.

 

Material and methods

This study was carried out in the metabolism room, situated in the experimental of the Universidade Estadual do Oeste do Paraná, Brazil. The experimental procedures were in agreement with the Animal Welfare Committee of this Institution.

Twenty four crossbred barrows (Pietráin x Landrace x Large White), averaging 18.00 ± 0.38 kg of initial weight, were individually allotted and distributed in a completely randomized blocks design, in a 2 x 3 factorial scheme (probiotic levels-0.30 and 0.60 %; inulin levels-0.00, 0.25 and 0.50 %), with four replicates.

The probiotic used was a mix of Lactobacillus acidophillus, Streptococcus faecium and Bifidobacterium bifidum. The inulin was the prebiotic used in this study, characterized as an indigestible carbohydrate formed by fructooligosaccharides.

Experimental diets (table I) were formulated to achieve the nutritional requirements proposed by Rostagno et al. (2005). Barrows were fed twice a day (06 a.m. and 06 p.m.) and after each meal the water was freely offered. The individual feed intake was based on the metabolic weight (BW0.75), established during the adjustment period.

 

The metabolism assay used a seven day adjustment period, followed by a five day period of total collection of feces and urine. Barrows were housed in stainless-steel metabolism cages (Pekas, 1968), equipped with feeders and compartments which allowed separated collection of feces and urine.

Ferric oxide (Fe2O3) was used to indicate the beginning and the end of fecal collection period. Feces were collected twice a day, placed into plastic bags and stored (-18 oC). Urine was collected continuously over the 5-day collection period into a plastic recipient, containing 20 mL of 1:1 chloridic acid (HCl), and a 5 % aliquot was placed into glass containers, identified and stored (3 oC).

Prior to laboratory analysis feces were thawed, mixed, dried (55 oC) and ground through a 1 mm screen. Dry matter (DM), nitrogen (N), ether extract (EE) and mineral matter (MM) were analysed in diets and feces, and N were determined in urine, as described by Silva and Queiroz (2002).

The coefficients of apparent digestibility of dry matter (DCDM), ether extract (DCEE), mineral matter (DCMM) and organic matter (DCOM) were determined according to Matterson et al. (1965). Nitrogen intake and total N excretion were determined to obtain the N balance.

Data was submitted to variance analysis through the statistical software SAEG-System for Statistical and Genetic Analyses, developed by the Federal University of Viçosa (UFV, 1999). Data was analyzed in a factorial scheme (probiotc x inulin), and were applied the regression procedures in case of significance.

 

Results and discussion

Significant interactions (inulin x probiotic) were not observed (p>0.05) for nutrient digestibility (table II). The probiotic studied did not affected (p>0.05) the nutrient digestibility, but inulin levels provided a quadratic effect (p<0.05) on the digestibility coefficients of dry matter, organic matter and ether extract, and the better responses were obtained supplementing 0.194, 0.185 and 0.188 % of inulin (figure 1), respectively, because above these levels the digestibility coefficients decreased, and Hedemann et al. (2001) reported that a decrease in the nutrient digestibility is not desired in piglet diets.

 

 

Such enhancements in nutrient digestibility were previously observed in piglet diets with low-lactose supplemented with inulin (Pierce et al., 2005). The decrease in digestibility coefficients, observed for the high inulin levels (figure 1), may be related to a reduction in the number of goblet cells in the jejunum, as observed in weanling pigs fed diets with 0.40 % inulin (Mair et al., 2010), and Pickler et al. (2012) reported that the glycoproteins produced by goblet cells participate in the nutrient absorption.

However, higher inulin levels could demonstrate good results, depending on the lactose level used in the experimental diets. Lynch et al. (2009) observed an increase in digestibility of dry matter, organic matter and mineral matter in piglet diets containing lactose (5.00 %) and inulin (1.50 %), but this response were not observed with high lactose level (23.00 %). On the other hand, Lynch et al. (2007) evaluating diets with low and high levels of crude protein, supplemented with 0.00 and 1.25 % inulin, did not observe any effects of inulin in the digestibility of dry matter and organic matter for finishing pigs.

Evaluating the inclusion of Enterococcus faecium and inulin (2.00 %) in piglet diets Böhmer et al. (2005) reported a positive effect of inulin, and inulin with E. faecium, compared to the control diet and containing just E. faecium.

