Carcass traits and short-chain fatty acid profile in cecal digesta of piglets fed alfalfa hay and fructooligosaccharides

Rodrigues, Daniela Junqueira; Budiño, Fábio Enrique Lemos; Prezzi, Joel Alberto; Monferdini, Renato Pacheco; Otsuk, Ivani Pozar; Moraes, José Evandro de

doi:10.1590/S1806-92902017000400009

ABSTRACT

The objective of this study was to evaluate the effects of the addition of the prebiotic fructooligosaccharide and/or alfalfa hay to piglet diets on carcass traits and short-chain fatty acid profiles in the cecal digesta. Seventy-two commercial crossbred piglets of both sexes, with an average initial weight about 6 kg and age of approximately 21 days, were distributed in a randomized block design, using a factorial scheme, which consisted of three alfalfa hay levels (0, 5, and 10%) and two fructooligosaccharide levels (0 and 0.3%). Fiber addition in the presence of the prebiotic exerted an effect on cecal digesta short-chain fatty acid, increasing the acetic and reducing the butyric acid concentrations. The meat quality was also affected by the treatments, water activity, water-holding capacity of meat, and especially the reduction of fat content and the increase of moisture. The treatments did not affect the pH and the ammonia content in the cecal digesta. Most carcass traits were not affected by the treatments, except for carcass weight and backfat thickness in points 1 and 2, that decreased with the inclusions of fiber and prebiotic. The addition of 5% alfalfa hay improves carcass and meat traits in growing pigs without any change in carcass weight, demonstrating the advantage of using this ingredient to obtain a healthy final product to the customers.

Key Words:
backfat thickness; fiber; meat quality; prebiotic; swine

Introduction

Pork is the most important source of high-quality animal protein worldwide. Several nutritional strategies have been studied in an attempt to meet production requirements and to improve quality, such as a reduction in carcass fat. This can be achieved by including fibers to the animal diet, which reduce the energy consumed and provide benefits in carcass quality, characteristics sought by slaughterhouses and consumers.

The most challenging phase is the weaning of piglets because of the stress caused by the separation from the mother and the change in diet from liquid to solid. Consequently, these animals often suffer from diarrhea, causing problems in the development, or even death. In an attempt to reduce these losses, traditional growth promoters, such as antibiotics and chemotherapeutic agents, are added to the diet to improve animal performance due to their positive action on the microorganisms of the intestinal flora (Stefe et al., 2008Stefe, C. A.; Alves, M. A. R. and Ribeiro, R. L. 2008. Probióticos, prebióticos e simbióticos: Artigo de revisão. Saúde e Ambiente em Revista 3:16-33.). The use of antibiotics, as growth promoters in livestock, have been prohibited in Europe since 2006; therefore, additives such as prebiotics and probiotics are being studied as alternatives to the antimicrobial growth promoter. In general, studies have reported three different responses to the use of prebiotics: beneficial modulation of the host microbiota, a possible enhancer effect on the immune system and on certain anatomical aspects of the digestive system, and a consequent influence on animal performance (Budiño et al., 2010Budiño, F. E. L.; Castro, F. G. and Otsuk, I. P. 2010. Adição de frutoligossacarídeo em dietas para leitões desmamados: desempenho, incidência de diarreia e metabolismo. Revista Brasileira de Zootecnia 39:2187-2193.).

In pigs, only a small part of the components of dietary fibers is digested in the small intestine, providing the substrate for microbial fermentation in the large intestine. The main products of this fermentation are the short-chain fatty acids (SCFA): propionate, butyrate, and acetate. The calorie contribution of these SCFA in pigs has been estimated at 5 to 28% of maintenance energy requirements, depending on the frequency of feed intake and the dietary fiber level (NRC, 2012NRC - National Research Council. 2012. Nutrient requirement of swine. 11th ed. National Academic Science, Washington, DC.). These SCFA cause a reduction in intestinal pH, which is related to the growth inhibition of pathogenic bacteria and provides better conditions for the growth of probiotic microorganisms (McDonald et al., 2006McDonald, P.; Edwards, R. A. and Greenhalgh, J. F. D. 2006. Nutrición animal. 6.ed. Acribia, Zaragoza.). Thus, the inclusion of fiber-rich feeds combined with a prebiotic can improve the use of this material by the swine digestive system, as well as contribute to the improvement of meat quality by reducing the fat content.

The objective of this study was to evaluate the effects of the separate or combined administration of alfalfa hay fiber and fructooligosaccharide (FOS) on carcass characteristics, meat quality, and the SCFA profile, pH, and NH₃ of the cecal content.

Material and Methods

The present study was approved by the animal welfare committee in São Paulo, SP, Brazil. The facilities were two identical rooms with 18 elevated cages in each one. All cages were provided with a feeder and a nipple drinker; half of the cage floor was half solid and half slatted plastic; and the temperature was controlled using air conditioner, when necessary.

Seventy-two piglets with a mean age of 21 days and an average initial body weight of 5.95±0.75 kg were divided into six treatments and six replications of two animals (one male and one female) per experimental unit. The pelletized alfalfa hay and/or the prebiotic FOS (Fortifeed^® - Corn Products Brazil) were mixed with the other ingredients in a feed mill according to the treatments. The animals were subjected to the following treatments: a control diet without FOS; a control diet + 0.3% FOS; a diet containing 5% alfalfa without FOS; a diet containing 5% alfalfa + 0.3% FOS; a diet containing 10% alfalfa without FOS; a diet containing 10% alfalfa + 0.3% FOS. The alfalfa hay inclusion was calculated to increase the neutral detergent fiber content, in a considered not prejudicial ammount to the intake of piglets because their gastrointestinal tract are not totally developed. The FOS inclusion was according to the manufacturer's recommendation. The experimental diets, divided into three phases, according to the age of the animals, were formulated in such a way as to meet the minimal nutritional requirements of animals proposed by the NRC (2012)NRC - National Research Council. 2012. Nutrient requirement of swine. 11th ed. National Academic Science, Washington, DC.. These formulations were based on the nutritional composition of feeds reported by Rostagno et al. (2011)Rostagno, H. S.; Albino, L. F. T.; Donzele, J. L.; Gomes, P. C.; Oliveira, R. F.; Lopes, D. C.; Ferreira, A. S.; Barreto, S. L. T. and Euclides, R. F. 2011. Tabelas brasileiras para aves e suínos - Composição de alimentos e exigências nutricionais. Editora UFV, Viçosa, MG., with the usual ingredients that compose a piglet diet, such as corn, soybean meal, sugar (palatability), and soybean oil (Table 1: 21 to 28 days of age; Table 2: 29 to 42 days of age; and Table 3: 43 days to 59 days of age).

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Table 1
Percent composition and nutrient content of the diets (control, 5% alfalfa, and 10% alfalfa) offered to piglets during the pre-initial phase (21 to 28 days of age)

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Table 2
Percent composition and nutrient content of the diets (control, 5% alfalfa, and 10% alfalfa) offered to piglets during initial phase 1 (29 to 42 days of age)

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Table 3
Percent composition and nutrient content of the diets (control, 5% alfalfa, and 10% alfalfa) offered to piglets during initial phase 2 (from 43 days of age)

When the animals were 59 days of age, one piglet (a female) of each experimental unit was slaughtered in accordance with the norms of the technical regulations of stunning methods for slaughter (Ministério da Agricultura, 2000Ministério da Agricultura. 2000. Instrução Normativa n° 3, de 07 de janeiro de 2000. Regulamento técnico de métodos de insensibilização para o abate humanitário de animais de açougue. S.D.A./M.A.A. Diário Oficial da União, Brasília, DF, 24 jan. 2000. Seção I, p.14-16.), using an electrical shock.

Cecal digesta samples were collected for the measurement of pH, the quantification of N-NH₃ content, and the analysis of SCFA profile. The pH was measured during sample collection with a portable pH-meter Lutron 221. The N-NH₃ content was measured in accordance with Fenner's methodology (Fenner, 1965Fenner, H. 1965. Method for determining total volatile bases in rumen fluid by steam distillation. Journal of Dairy Science 48:249-251.). The SCFA concentration was determined by gas chromatography (Erwin et al., 1961Erwin, E. S.; Marco, G. J. and Emery, E. M. 1961. Volatile fatty acid analyses of blood and rumen fluid by gas chromatography. Journal Dairy Science 44:1768-1771.).

The following analyses were performed for the evaluation of carcass traits: carcass weight; hot carcass weight after the removal of viscera; carcass length measured with a metal tape from the first rib to the ischiopubic symphysis, according to the Brazilian method of carcass evaluation (ABCS, 1973ABCS - Associação Brasileira de Criadores de Suínos. 1973. Método brasileiro de classificação de carcaça. Estrela. 17p. (Publicação Técnica, 2).); and organ weight of the digestive system, as described by Jorgensen et al. (1996)Jorgensen, H.; Zhao, X. and Eggum, B. O. 1996. The influence of dietary fiber and environmental temperature on the development of the gastrointestinal tract, digestibility, degree of fermentation in the hind-gut and energy metabolism in pigs. British Journal of Nutrition 75:365-378.. These assessments were done on the day of slaughter. Cooling of the left half-carcasses was necessary for other procedures. Therefore, these carcasses were stored at 0 to 2 °C for 20 h for the evaluation of backfat thickness and loin eye area. Backfat thickness was measured at three different sites according to the USDA (1994)USDA - United State Department of Agriculture. 1994. National Engineering Handbook. Agricultural Waste Management Field Handbook. United State Department of Agriculture, Washington, DC.: backfat thickness 1 was measured at the first thoracic vertebra, backfat thickness 2 was measured at the last thoracic vertebra, and backfat thickness 3 was measured at the last lumbar vertebra. The loin eye area was defined using the method described by ABCS (1973)ABCS - Associação Brasileira de Criadores de Suínos. 1973. Método brasileiro de classificação de carcaça. Estrela. 17p. (Publicação Técnica, 2)..

The longissimus dorsi muscle was cut for the following physical and chemical analyses of the fresh meat: pH, determined 24 h after slaughter with a DM-2 Digimed^© pH meter; moisture content, determined as described Horwitz (2005)Horwitz, W. 2005. Guidelines for collaborative study procedures to validate characteristics of a method of analysis. Appendix D, AOAC Official methods of analysis. 18th ed. AOAC International, Geneva, Switzerland. p.1-12.; water activity, determined with an Aqualab CX-2 apparatus (Decagon Devices, Inc., Operators Manual version 3.0); fat percentage (total fat), determined as described by Horwitz (2005)Horwitz, W. 2005. Guidelines for collaborative study procedures to validate characteristics of a method of analysis. Appendix D, AOAC Official methods of analysis. 18th ed. AOAC International, Geneva, Switzerland. p.1-12.; water-holding capacity, determined as described by Hofmann et al. (1982)Hofmann, K.; Hamm, R. and Luchel, E. 1982. New information on the determination of water binding in meat by the filter paper press method. Fleischwirtsch 62:87-94..

A randomized block design was used to control initial differences in weight, which consisted of six treatments and six replications in a 3 × 2 factorial scheme (three levels of alfalfa hay and two levels of FOS). The experimental unit consisted of two animals (male and female). Analysis of variance was performed using the GLM procedure of the SAS software (Statistical Analysis System, version 9.0), considering the significant level at 5% (F test) (P<0.05). Two different contrast analyses were performed due to the interactions between treatments. Contrast 1 compared the diets without alfalfa hay with the remaining diets and contrast 2 compared the diets containing 5% alfalfa hay with the diets containing 10% alfalfa hay.

Results and Discussion

The data presented in this study are associated with the performance results of animals published in Budiño et al. (2015)Budiño, F. E. L.; Prezzi, J. A.; Rodrigues, D. J.; Monferdini, R. P. and Otsuk, I. P. 2015. Desempenho e digestibilidade de leitões alimentados com rações contendo feno de alfafa e frutoligossacarídeo na fase inicial. Revista Brasileira de Saúde e Produção Animal 16:796-810., in which no effect on performance parameters were obtained with the treatment diets.

No difference (P>0.05) in the molar percentage (mmol/L) of the SCFA studied was observed between the groups without FOS (Table 4). An increase (P<0.05) in the molar percentage of acetate was observed in piglets fed diet containing 0.3% FOS plus alfalfa hay when compared with the control group (0% alfalfa, 0% FOS). In contrast, there was a decrease (P<0.05) in the molar percentage of butyrate in animals fed diets containing 5 or 10% alfalfa hay compared with the control group. However, no difference (P>0.05) in the molar percentage of propionate was observed among the studied treatments.

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Table 4
Cecal digesta characteristics of piglets fed three levels of alfalfa hay (0%, 5%, and 10%) and two levels of fructooligosaccharide (0% and 0.3%)

One of the best known effects of prebiotics is the increase of SCFA production in the large intestine, which contributes to decline the pH and, consequently, reduces the capacity of pathogens to colonize the intestine (Gomes et al., 2011Gomes, M. O. S.; Beraldo, M. C.; Putarov, T. C.; Brunetto, M. A.; Zaine, L.; Glória, M. B. and Carciofi, A. C. 2011. Old beagle dogs have lower faecal concentrations of some fermentation products and lower peripheral lymphocyte counts than young adult beagles. British Journal of Nutrition 106:187-190.). The increase in the molar percentage of acetate is probably due to the higher amount of dietary fiber, whose main fermentation product is acetate. Martins et al. (2010)Martins, C.; Pinho, M.; Lordelo, M. M.; Cunha, L. F.; Carvalho, J. and Freire, J. P. B. 2010. Effect of brewers grain on intestinal microbial activity and mucosa morphology of weaned piglets. Livestock Science 133:132-134. studied the effects of barley bagasse and wheat flour in piglets and concluded that the increased fiber contents, except for barley bagasse, resulted in an increase in SCFA produced in the cecum. Freire et al. (2000)Freire, J. P. B.; Guerreiro, A. J. G; Cunha, L. F. and Aumaitre, A. 2000. Effect of dietary fiber source on total tract digestibility, caecum volatile fatty acids and digestive transit time in the weaned piglet. Animal Feed Science and Technology 87:71-83., evaluating different fiber sources (wheat bran, beet pulp, soybean hull, and alfalfa meal) in piglet diets, found no significant difference in the production of propionate, as was observed in the present study.

The addition of fiber sources to piglet diets has been shown to influence the fermented end-products in the large intestine. Furthermore, the types of fiber contained in the different sources directly affects the fatty acid profile. However, a change in this profile only occurs if the amount of substrate is efficient in modifying or increasing the intestinal microbiota (Solà-Oriol et al., 2011Solà-Oriol, D.; Roura, E. and Torrallardona, D. 2011. Feed preference in pigs: Effect of selected protein, fat, and fiber sources at different inclusion rates. Journal of Animal Science 89:3219-3227.). In addition, the presence of a prebiotic can positively affect the colonization of fermentative bacteria and also influence the production of SCFA (Gomes et al., 2011Gomes, M. O. S.; Beraldo, M. C.; Putarov, T. C.; Brunetto, M. A.; Zaine, L.; Glória, M. B. and Carciofi, A. C. 2011. Old beagle dogs have lower faecal concentrations of some fermentation products and lower peripheral lymphocyte counts than young adult beagles. British Journal of Nutrition 106:187-190.).

According to Montagne et al. (2010)Montagne, L.; Arturo-Schaan, M.; Le Floc'h, N.; Guerra, L. and Le Gall, M. 2010. Effect of sanitary conditions and dietary fibre on the adaptation of gut microbiota after weaning. Livestock Science 133:113-116., the addition of prebiotics and fiber sources to piglet diets exerts a direct effect on the intestinal microbiota, consequently altering the production of SCFA. A higher production of these acids promotes a reduction in pH, which in turn inhibits the development of populations of harmful, acid-sensitive bacteria, such as Escherichia coli, Clostridium sp., and Salmonella sp.. In addition, a reduction in intestinal pH improves the activity of digestive enzymes; however, no difference in pH cecal digesta samples was observed in the present study (P>0.05) (Table 4).