For the nitrogen balance there were no significant (p>0.05) interactive effects of inulin and probiotic (table III). The nitrogen intake was similar for the evaluated treatments because experimental diets were isonitrogenous and animals were fed based on metabolic weight (BW0.75).

 

The probiotic used did not affect (p>0.05) the nitrogen balance variables, but a quadratic effect (p<0.01) was observed for the nitrogen excreted in feces (figure 2). According to Vanhoof and De Schrijver (1996), increased nitrogen excretion may be resulted from higher microbial activity in the large intestine and thus higher nitrogen incorporation in microbial protein excreted in feces. Hansen et al. (2010) observed higher bacterial activity in the upper colon in pigs fed a diet with 8.00 % inulin. In vitro studies to evaluate different indigestible carbohydrates, and bacterial isolates, demonstrated that inulin and starch increased bacterial nitrogen fixing, compa-red to cellulose, xylan and pectin (Bindelle et al., 2007a; 2007b).

 

In the current study, the increase in inulin levels, higher than 0.170 %, increased the nitrogen excreted in feces. This inulin level is lower than 1,25 % used by Lynch et al. (2007) which observed higher amounts of nitrogen in swine feces when the animals were supplemented with 1.25 % inulin in the diet. However the nitrogen excreted in urine was not affected by the inulin levels. In the same way, Halas et al. (2010a) observed an increase in fecal nitrogen, but the urine nitrogen decreased in weanling pigs that received 4.00 or 8.00 % of inulin in diets, being a desired effect for the environment, since it decreases the ammonia emission due to fecal nitrogen be consisted primarily by bacterial protein, which is less susceptible to decomposition than the urea present in the urine, because urea is easily converted into ammonia and carbon dioxide by bacterial urease (Mroz et al., 2000).

However, the levels of inulin used in these studies were higher than the ones used in the current research (0.00-0.50 %), and using a low-inulin level (0.40 %) in diets for growing pigs Loh et al. (2010) reported no effect on the nitrogen excretion, but the inulin tended to shift nitrogen excretion from urine to feces.

The inverse response obtained for nitrogen excreted in feces and nitrogen digestibility (figures 2 and 3) also was found by Lynch et al. (2007) using more than 1.25 % inulin in diets for finishing pigs. Nevertheless, Lynch et al. (2009) observed an increased nitrogen digestibility in piglets supplemented with 1.50 % inulin in a diet containing 5.00 % lactose. According to these authors, inulin may increase the population of lactic bacterias, like bifidobacteria. Their capacity to produce a wide variety of depolymerases and glycosidases, which acts over polysaccharides, may improve digestion. Even so, Vanhoof and De Schrijver (1996) and Halas et al. (2010b) did not report any differences on nitrogen digestibility after supplementing 6.00 and 8.00 % of inulin in piglet diets.

 

The results obtained for nitrogen excreted in feces, and urine, influenced the total nitrogen excretion (p<0.05), showing the better excretion at a level of 0.216 % inulin (figure 2). Although total nitrogen excretion was affected by the inulin and nitrogen intake remained constant, there was no difference in nitrogen retention (table III). This effect was also evidenced by a quadratic effect observed for nitrogen efficiency use (figure 3), which is the percentage of nitrogen retained, showing that the supplementation of 0.202 % inulin provided the better efficiency, that is proximate of 0.216 % found for total nitrogen excretion. Lynch et al. (2007) and Vanhoof and De Schrijver (1996) did not obtain significant response for the efficiency of nitrogen utilization according to inulin levels studied. Likewise, Mountzouris et al. (2006) evaluated two indigestible carbohydrates (oligofructose and transgalactoligosaccharides) as supplement in piglet and did not observe significant effects on the efficiency of nitrogen use.

 

Conclusions

The inulin levels of 0.194 and 0.216 %, in piglet diets, were the most effectives for dry matter digestibility and total nitrogen excretion, respectively.