The results can vary depending on the type and quantity of added fiber, as well as the percentage of the prebiotic. A lack of a significant difference in cecal digesta pH has also been reported by Martins et al. (2010)Martins, C.; Pinho, M.; Lordelo, M. M.; Cunha, L. F.; Carvalho, J. and Freire, J. P. B. 2010. Effect of brewers grain on intestinal microbial activity and mucosa morphology of weaned piglets. Livestock Science 133:132-134., who studied the effects of different fiber sources (wheat flour, unwashed, and washed barley bagasse) in piglet diets, and Pascoal et al. (2012)Pascoal, L. A. F.; Thomas, M. C.; Watanabe, P. H.; Ruiz, U. S.; Ezequiel, J. M. B.; Amorim, A. B.; Daniel, E. and Masson, G. C. I. H. 2012. Fiber sources in diets for newly weaned piglets. Revista Brasileira de Zootecnia 41:636-642., who evaluated the addition of pure cellulose, soybean hull, and citrus pulp to piglet diets.

No difference (P>0.05) in the N-NH₃ was observed among the treatments (Table 4), which indirectly suggests that the fiber fermentation level was the same in all treatments. The physical properties of dietary fiber (water-holding capacity, viscosity, and solubility) influence ammonia levels, since the latter is the main source of nitrogen for microorganisms, and they decrease proteolytic fermentations, reducing the loss of nitrogen on farms (Jeaurond et al., 2008Jeaurond, E. A.; Rademacher, M.; Pluske, J. R.; Zhu, C. H. and de Lange, C. F. M. 2008. Impact of feeding fermentable proteins and carbohydrates on growth performance, gut health and gastrointestinal function of newly weaned pigs. Canadian Journal of Animal Science 88:271-281.). The present study agrees with the results reported by Freire et al. (2003)Freire, J. P. B.; Dias, R. I. M; Cunha, L. F. and Aumaitre, A. 2003. The effect of genotype and dietary fiber level on the caecal bacterial enzyme activity of young piglets: digestive consequences. Animal Feed Science and Technology 106:119-130., who tested piglet diets, in which wheat was replaced by wheat bran. These authors concluded that the N-NH₃ concentration was not significantly affected by the level of dietary fiber. Possenti et al. (2008)Possenti, R. A.; Franzolin, R.; Schammas, E. A.; Demarchi, J. J. A. A.; Frighetto, R. T. S. and Lima, M. A. 2008. Efeitos de dietas contendo Leucaena leucocephala e Saccharomyces cerevisae sobre a fermentação ruminal e a emissão de gás metano em bovinos. Revista Brasileira de Zootecnia 37:1509-1516. also found no significant differences in the ruminal N-NH₃ concentration between cattle diets containing different levels of Leucaena in the presence or absence of yeast.

No difference (P>0.05) in carcass weight was observed among the groups of piglets fed diets without the FOS (Table 5). In contrast, in piglets fed diets containing 0.3% FOS, the contrasts demonstrated a reduction (P<0.05) in carcass weight for the diet containing 10% alfalfa compared with the diet containing 5%.

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Table 5
Carcass and organ weight yield of piglets fed three levels of alfalfa hay (0%, 5%, and 10%) and two levels of fructooligosaccharide (0% and 0.3%)

Rekiel et al. (2005)Rekiel, A.; Wiecek, J. and Dziuba, M. 2005. Effect of feed additives on the results of fattening and selected slaughter and quality traits of pork meat of pigs with different genotypes. Czech Journal of Animal Science 50:561-567. observed no differences in carcass parameters of pigs that received diets containing mannanoligosaccharides (MOS) and antibiotics. Bellé et al. (2009)Bellé, J. C.; Silva, C. A.; Bridi, A. M. and Pacheco, G. D. 2009. Avaliação de prebióticos como promotor de crescimento para suínos nas fases de recria e terminação. Semina: Ciências Agrárias 30:471-480. studied the addition of 0.2% prebiotics (0.1% MOS + 0.1% FOS) to pig diets and also observed no significant differences in carcass weight when compared with pigs fed control diet (no addition of prebiotics). Gomes et al. (2006)Gomes, J. D. F.; Fukushima, R. S.; Putrino, S. M.; Grossklaus, C. and Lima, G. J. M. M. 2006. Efeitos do incremento da fibra em detergente neutro na dieta de suínos sobre a morfologia dos órgãos digestivos e não digestivos. Brazilian Journal Veterinary Research and Animal Science 43:202-209. investigated the effect of the addition of 8% neutral detergent fiber (NDF; Tifton hay) to pig diets and found no significant differences in carcass traits.

An analysis of liver + gallbladder weight showed a higher mean weight (P<0.05) in the treatments with 0.3% FOS compared with those treatments without the prebiotic (Table 5). According to Martinez-Ramirez et al. (2008)Martinez-Ramirez, H. R.; Jeaurond, E. A. and de Lange, C. F. M. 2008. Dynamics of body protein deposition and changes in body composition after sudden changes in amino acid intake: I. Barrows. Journal of Animal Science 86:2156-2167., organ weight varies according to energy and/or protein intake, suggesting that, if the same quantities of these components are maintained, the organ weights should be similar. In the present study, the diets were formulated to be isonitrogenous and isoenergetic; however, in the performance experiment carried out together with this analysis, a higher feed intake (P<0.05) was observed in animals receiving the diet with FOS (Budiño et al., 2015Budiño, F. E. L.; Prezzi, J. A.; Rodrigues, D. J.; Monferdini, R. P. and Otsuk, I. P. 2015. Desempenho e digestibilidade de leitões alimentados com rações contendo feno de alfafa e frutoligossacarídeo na fase inicial. Revista Brasileira de Saúde e Produção Animal 16:796-810.). This higher feed intake increases nutrient intake, which may explain the increase in liver + gallbladder weight (P<0.05).

An increase in empty stomach weight (P<0.05) was observed in animals fed 0.3% FOS compared with those that were fed diet without FOS (Table 5). Gomes et al. (2006)Gomes, J. D. F.; Fukushima, R. S.; Putrino, S. M.; Grossklaus, C. and Lima, G. J. M. M. 2006. Efeitos do incremento da fibra em detergente neutro na dieta de suínos sobre a morfologia dos órgãos digestivos e não digestivos. Brazilian Journal Veterinary Research and Animal Science 43:202-209. studied the addition of 8% NDF to nursery pig diets and observed an increase in stomach weight (percentage of live weight). In the study by Pond et al. (1988)Pond, W. G.; Jung, H. G. and Varel, V. H. 1988. Effect of dietary fiber on young adult genetically lean, obese and contemporary pigs: body weight, carcass measurements, organ weight and digesta content. Journal of Animal Science 66:699-706., the relative weight of the empty stomach increased when a high-fiber diet was offered (43% NDF obtained by the addition of 80% alfalfa meal). According to Serena et al. (2008)Serena, A.; Hedemann, M. S. and Bach Knudsen, K. E. 2008. Influence of dietary fiber on luminal environment and morphology in the small and large intestine of sows. Journal of Animal Science 86:2217-2227., this data suggests partial morphological adaptations of the organs to the dietary fiber component.

There was no difference (P>0.05) in intestine mass among the treatments, indicating that the addition of dietary fiber or FOS did not affect the weight of this organ (Table 5). Gomes et al. (2006)Gomes, J. D. F.; Fukushima, R. S.; Putrino, S. M.; Grossklaus, C. and Lima, G. J. M. M. 2006. Efeitos do incremento da fibra em detergente neutro na dieta de suínos sobre a morfologia dos órgãos digestivos e não digestivos. Brazilian Journal Veterinary Research and Animal Science 43:202-209., evaluating the addition of 8% NDF to nursery pig diets, observed an increase in the mass of the large intestine and filled cecum. In addition, animals receiving the high-NDF diet presented a higher gut weight at the end of the finisher phase. In addition to the increase in gut weight, Pekas et al. (1983)Pekas, J. C.; Yen, J. T. and Pond, W. G. 1983. Gastrointestinal carcass and performance traits of obese versus lean genotype swine: effect of dietary fiber. Nutrition Reports International 27:259-270. also found a higher weight of the small intestine and colon in finishing pigs fed 50% alfalfa hay. In a subsequent study, Pond et al. (1988)Pond, W. G.; Jung, H. G. and Varel, V. H. 1988. Effect of dietary fiber on young adult genetically lean, obese and contemporary pigs: body weight, carcass measurements, organ weight and digesta content. Journal of Animal Science 66:699-706. showed that the relative mass of the small and large intestines increased when the animals were fed a high-fiber diet (43% NDF obtained by the addition of 80% alfalfa meal).

An increase in carcass yield (P<0.05) was observed in groups receiving diets without FOS and with 5 and 10% alfalfa when compared with the group receiving the control treatment (Table 5). These results could be related to the increase of fiber level that would increase the intake, but not the fat deposition. Similar results were reported by Pekas et al. (1983)Pekas, J. C.; Yen, J. T. and Pond, W. G. 1983. Gastrointestinal carcass and performance traits of obese versus lean genotype swine: effect of dietary fiber. Nutrition Reports International 27:259-270., who fed finishing pigs 50% alfalfa hay, and by Pond et al. (1988)Pond, W. G.; Jung, H. G. and Varel, V. H. 1988. Effect of dietary fiber on young adult genetically lean, obese and contemporary pigs: body weight, carcass measurements, organ weight and digesta content. Journal of Animal Science 66:699-706., who studied the use of high-fiber diets (43% NDF by the addition of 80% alfalfa meal). The authors observed a reduction in the hot carcass yield of pigs during the grower and finisher phases. In contrast, Gomes et al. (2008)Gomes, J. D. F.; Putrino, S. M.; Martelli, M. R.; Sobral, P. J. A. and Fukushima, R. S. 2008. Desempenho e características de carcaça de suínos alimentados com dieta com feno de tifton (Cynodon dactylon). Ciência Animal Brasileira 9:59-67. found no effect of the increase in dietary NDF on hot carcass yield. Bellé et al. (2009)Bellé, J. C.; Silva, C. A.; Bridi, A. M. and Pacheco, G. D. 2009. Avaliação de prebióticos como promotor de crescimento para suínos nas fases de recria e terminação. Semina: Ciências Agrárias 30:471-480., evaluating the addition of 0.2% prebiotics (0.1% MOS + 0.1% FOS) to pig diets, observed no difference (P>0.05) in carcass yield when compared with the control diet.

No difference (P>0.05) in carcass length was observed among the studied treatments (Table 6). Backfat thickness, at the three sites studied, was not affected (P>0.05) by the addition of FOS (Table 6). A reduction (P<0.05) in backfat thickness 1, measured at the first thoracic vertebra, was observed in the groups receiving the diets without FOS but with 5 and 10% alfalfa, when compared with group receiving the control treatment. Mean backfat thickness 2, measured at the last thoracic vertebra, was reduced (P<0.05) in the treatments with alfalfa compared with the treatments without this fibrous ingredient. No difference (P>0.05) in backfat thickness 3, measured at the last lumbar vertebra, was observed among the studied treatments (Table 6).

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Table 6
Carcass characteristics of piglets fed three levels of alfalfa hay (0%, 5%, and 10%) and two levels of fructooligosaccharide (0% and 0.3%)

An analysis of loin eye area showed no difference (P>0.05) among the studied treatments (Table 6). The reduction in backfat thickness and body fat and the increase in muscle mass production resulted in improved carcass quality, although they are generally associated with lower body weight gain of pigs fed fibrous diets. Therefore, if muscle percentage in the carcass increases and subcutaneous fat decreases with increasing levels of dietary fiber, these changes in carcass composition would represent indirect effects of the low carcass weight of pigs fed dietary fiber since the amount of lean meat of these carcasses generally increases with decreasing carcass weight (Jha and Berrocoso, 2015Jha, R. and Berrocoso, J. D. 2015. Review: dietary fiber utilization and its effects on physiological functions and gut health of swine. Animal 9:1441-1452.).

Varel et al. (1984)Varel, V. H.; Pond, W. G. and Yen, J. T. 1984. Influence of dietary fiber on the performance and cellulose activity of growing-finishing swine. Journal of Animal Science 59:388-393., studying growing pigs fed 35% alfalfa meal, observed depressive effects on carcass traits, including lower carcass weight, lower loin eye area, and lower backfat thickness. Bellé et al. (2009)Bellé, J. C.; Silva, C. A.; Bridi, A. M. and Pacheco, G. D. 2009. Avaliação de prebióticos como promotor de crescimento para suínos nas fases de recria e terminação. Semina: Ciências Agrárias 30:471-480., testing the addition of 0.2% prebiotics (0.1% MOS + 0.1% FOS) to pig diets, found no difference in backfat thickness when compared with pigs fed the control diet. The results presented here are according with these authors and it can suggest that the fibers and energy levels are the most important factor when evaluating the carcass traits.

The discordance between the results obtained might be due to factors such as differences in the animal genetics, level, composition and processing of dietary fiber, presence of antinutritional factors, environmental effects, age of the animals, and/or differences among the animal groups studied (Jha and Berrocoso, 2015Jha, R. and Berrocoso, J. D. 2015. Review: dietary fiber utilization and its effects on physiological functions and gut health of swine. Animal 9:1441-1452.). The addition of fiber to the diet of pigs destined to slaughter permits better control of carcass standards by adjusting body weight gain to lean meat yield, an approach that guarantees a higher yield of lean meat due to lower subcutaneous fat content (Gomes et al., 2008Gomes, J. D. F.; Putrino, S. M.; Martelli, M. R.; Sobral, P. J. A. and Fukushima, R. S. 2008. Desempenho e características de carcaça de suínos alimentados com dieta com feno de tifton (Cynodon dactylon). Ciência Animal Brasileira 9:59-67.).

An increase (P<0.05) in the moisture content of meat was observed in piglets fed diets containing 0.3% FOS when compared with the control group and a decrease (P<0.05) in fat content in meat were observed in piglets fed diets containing 0.3% FOS and 5 or 10% alfalfa when compared with the control group (Table 7).

Thumbnail

Table 7
Meat traits of the longissimus dorsi muscle of piglets fed three levels of alfalfa hay (0%, 5%, and 10%) and two levels of fructooligosaccharide (0% and 0.3%)

There was no difference (P>0.05) in meat pH among the studied treatments (Table 7). The pH in live muscles of pigs ranges from 7.0 to 7.2. Muscle pH declines during the conversion from muscle to meat and the final pH is important for the determination of pork quality. According to Boler et al. (2011)Boler, D. D.; Holmer, S. F.; Duncan, D. A.; Carr, S. N.; Ritter, M. J.; Stites, C. R.; Petry, D. B.; Hinson, R. B.; Allee, G. L.; McKeith, F. K. and Killefer, J. 2011. Fresh meat and further processing characteristics of ham muscles from finishing pigs fed ractopamine hydrochloride. Journal of Animal Science 89:210-220., under normal conditions, the pH of pork decreases to values of 5.3 to 5.7 within a period of 24 h after slaughter, a fact also observed in the present study.

No difference (P>0.05) in water activity was observed for piglets fed diet without FOS (Table 7). In contrast, for the diets containing 0.3% FOS, an increase (P<0.05) in water activity was found for animals fed 10% alfalfa compared with those receiving 5% alfalfa.

Water activity indicates the strength of forces that bind water to other non-water components and, consequently, the amount of water available for the growth of microorganisms and for different chemical and biochemical reactions (Ordónez, 2005Ordónez, J. A. 2005. Tecnologia de alimentos. Componentes dos alimentos e processos. v.1. Artmed, Porto Alegre.). The values found in the present study agree with Silliker (1980)Silliker, J. H. 1980. Microorganisms in foods. 3. Microbial ecology of foods. Academic Press, New York., who defines fresh meat as a high-moisture food, with water activity of 0.98 or higher, allowing the growth of pathogenic bacteria and microorganisms that cause food spoilage.

A reduction (P<0.05) in the water-holding capacity of meat was observed in piglets fed diets containing 0.3% FOS and alfalfa compared with the control group (Table 7).

The water-holding capacity is defined as the ability of meat to retain water during the application of some external force (cutting, heating, grinding, or pressing) and is influenced by different factors such as pH variation. In this respect, the formation of lactic acid and the consequent post-mortem pH decline reduce the water-holding capacity of meat. This trait affects the appearance and weight loss of the meat before cooking, the behavior of meat during cooking, and juiciness during mastication. A reduced water-holding capacity, therefore, compromises meat quality (Araújo, 1995Araújo, M. A. 1995. Química de alimentos: teoria e prática. Imprensa Universitária, Viçosa, MG.).