 

References

1. Bindelle, J.; Buldgen, A.; Michaux, D.; Wavreille, J.; Destain, J.P. and Leterme, P. 2007a. Influence of purified dietary fibre on bacterial protein synthesis in the large intestine of pigs, as measured by the gas production technique. Livest Sci, 109: 232-235.         [ Links ]

2. Bindelle, J.; Buldgen, A.; Wavreille, J.; Agneessens, R.; Destain, J.P.; Wathelet, B. and Leterme, P. 2007b. The source of fermentable carbohydrates influences the in vitro protein synthesis by colonic bacteria isolated from pigs. Animal, 1: 1126-1133.         [ Links ]

3. Böhmer, B.M.; Branner, G.R. and Roth-Maier, D.A. 2005. Precaecal and faecal digestibility of inulin (DP 10-12) or an inulin/Enterococcus faecium mix and effects on nutrient digestibility and microbial gut flora. J Anim Physiol An N, 89: 388-396.         [ Links ]

4. Chiquieri, J.M.S.; Soares, R.T.R.N.; Souza, J.C.D.; Hurtado Nery, V.L.; Ferreira, R.A. y Ventura, B.G. 2006. Probiótico y prebiótico en la alimentación de cerdos en crecimiento y terminación. Arch Zootec, 55: 305-308.         [ Links ]

5. Delzenne, N.M. 2003. Oligosaccharides: state of the art. P Nutr Soc, 62: 177-182.         [ Links ]

6. Fuller, R. 1989. Probiotics in man and animals-A Review. J Appl Bacteriol, 66: 365-378.         [ Links ]

7. Gibson, G.R. and Roberfroid, M.B. 1995. Dietary modulation of the human colonic microbiota: introducing the concept of prebiotics. J Nutr, 125: 1401-1412.         [ Links ]

8. Halas, D.; Hansen, C.F.; Hampson, D.J.; Kim, J.C.; Mullan, B.P.; Wilson, R.H. and Pluske, J.R. 2010a. Effects of benzoic acid and inulin on ammonia-nitrogen excretion, plasma urea levels, and the pH in feces and urine of weaner pigs. Livest Sci, 134: 243-245.         [ Links ]

9. Halas, D.; Hansen, C.F.; Hampson, D.J.; Mullan, B.P.; Kim, J.C.; Wilson, R.H. and Pluske, J.R. 2010b. Dietary supplementation with benzoic acid improves apparent ileal digestibility of total nitrogen and increases villous height and caecal microbial diversity in weaner pigs. Anim Feed Sci Tech, 160: 137-147.         [ Links ]

10. Hansen, C.F.; Phillips, N.D.; La, T.; Hernandez, A.; Mansfield, J.; Kim, J.C.; Mullan, B.P.; Hampson, D.J. and Pluske, J.R. 2010. Diets containing inulin but not lupins help to prevent swine dysentery in experimentally challenged pigs. J Anim Sci, 88: 3327-3336.         [ Links ]

11. Hedemann, M.S.; Pedersen, A.R. and Engberg, R.M. 2001. Exocrine pancreatic secretion is stimulated in piglets fed fish oil compared with those fed coconut oil or lard. J Nutr, 131: 3222-3226.         [ Links ]

12. Kelly, G. 2008. Inulin-type prebiotics-A review: Part 1. Altern Med Rev, 13: 315-329.         [ Links ]

13. Loh, T.C.; Wang, W.S. and Foo, H.L. 2010. Effects of dietary protein and inulin on growth and nitrogen balance in growing pigs. J Appl Anim Res, 38: 55-59.         [ Links ]

14. Lynch, B.; Callan, J.J. and O'Doherty, J.V. 2009. The interaction between dietary crude protein and fermentable carbohydrate source on piglet post weaning performance, diet digestibility and selected faecal microbial populations and volatile fatty acid concentration. Livest Sci, 124: 93-100.         [ Links ]

15. Lynch, M.B.; Sweeney, T.; Callan, J.J.; Flynn, B. and O'Doherty, J.V. 2007. The effect of high and low dietary crude protein and inulin supplementation on nutrient digestibility, nitrogen excretion, intestinal microflora and manure ammonia emissions from finisher pigs. Animal, 8: 1112-1121.         [ Links ]

16. Mair, C.; Plitsner, C.; Pfaffl, M.W.; Schedle, K.; Meyer, H.H.D. and Windisch, W. 2010. Inulin and probiotics in newly weaned piglets: effects on intestinal morphology, mRNA expression levels of inflammatory marker genes and haematology. Arch Anim Nutr, 64: 304-321.         [ Links ]