Conclusions

The addition of 5% alfalfa hay allows improvement in some carcass and meat traits in growing pigs without any change in carcass weight, comparing the result with the diets without and with 10% alfalfa hay. These findings demonstrate the advantage of using this fibrous feed ingredient, providing a better final product to the customers that are more worried about buying healthy products.

Acknowledgments

The authors thank Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) for the financial support (09/06281-6).

References

Araújo, M. A. 1995. Química de alimentos: teoria e prática. Imprensa Universitária, Viçosa, MG.
ABCS - Associação Brasileira de Criadores de Suínos. 1973. Método brasileiro de classificação de carcaça. Estrela. 17p. (Publicação Técnica, 2).
Bellé, J. C.; Silva, C. A.; Bridi, A. M. and Pacheco, G. D. 2009. Avaliação de prebióticos como promotor de crescimento para suínos nas fases de recria e terminação. Semina: Ciências Agrárias 30:471-480.
Boler, D. D.; Holmer, S. F.; Duncan, D. A.; Carr, S. N.; Ritter, M. J.; Stites, C. R.; Petry, D. B.; Hinson, R. B.; Allee, G. L.; McKeith, F. K. and Killefer, J. 2011. Fresh meat and further processing characteristics of ham muscles from finishing pigs fed ractopamine hydrochloride. Journal of Animal Science 89:210-220.
Budiño, F. E. L.; Castro, F. G. and Otsuk, I. P. 2010. Adição de frutoligossacarídeo em dietas para leitões desmamados: desempenho, incidência de diarreia e metabolismo. Revista Brasileira de Zootecnia 39:2187-2193.
Budiño, F. E. L.; Prezzi, J. A.; Rodrigues, D. J.; Monferdini, R. P. and Otsuk, I. P. 2015. Desempenho e digestibilidade de leitões alimentados com rações contendo feno de alfafa e frutoligossacarídeo na fase inicial. Revista Brasileira de Saúde e Produção Animal 16:796-810.
Erwin, E. S.; Marco, G. J. and Emery, E. M. 1961. Volatile fatty acid analyses of blood and rumen fluid by gas chromatography. Journal Dairy Science 44:1768-1771.
Fenner, H. 1965. Method for determining total volatile bases in rumen fluid by steam distillation. Journal of Dairy Science 48:249-251.
Freire, J. P. B.; Dias, R. I. M; Cunha, L. F. and Aumaitre, A. 2003. The effect of genotype and dietary fiber level on the caecal bacterial enzyme activity of young piglets: digestive consequences. Animal Feed Science and Technology 106:119-130.
Freire, J. P. B.; Guerreiro, A. J. G; Cunha, L. F. and Aumaitre, A. 2000. Effect of dietary fiber source on total tract digestibility, caecum volatile fatty acids and digestive transit time in the weaned piglet. Animal Feed Science and Technology 87:71-83.
Gomes, J. D. F.; Fukushima, R. S.; Putrino, S. M.; Grossklaus, C. and Lima, G. J. M. M. 2006. Efeitos do incremento da fibra em detergente neutro na dieta de suínos sobre a morfologia dos órgãos digestivos e não digestivos. Brazilian Journal Veterinary Research and Animal Science 43:202-209.
Gomes, J. D. F.; Putrino, S. M.; Martelli, M. R.; Sobral, P. J. A. and Fukushima, R. S. 2008. Desempenho e características de carcaça de suínos alimentados com dieta com feno de tifton (Cynodon dactylon). Ciência Animal Brasileira 9:59-67.
Gomes, M. O. S.; Beraldo, M. C.; Putarov, T. C.; Brunetto, M. A.; Zaine, L.; Glória, M. B. and Carciofi, A. C. 2011. Old beagle dogs have lower faecal concentrations of some fermentation products and lower peripheral lymphocyte counts than young adult beagles. British Journal of Nutrition 106:187-190.
Hofmann, K.; Hamm, R. and Luchel, E. 1982. New information on the determination of water binding in meat by the filter paper press method. Fleischwirtsch 62:87-94.
Horwitz, W. 2005. Guidelines for collaborative study procedures to validate characteristics of a method of analysis. Appendix D, AOAC Official methods of analysis. 18th ed. AOAC International, Geneva, Switzerland. p.1-12.
Jeaurond, E. A.; Rademacher, M.; Pluske, J. R.; Zhu, C. H. and de Lange, C. F. M. 2008. Impact of feeding fermentable proteins and carbohydrates on growth performance, gut health and gastrointestinal function of newly weaned pigs. Canadian Journal of Animal Science 88:271-281.
Jha, R. and Berrocoso, J. D. 2015. Review: dietary fiber utilization and its effects on physiological functions and gut health of swine. Animal 9:1441-1452.
Jorgensen, H.; Zhao, X. and Eggum, B. O. 1996. The influence of dietary fiber and environmental temperature on the development of the gastrointestinal tract, digestibility, degree of fermentation in the hind-gut and energy metabolism in pigs. British Journal of Nutrition 75:365-378.
Martinez-Ramirez, H. R.; Jeaurond, E. A. and de Lange, C. F. M. 2008. Dynamics of body protein deposition and changes in body composition after sudden changes in amino acid intake: I. Barrows. Journal of Animal Science 86:2156-2167.
Martins, C.; Pinho, M.; Lordelo, M. M.; Cunha, L. F.; Carvalho, J. and Freire, J. P. B. 2010. Effect of brewers grain on intestinal microbial activity and mucosa morphology of weaned piglets. Livestock Science 133:132-134.
McDonald, P.; Edwards, R. A. and Greenhalgh, J. F. D. 2006. Nutrición animal. 6.ed. Acribia, Zaragoza.
Ministério da Agricultura. 2000. Instrução Normativa n° 3, de 07 de janeiro de 2000. Regulamento técnico de métodos de insensibilização para o abate humanitário de animais de açougue. S.D.A./M.A.A. Diário Oficial da União, Brasília, DF, 24 jan. 2000. Seção I, p.14-16.
Montagne, L.; Arturo-Schaan, M.; Le Floc'h, N.; Guerra, L. and Le Gall, M. 2010. Effect of sanitary conditions and dietary fibre on the adaptation of gut microbiota after weaning. Livestock Science 133:113-116.
NRC - National Research Council. 2012. Nutrient requirement of swine. 11th ed. National Academic Science, Washington, DC.
Ordónez, J. A. 2005. Tecnologia de alimentos. Componentes dos alimentos e processos. v.1. Artmed, Porto Alegre.
Pascoal, L. A. F.; Thomas, M. C.; Watanabe, P. H.; Ruiz, U. S.; Ezequiel, J. M. B.; Amorim, A. B.; Daniel, E. and Masson, G. C. I. H. 2012. Fiber sources in diets for newly weaned piglets. Revista Brasileira de Zootecnia 41:636-642.
Pekas, J. C.; Yen, J. T. and Pond, W. G. 1983. Gastrointestinal carcass and performance traits of obese versus lean genotype swine: effect of dietary fiber. Nutrition Reports International 27:259-270.
Pond, W. G.; Jung, H. G. and Varel, V. H. 1988. Effect of dietary fiber on young adult genetically lean, obese and contemporary pigs: body weight, carcass measurements, organ weight and digesta content. Journal of Animal Science 66:699-706.
Possenti, R. A.; Franzolin, R.; Schammas, E. A.; Demarchi, J. J. A. A.; Frighetto, R. T. S. and Lima, M. A. 2008. Efeitos de dietas contendo Leucaena leucocephala e Saccharomyces cerevisae sobre a fermentação ruminal e a emissão de gás metano em bovinos. Revista Brasileira de Zootecnia 37:1509-1516.
Rekiel, A.; Wiecek, J. and Dziuba, M. 2005. Effect of feed additives on the results of fattening and selected slaughter and quality traits of pork meat of pigs with different genotypes. Czech Journal of Animal Science 50:561-567.
Rostagno, H. S.; Albino, L. F. T.; Donzele, J. L.; Gomes, P. C.; Oliveira, R. F.; Lopes, D. C.; Ferreira, A. S.; Barreto, S. L. T. and Euclides, R. F. 2011. Tabelas brasileiras para aves e suínos - Composição de alimentos e exigências nutricionais. Editora UFV, Viçosa, MG.
Serena, A.; Hedemann, M. S. and Bach Knudsen, K. E. 2008. Influence of dietary fiber on luminal environment and morphology in the small and large intestine of sows. Journal of Animal Science 86:2217-2227.
Silliker, J. H. 1980. Microorganisms in foods. 3. Microbial ecology of foods. Academic Press, New York.
Solà-Oriol, D.; Roura, E. and Torrallardona, D. 2011. Feed preference in pigs: Effect of selected protein, fat, and fiber sources at different inclusion rates. Journal of Animal Science 89:3219-3227.
Stefe, C. A.; Alves, M. A. R. and Ribeiro, R. L. 2008. Probióticos, prebióticos e simbióticos: Artigo de revisão. Saúde e Ambiente em Revista 3:16-33.
USDA - United State Department of Agriculture. 1994. National Engineering Handbook. Agricultural Waste Management Field Handbook. United State Department of Agriculture, Washington, DC.
Varel, V. H.; Pond, W. G. and Yen, J. T. 1984. Influence of dietary fiber on the performance and cellulose activity of growing-finishing swine. Journal of Animal Science 59:388-393.

Publication Dates

Publication in this collection
Apr 2017

History

Received
07 Apr 2016
Accepted
10 Jan 2017

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Araújo, M. A. 1995. Química de alimentos: teoria e prática. Imprensa Universitária, Viçosa, MG.

[2] ABCS - Associação Brasileira de Criadores de Suínos. 1973. Método brasileiro de classificação de carcaça. Estrela. 17p. (Publicação Técnica, 2).

[3] Bellé, J. C.; Silva, C. A.; Bridi, A. M. and Pacheco, G. D. 2009. Avaliação de prebióticos como promotor de crescimento para suínos nas fases de recria e terminação. Semina: Ciências Agrárias 30:471-480.

[4] Boler, D. D.; Holmer, S. F.; Duncan, D. A.; Carr, S. N.; Ritter, M. J.; Stites, C. R.; Petry, D. B.; Hinson, R. B.; Allee, G. L.; McKeith, F. K. and Killefer, J. 2011. Fresh meat and further processing characteristics of ham muscles from finishing pigs fed ractopamine hydrochloride. Journal of Animal Science 89:210-220.

[5] Budiño, F. E. L.; Castro, F. G. and Otsuk, I. P. 2010. Adição de frutoligossacarídeo em dietas para leitões desmamados: desempenho, incidência de diarreia e metabolismo. Revista Brasileira de Zootecnia 39:2187-2193.

[6] Budiño, F. E. L.; Prezzi, J. A.; Rodrigues, D. J.; Monferdini, R. P. and Otsuk, I. P. 2015. Desempenho e digestibilidade de leitões alimentados com rações contendo feno de alfafa e frutoligossacarídeo na fase inicial. Revista Brasileira de Saúde e Produção Animal 16:796-810.

[7] Erwin, E. S.; Marco, G. J. and Emery, E. M. 1961. Volatile fatty acid analyses of blood and rumen fluid by gas chromatography. Journal Dairy Science 44:1768-1771.

[8] Fenner, H. 1965. Method for determining total volatile bases in rumen fluid by steam distillation. Journal of Dairy Science 48:249-251.

[9] Freire, J. P. B.; Dias, R. I. M; Cunha, L. F. and Aumaitre, A. 2003. The effect of genotype and dietary fiber level on the caecal bacterial enzyme activity of young piglets: digestive consequences. Animal Feed Science and Technology 106:119-130.

[10] Freire, J. P. B.; Guerreiro, A. J. G; Cunha, L. F. and Aumaitre, A. 2000. Effect of dietary fiber source on total tract digestibility, caecum volatile fatty acids and digestive transit time in the weaned piglet. Animal Feed Science and Technology 87:71-83.

[11] Gomes, J. D. F.; Fukushima, R. S.; Putrino, S. M.; Grossklaus, C. and Lima, G. J. M. M. 2006. Efeitos do incremento da fibra em detergente neutro na dieta de suínos sobre a morfologia dos órgãos digestivos e não digestivos. Brazilian Journal Veterinary Research and Animal Science 43:202-209.

[12] Gomes, J. D. F.; Putrino, S. M.; Martelli, M. R.; Sobral, P. J. A. and Fukushima, R. S. 2008. Desempenho e características de carcaça de suínos alimentados com dieta com feno de tifton (Cynodon dactylon). Ciência Animal Brasileira 9:59-67.

[13] Gomes, M. O. S.; Beraldo, M. C.; Putarov, T. C.; Brunetto, M. A.; Zaine, L.; Glória, M. B. and Carciofi, A. C. 2011. Old beagle dogs have lower faecal concentrations of some fermentation products and lower peripheral lymphocyte counts than young adult beagles. British Journal of Nutrition 106:187-190.

[14] Hofmann, K.; Hamm, R. and Luchel, E. 1982. New information on the determination of water binding in meat by the filter paper press method. Fleischwirtsch 62:87-94.

[15] Horwitz, W. 2005. Guidelines for collaborative study procedures to validate characteristics of a method of analysis. Appendix D, AOAC Official methods of analysis. 18th ed. AOAC International, Geneva, Switzerland. p.1-12.

[16] Jeaurond, E. A.; Rademacher, M.; Pluske, J. R.; Zhu, C. H. and de Lange, C. F. M. 2008. Impact of feeding fermentable proteins and carbohydrates on growth performance, gut health and gastrointestinal function of newly weaned pigs. Canadian Journal of Animal Science 88:271-281.

[17] Jha, R. and Berrocoso, J. D. 2015. Review: dietary fiber utilization and its effects on physiological functions and gut health of swine. Animal 9:1441-1452.

[18] Jorgensen, H.; Zhao, X. and Eggum, B. O. 1996. The influence of dietary fiber and environmental temperature on the development of the gastrointestinal tract, digestibility, degree of fermentation in the hind-gut and energy metabolism in pigs. British Journal of Nutrition 75:365-378.

[19] Martinez-Ramirez, H. R.; Jeaurond, E. A. and de Lange, C. F. M. 2008. Dynamics of body protein deposition and changes in body composition after sudden changes in amino acid intake: I. Barrows. Journal of Animal Science 86:2156-2167.

[20] Martins, C.; Pinho, M.; Lordelo, M. M.; Cunha, L. F.; Carvalho, J. and Freire, J. P. B. 2010. Effect of brewers grain on intestinal microbial activity and mucosa morphology of weaned piglets. Livestock Science 133:132-134.

[21] McDonald, P.; Edwards, R. A. and Greenhalgh, J. F. D. 2006. Nutrición animal. 6.ed. Acribia, Zaragoza.

[22] Ministério da Agricultura. 2000. Instrução Normativa n° 3, de 07 de janeiro de 2000. Regulamento técnico de métodos de insensibilização para o abate humanitário de animais de açougue. S.D.A./M.A.A. Diário Oficial da União, Brasília, DF, 24 jan. 2000. Seção I, p.14-16.

[23] Montagne, L.; Arturo-Schaan, M.; Le Floc'h, N.; Guerra, L. and Le Gall, M. 2010. Effect of sanitary conditions and dietary fibre on the adaptation of gut microbiota after weaning. Livestock Science 133:113-116.

[24] NRC - National Research Council. 2012. Nutrient requirement of swine. 11th ed. National Academic Science, Washington, DC.

[25] Ordónez, J. A. 2005. Tecnologia de alimentos. Componentes dos alimentos e processos. v.1. Artmed, Porto Alegre.

[26] Pascoal, L. A. F.; Thomas, M. C.; Watanabe, P. H.; Ruiz, U. S.; Ezequiel, J. M. B.; Amorim, A. B.; Daniel, E. and Masson, G. C. I. H. 2012. Fiber sources in diets for newly weaned piglets. Revista Brasileira de Zootecnia 41:636-642.

[27] Pekas, J. C.; Yen, J. T. and Pond, W. G. 1983. Gastrointestinal carcass and performance traits of obese versus lean genotype swine: effect of dietary fiber. Nutrition Reports International 27:259-270.

[28] Pond, W. G.; Jung, H. G. and Varel, V. H. 1988. Effect of dietary fiber on young adult genetically lean, obese and contemporary pigs: body weight, carcass measurements, organ weight and digesta content. Journal of Animal Science 66:699-706.