17. Matterson, L.D.; Potter, L.M. and Stutz, M.W. 1965. The metabolizable energy of feed ingredient for chickens: research report. University of Connecticut. Storrs. Connecticut. 11 pp.         [ Links ]

18. Mountzouris, K.C.; Xypoleas, I.; Kouseris, I. and Fegeros, K. 2006. Nutrient digestibility, faecal physicochemical characteristics and bacterial glycolytic activity of growing pigs fed a diet supplemented with oligofructose or trans-galactooligosaccharides. Livest Sci, 105: 168-175.         [ Links ]

19. Mroz, Z.; Moeser, A.J.; Vreman, K.; Van Diepen, J.T.M.; Van Kempen, T.; Canh, T.T. and Jongbloed, A.W. 2000. Effects of dietary carbohydrates and buffering capacity on nutrient digestibility and manure characteristics in finishing pigs. J Anim Sci, 78: 3096-3106.         [ Links ]

20. Nahm, K.H. 2003. Influences of fermentable carbohydrates on shifting nitrogen excretion and reducing ammonia emission of pigs. Crit Rev Env Sci Tec, 30: 135-186.         [ Links ]

21. Pekas, J.C. 1968. Versatile swine laboratory apparatus for physiologic and metabolic studies. J Anim Sci, 27: 1303-1306.         [ Links ]

22. Pickler, L.; Hayashi, R.M.; Lourenço, M.C.; Miglino, L.B.; Caron, L.F.; Beirão, B.C.B.; Silva, A.V.F. e Santin, E. 2012. Avaliação microbiológica, histológica e imunológica de frangos de corte desafiados com Salmonella enteritidis e Minnesota e tratados com ácidos orgânicos. Pesquisa Vet Brasil, 32: 27-36.         [ Links ]

23. Pierce, K.M.; Callan, J.J.; McCarthy, P. and O'Doherty, J.V. 2005. Performance of weanling pigs offered low or high lactose diets supplemented with avilamycin or inulin. Anim Sci, 80: 313-318.         [ Links ]

24. Roberfroid, M. 1993. Dietary fibre, inulin and oligofructose: a review comparing their physiological effects. Crit Rev Food Sci, 33: 103-148.         [ Links ]

25. Rostagno, H.S.; Albino, L.F.T.; Donzele, J.L.; Gomes, P.C.; Oliveira, R.F. de; Lopes, D.C.; Ferreira, A.S. e Barreto, S.L.T. 2005. Composição de alimentos e exigências nutricionais. Tabelas brasileiras para aves e suínos. 2a ed. Editora UFV. Viçosa. 186 pp.         [ Links ]

26. Shim, S.B.; Verstegen, M.W.A.; Kim, I.H.; Kwon, O.S. and Verdonk, J.M.A.J. 2005. Effects of feeding antibiotic-free creep feed supplemented with oligofructose, probiotics or synbiotics to suckling piglets increases the preweaning weight gain and composition of intestinal microbiota. Arch Anim Nutr, 59: 419-427.         [ Links ]

27. Silva, D.J. and Queiroz, A.C. 2002. Análise de alimentos: métodos químicos e biológicos. 3a ed. Editora UFV. Viçosa. 235 pp.         [ Links ]

28. UFV. 1999. Universidade Federal de Viçosa. Manual de utilização do programa SAEG (Sistema para análises estatísticas e genéticas). Editora UFV. Viçosa. 59 pp.         [ Links ]

29. Vanhoof, K. and De Schrijver, R. 1996. Nitrogen metabolism in rats and pigs fed inulin. Nutr Res, 16: 1035-1039.         [ Links ]

30. Zentek, J.; Marquart, B.; Pietrzak, T.; Ballevre, O. and Rochat, F. 2003. Dietary effects on Bifidobacteria and Clostridium perfringens in the canine intestinal tract. J Anim Physiol An N, 87: 397-407.         [ Links ]

31. Zervas, S. and Zijlstra, R.T. 2002. Effects of dietary protein and fermentable fiber on nitrogen excretion patterns and plasma urea in grower pigs. J Anim Sci, 80: 3247-3256.         [ Links ]

 

 

Recibido: 11-4-12.
Aceptado: 31-10-12.

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