[29] Possenti, R. A.; Franzolin, R.; Schammas, E. A.; Demarchi, J. J. A. A.; Frighetto, R. T. S. and Lima, M. A. 2008. Efeitos de dietas contendo Leucaena leucocephala e Saccharomyces cerevisae sobre a fermentação ruminal e a emissão de gás metano em bovinos. Revista Brasileira de Zootecnia 37:1509-1516.

[30] Rekiel, A.; Wiecek, J. and Dziuba, M. 2005. Effect of feed additives on the results of fattening and selected slaughter and quality traits of pork meat of pigs with different genotypes. Czech Journal of Animal Science 50:561-567.

[31] Rostagno, H. S.; Albino, L. F. T.; Donzele, J. L.; Gomes, P. C.; Oliveira, R. F.; Lopes, D. C.; Ferreira, A. S.; Barreto, S. L. T. and Euclides, R. F. 2011. Tabelas brasileiras para aves e suínos - Composição de alimentos e exigências nutricionais. Editora UFV, Viçosa, MG.

[32] Serena, A.; Hedemann, M. S. and Bach Knudsen, K. E. 2008. Influence of dietary fiber on luminal environment and morphology in the small and large intestine of sows. Journal of Animal Science 86:2217-2227.

[33] Silliker, J. H. 1980. Microorganisms in foods. 3. Microbial ecology of foods. Academic Press, New York.

[34] Solà-Oriol, D.; Roura, E. and Torrallardona, D. 2011. Feed preference in pigs: Effect of selected protein, fat, and fiber sources at different inclusion rates. Journal of Animal Science 89:3219-3227.

[35] Stefe, C. A.; Alves, M. A. R. and Ribeiro, R. L. 2008. Probióticos, prebióticos e simbióticos: Artigo de revisão. Saúde e Ambiente em Revista 3:16-33.

[36] USDA - United State Department of Agriculture. 1994. National Engineering Handbook. Agricultural Waste Management Field Handbook. United State Department of Agriculture, Washington, DC.

[37] Varel, V. H.; Pond, W. G. and Yen, J. T. 1984. Influence of dietary fiber on the performance and cellulose activity of growing-finishing swine. Journal of Animal Science 59:388-393.

Ingredient (%)	Control	5% alfalfa	10% alfalfa
Alfalfa (hay)	-	5.000	10.000
Soybean meal, 46%	20.000	17.000	16.600
Corn¹ 1 Fructooligosaccharide was added to corn in the treatments in which the prebiotic was tested.	37.800	33.800	24.570
Sugar	2.000	2.000	2.000
Soybean oil	0.200	2.000	6.500
Premix² 2 Guaranteed levels per kg ration: vitamin A, 30,000 IU; vitamin D3, 5,500 IU; vitamin E, 187.5 mg; vitamin K3, 12.5 mg; vitamin B1, 5.0 mg; vitamin B2, 12.50 mg; vitamin B6, 7.50 mg; vitamin B12, 100 µg; folic acid, 1 mg; pantothenic acid, 75 mg; niacin, 125 mg; biotin, 0.75 mg; choline, 3,000 mg; calcium (max.), 21 g; phosphorus (min.), 12.20 g; fluoride (max.), 122 mg; sodium, 5.5 g; iron, 250 mg; copper, 30 mg; zinc, 250 mg; manganese, 100 mg; iodine, 2.48 mg; selenium, 1 mg; cobalt, 1.88 mg; crude protein (min.), 18%; lysine, 16,000 mg; methionine, 7,200 mg; threonine, 10,603.6 mg; lactose (min.), 20%; flavoring agent, 500 mg; metabolizable energy, 3,000 kcal/kg; antioxidant, 0.025%.	40.000	40.000	40.000
L-lysine (HCl, 78%)	-	0.120	0.166
L-threonine (98%)	-	0.040	0.080
DL-methionine (99%)	-	0.040	0.085
Total	100.000	100.000	100.000
Calculated values
Energy (digestible) (kcal/kg)	3.267	3.180	3.225
Crude protein (%)	20.822	20.095	20.148
Lysine (digestible) (%)	1.709	1.700	1.700
Methionine (digestible) (%)	0.634	0.644	0.663
Met+Cys (digestible) (%)	0.983	0.965	0.965
Threonine (digestible) (%)	1.091	1.063	1.063
Tryptophane (digestible) (%)	0.263	0.240	0.230
Calcium (%)	0.621	0.684	0.754
Total phosphorus (%)	0.619	0.603	0.590
Sodium (%)	0.310	0.307	0.304
Neutral detergent fiber (NDF) (%)	6.280	7.590	8.820
NDF increment provided by	-	1.940	3.880
alfalfa (%)

Ingredient (%)	Control	5% alfalfa	10% alfalfa
Alfalfa (hay)	-	5.000	10.000
Soybean meal, 46%	29.000	25.600	25.400
Corn¹ 1 Fructooligosaccharide was added to corn in the treatments in which the prebiotic was tested.	47.900	42.910	34.710
Sugar	2.000	2.000	2.000
Soybean oil	1.100	4.300	7.600
Premix² 2 Guaranteed levels per kg ration: vitamin A, 60,000 IU; vitamin D3, 11,0000 IU; vitamin E, 375.0 mg; vitamin K3, 25 mg; vitamin B1, 10.0 mg; vitamin B2, 25 mg; vitamin B6, 15 mg; vitamin B12, 200 µg; folic acid, 2 mg; pantothenic acid, 150 mg; niacin, 250 mg; biotin, 1.5 mg; choline, 4,000 mg; calcium (max.), 43.75 g; phosphorus (min.), 21.25 g; sodium, 10 g; iron, 500 mg; copper, 57.5 mg; zinc, 500 mg; manganese, 300 mg; iodine, 3.875 mg; selenium, 2 mg; cobalt, 3.75 mg; crude protein (min.), 21%; lysine, 16,250 mg; methionine, 11,250 mg; threonine, 13,500 mg; lactose (min.), 20%; antioxidant, 50 mg.	20.000	20.000	20.000
L-lysine (HCl, 78%)	-	0.011	0.015
L-threonine (98%)	-	0.040	0.070
DL-methionine (99%)	-	0.040	0.070
Total	100.000	100.000	100.000
Calculated values
Energy (digestible) (kcal/kg)	3.337	3.318	3.304
Crude protein (%)	21.341	20.364	20.532
Lysine (digestible) (%)	1.529	1.500	1.500
Methionine (digestible) (%)	0.561	0.565	0.581
Met+Cys (digestible) (%)	0.898	0.870	0.870
Threonine (digestible) (%)	1.020	0.980	0.980
Tryptophane (digestible) (%)	0.280	0.254	0.245
Calcium (%)	0.728	0.790	0.860
Total phosphorus (%)	0.610	0.590	0.580
Sodium (%)	0.190	0.186	0.183
Neutral detergent fiber (NDF) (%)	8.440	11.270	10.860
NDF increment provide by	-	1.940	3.880
alfalfa (%)

Ingredient (%)	Control	5% alfalfa	10% alfalfa
Alfalfa (hay)	-	5.000	10.000
Soybean meal, 46%	29.600	30.000	30.200
Corn¹ 1 Fructooligosaccharide was added to corn in the treatments in which the prebiotic was tested.	63.195	56.390	48.188
Sugar	2.000	2.000	2.000
Soybean oil	1.000	2.400	5.300
Premix² 2 Guaranteed levels per kg ration: vitamin A, 262,500 IU; vitamin D3, 55,000 IU; vitamin E, 1.875 mg; vitamin K3, 100 mg; vitamin B1, 50.0 mg; vitamin B2, 125.0 mg; vitamin B6, 75.0 mg; vitamin B12, 1 µg; folic acid, 10 mg; pantothenic acid, 500 mg; niacin, 1,000 mg; biotin, 5.0 mg; choline, 10,000 mg; calcium (max.), 183 g; phosphorus (min.), 67 g; sodium, 36 g; iron, 2,000 mg; copper, 300 mg; zinc, 2,250 mg; manganese, 875 mg; iodine, 17.5 mg; selenium, 8.75 mg; cobalt, 16.25 mg; lysine, 7,000 mg; methionine, 5,000 mg; flavoring agent, 0.063%; antioxidant, 0.125%.	4.000	4.000	4.000
L-lysine (HCl, 78%)	0.020	0.010	0.047
L-threonine (98%)	0.015	0.020	0.055
DL-methionine (99%)	0.170	0.180	0.210
Total	100.000	100.000	100.000
Calculated values
Energy (digestible) (kcal/kg)	3.419	3.315	3.282
Crude protein, (%)	19.500	20.218	20.360
Lysine (digestible) (%)	1.280	1.280	1.280
Methionine (digestible) (%)	0.547	0.547	0.562
Met+Cys (digestible) (%)	0.877	0.871	0.870
Threonine (digestible) (%)	0.800	0.800	0.800
Tryptophane (digestible) (%)	0.254	0.254	0.245
Calcium (%)	0.820	0.893	0.962
Total phosphorus (%)	0.593	0.592	0.583
Sodium (%)	0.185	0.184	0.181
Neutral detergent fiber (NDF) (%)	9.900	11.340	12.530
NDF increment provide by	-	1.940	3.880
alfalfa (%)

FOS	Alfalfa			Mean±SD	Contrast
FOS	0%	5%	10%	Mean±SD	1	2
		Acetate (mmol/L)
0%	52.78±1.87	54.36±1.87	57.22±1.87	54.79±1.08	ns	ns
0.3%	51.65±1.87	56.52±1.87	56.89±1.87	55.02±1.08	^* * Significant statistical difference (P<0.05).	ns
Mean	52.21±1.32	55.44±1.32	57.05±1.32		ns	ns
		Propionate (mmol/L)
0%	33.14±2.21	30.63±2.21	31.60±2.21	31.79±1.28	ns	ns
0.3%	30.31±2.21	31.35±2.21	28.57±2.21	30.08±1.28	ns	ns
Mean	31.72±1.56	30.99±1.56	30.08±1.56		ns	ns
		Butyrate (mmol/L)
0%	14.08±2.06	15.01±2.06	11.18±2.06	13.42±1.19	ns	ns
0.3%	18.03±2.06	12.13±2.06	14.53±2.06	14.90±1.19	^* * Significant statistical difference (P<0.05).	ns
Mean	16.06±1.46	13.57±1.46	12.86±1.46		ns	ns
		pH
0%	5.91±0.12	5.70±0.12	5.91±0.12	5.84±0.07	ns	ns
0.3%	5.77±0.12	5.88±0.12	5.75±0.12	5.80±0.07	ns	ns
Mean	5.84±0.09	5.79±0.09	5.83±0.09		ns	ns
		N-NH₃ (g/kg)
0%	0.23±0.05	0.23±0.05	0.20±0.05	0.22±0.03	ns	ns
0.3%	0.35±0.05	0.32±0.05	0.22±0.05	0.29±0.03	ns	ns
Mean	0.29±0.03	0.27±0.03	0.21±0.03		ns	ns

FOS	Alfalfa			Mean±SD	Contrast
FOS	0%	5%	10%	Mean±SD	1	2
		Carcass (kg)
0%	15.98±0.79	16.69±0.79	14.68±0.79	15.78±0.45	ns	ns
0.3%	17.11±0.79	16.37±0.79	14.42±0.79	15.97±0.45	ns	^* * Significant statistical difference (P<0.05).
Mean	16.54±0.56	16.53±0.56	14.55±0.56		ns	ns
		Liver + gallbladder (g)
0%	542.78±32.54	589.35±32.54	499.18±32.54	543.77±18.79B	ns	ns
0.3%	654.77±32.54	612.42±32.54	584.27±32.54	617.15±18.79A	ns	ns
Mean	598.77±23.01	600.88±23.01	541.72±23.01		ns	ns
		Empty stomach (g)
0%	178.30±10.89	195.23±10.89	174.93±10.89	182.82±6.29B	ns	ns
0.3%	219.45±10.89	191.22±10.89	204.65±10.89	205.10±6.29A	ns	ns
Mean	198.87±7.70	193.22±7.70	189.79±7.70		ns	ns
		Intestine mass (g)
0%	1844.92±154.83	2302.33±154.83	2110.77±154.83	2086.00±89.39	ns	ns
0.3%	2280.97±154.83	2231.67±154.83	1931.93±154.83	2148.19±89.39	ns	ns
Mean	2062.94±109.48	2267.00±109.48	2021.35±109.48		ns	ns
		Carcass yield (%)
0%	73.28±0.97	75.95±0.97	78.99±0.97	74.07±0.56	^* * Significant statistical difference (P<0.05).	ns
0.3%	71.27±0.97	71.88±0.97	71.57±0.97	71.57±0.56	ns	ns
Mean	72.27±0.69	73.92±0.69	72.28±0.69		ns	ns

FOS	Alfalfa			Mean±SD	Contrast
FOS	0%	5%	10%	Mean±SD	1	2
		Length (cm)
0%	49.83±1.08	49.50±1.08	48.17±1.08	49.17±0.62	ns	ns
0.3%	51.58±1.08	51.92±1.08	48.83±1.08	50.78±0.62	ns	ns
Mean	50.71±0.76	50.71±0.76	48.50±0.76		ns	ns
		Backfat thickness 1 (mm)
0%	11.19±1.01	6.76±1.01	8.46±1.01	8.81±0.59	^ Significant statistical difference (P<0.01).	ns
0.3%	9.98±1.01	7.91±1.01	8.38±1.01	8.76±0.59	ns	ns
Mean	10.59±0.72	7.33±0.72	8.42±0.72		ns	ns
		Backfat thickness 2 (mm)
0%	4.18±0.54	2.66±0.54	3.13±0.54	3.32±0.31	ns	ns
0.3%	3.70±0.54	3.38±0.54	2.40±0.54	3.16±0.31	ns	ns
Mean	3.94±0.38	3.02±0.38	2.75±0.38		^* * Significant statistical difference (P<0.05).	ns
		Backfat thickness 3 (mm)
0%	3.15±0.42	2.50±0.42	2.28±0.42	2.64±0.24	ns	ns
0.3%	3.06±0.42	2.91±0.42	3.33±0.42	3.10±0.24	ns	ns
Mean	3.10±0.30	2.71±0.30	2.80±0.30		ns	ns
		Loin eye area (cm²)
0%	14.94±1.08	14.48±1.08	15.17±1.08	14.86±0.62	ns	ns
0.3%	14.08±1.08	13.42±1.08	14.08±1.08	13.86±0.62	ns	ns
Mean	14.51±0.76	13.95±0.76	14.63±0.76		ns	ns

FOS	Alfalfa			Mean±SD	Contrast
FOS	0%	5%	10%	Mean±SD	1	2
		Moisture (%)
0%	74.47±0.39	75.55±0.39	74.85±0.39	74.95±0.22	ns	ns
0.3%	74.24±0.39	75.45±0.39	75.60±0.39	75.10±0.22	^* * Significant statistical difference (P<0.05).	ns
Mean	74.35±0.27	75.50±0.27	75.22±0.27		ns	ns
		Fat (%)
0%	5.41±0.47	4.30±0.47	4.75±0.47	4.82±0.27	ns	ns
0.3%	5.78±0.47	4.69±0.47	4.46±0.47	4.98±0.27	^* * Significant statistical difference (P<0.05).	ns
Mean	5.59±0.33	4.49±0.33	4.61±0.33		ns	ns
		pH
0%	5.46±0.10	5.53±0.10	5.44±0.10	5.48±0.06	ns	ns
0.3%	5.60±0.10	5.57±0.10	5.55±0.10	5.57±0.06	ns	ns
Mean	5.53±0.07	5.55±0.07	5.49±0.07		ns	ns
		Water activity
0%	0.9933±0.0006	0.9938±0.0006	0.9930±0.0006	0.9934±0.0003	ns	ns
0.3%	0.9937±0.0006	0.9932±0.0006	0.9950±0.0006	0.9939±0.0003	ns	^* * Significant statistical difference (P<0.05).
Mean	0.9935±0.0004	0.9935±0.0004	0.9940±0.0004
		Water-holding capacity
0%	0.31±0.01	0.28±0.01	0.28±0.01	0.29±0.009	ns	ns
0.3%	0.33±0.01	0.29±0.01	0.27±0.01	0.29±0.009	^* * Significant statistical difference (P<0.05).	ns
Mean	0.32±0.01	0.29±0.01	0.27±0.01		ns	ns