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Flavonoids and mannanoligosaccharides in broiler diets

Antibiotic; broilers; flavonoids; mannan oligosaccharides; probiotic

Flavonoids and mannanoligosaccharides in broiler diets

Batista LSI; Garcia EAII; Faitarone ABGI; Sherer MRI; Móri CI; Pelícia KI; Pizzolante CCIII

IPost-graduation students of the Program of Post-Graduation in Animal Science and Animal Production FMVZ/UNESP - Botucatu

IIProfessor of the Dept. Animal Science – FMVZ/UNESP – Botucatu

IIIResearcher – UPD Brotas/APTA/SAA

Mail Address Mail Address Edivaldo Antônio Garcia Faculdade de Medicina Veterinária e Zootecnia, UNESP CP 560 - Distrito de Rubião Junior 18.690-000. Botucatu, SP, Brasil E-mail: egarcia@fca.unesp.br

Keywords: Antibiotic, broilers, flavonoids, mannan oligosaccharides, probiotic.

INTRODUCTION

This experiment was carried out at the at the poultry sector of the School of Veterinary Medicine and Animal Science – UNESP, Botucatu campus, and aimed at evaluating the effect of the inclusion of flavonoids along with mannan oligosaccharides (MOS) as compared to other additives on the performance, carcass and parts yields, and meat quality of broilers reared from 1 to 42 days of age. A total number of 1500 Cobb broilers were distributed according to a completely randomized experimental design into five treatments, with six replicates of 50 birds each. Treatments consisted of a control group, probiotic 1, probiotic 2, antibiotic, and flavonoids+MOS. For the period of 1 to 42 days of age, there were no differences among treatments as to daily weight gain, feed intake, mortality, and final body weight, but a significant difference was found for feed conversion ratio for the flavonoids+MOS treatment. Carcass and parts yields were not significantly influenced by the treatments. Tbars number, which indicates meat fat oxidation index, was significantly different in both refrigerated and frozen meat. The lowest oxidation index was obtained with the flavonoids+MOS treatments. Under the conditions of the present study, the supplementation of broiler diets with flavonoids+MOS was effective.

INTRODUCTION

Brazil is presently the world largest exporter of poultry meat. Brazilian poultry meat production chain generates more the US$10 billion annually, and more than one million direct and indirect job positions (Sbrissia, 2005).

One of the consequences of the increase in poultry production was the use of additives in animal nutrition to maximize performance indexes. Poultry production is presently highly dependent on the use of growth promoter to maintain high productivity levels. However, there is an increasing search for alternatives to practices that may pose risks to the consumers' health (Miltenburg, 2000).

The global concern with food safety is based on the possibility of the selection of bacteria resistant to antibiotics, which would be caused by the indiscriminate use of antibiotics used as growth promoters (Palermo Neto, 2002).

In the European Union, the ban of the use of antibiotic growth promoters was effective since January 1st, 2006, and coccidiostats and histomonostats will be banned in January (Comunidade Européia, 2002).

In Brazil, the following growth promoters were banned in 1998: tetracycline, penicillin, sulfonamide, chloramphenicol; in 2002, 3-nitro acid was banned, and in 2003, nitrofurazone and furazolidone (Demattê, 2004). The last substance to be banned as growth promoter was olaquindox, on November 25th, 2004 (Ministério da Agricultura, 2004).

Therefore, global market demands include the search for alternatives for antibiotic growth promoters, with no losses in performance. The main focus of the action of these alternative products is the gastrointestinal physiology. Research studies have demonstrated that organic acids, enzymes, symbiotics, prebiotics, probiotics, and phytogenic additives added to feeds may promote similar animal performance as to that achieved by conventional growth promoters (Nonboe, 1999).

Among the investigated alternatives, prebiotics, particularly mannan oligosaccharides, and phytogenic additives, such as flavonoids, are discussed here.

Prebiotics are defined as feed ingredients that are not digested in the gastrointestinal tract of monogastric animals, and that benefit the host by selectively stimulating the growth and/or metabolism of a limited group of bacteria in the gut (Gibson & Roberfroid, 1995). Ferket et al. (2002), working with turkeys, reported better performance when the feed was supplemented with mannan oligosaccharides.

Flavonoids are polyphenolic compounds, and their proven antioxidant properties yield several benefits to the body. Sebastián et al (2003) reported better carcass quality when flavonoids were added to swine diets.

Therefore, the present study aimed at evaluating the effects of flavonoids, mannan oligosaccharides, probiotics, and antibiotics on the performance, carcass yield, parts yield, and meat quality of 42-day-old broilers.

MATERIAL AND METHODS

This study was carried at the poultry sector of the School of Veterinary Medicine and Animal Science – UNESP, Botucatu campus, from February to April, 2004.

A total number 1500 male Cobb 500 broilers was used. Birds were weighed, and distributed into 5 treatments (control, probiotic 1, probiotic 2, antibiotic, flavonoids+ MOS), as shown in Table 1. A completely randomized experimental designed was applied, consisting of five treatments with 6 replicates of 50 birds each.

Feed and water were offered ad libitum. All feeds contained the coccidiostat sodium monensin, which was withdrawn when birds were 35 days of age. Diets were formulated to contain the same nutrient levels, and the only change was the additive used. All additives were added to the feeds as powder.

Performance data were measured for the period of 1 to 42 days of age. Body weight was determined per box. Daily weight gain was calculated as average final weight minus average initial weight, and dividing the result by the number of experimental days. Average feed intake was calculated as supplied feed minus feed residue at the end of the experimental period, and dividing the result by the average number of birds. Feed conversion ratio was calculated as the ratio between total feed intake and total weight gain plus weight gain of dead birds. Mortality was daily recorded, and the data, before being submitted to analysis of variance, were transformed into the square root of (x + 0.5)1/2, where x is mortality percentage (Steel & Torrie, 1980). All dead birds were weighed to correct feed intake and feed conversion ratio.

At 42 days of age, four birds per box were removed (24 per treatment, 120 birds total), individually identified by leg bands, and after being submitted to 8 hours fasting, they were slaughtered at the experimental slaughter plant of FMVZ/UNESP, Botucatu Campus, SP.

Carcass yield and part yield were calculated on live weight and carcass weight basis. Live weight was measured immediately before slaughter. Carcass weight was considered as carcass weight with no neck, feet, and abdominal fat. The following parts were evaluated: breast, legs (thighs+legs), back, wings, and thigh meat and breast meat. Yields were determined according to the methodology described by Mendes (1990).

To evaluate meat quality, leg samples were collected during slaughter, identified by leg bands, and frozen, if necessary.

Tbars number, which indicated the degree of fat oxidation, was determined by the distillation method recommended by Pikul et al. (1989). Legs were analyzed in two periods: refrigerated meat (meat refrigerated at 4ºC for four days), and frozen meat (meat frozen at -18ºC for six months).

Data were analyzed by analysis of variance, using SISVAR statistical package, as described by Ferreira (1998), and means were compared by the test of Tukey at 5% significance level.

RESULTS AND DISCUSSION

Performance results are presented in Table 2.

Considering the period of 1 to 42 days of age, there was no significant effect (p>0.05) of treatments on average body weight, daily weight gain, feed intake, or mortality. There was a significant effect (p<0,05) of the treatments on feed conversion ratio, with the broilers fed flavonoids + MOS presenting the best feed conversion ratio. Vargas Jr. et al. (2001) did not report significant differences in the performance of broiler fed diets supplemented with prebiotics and probiotics; however, as in the present study, flavonoids were also added with the prebiotic, this association may have favored an improvement in feed conversion ratio.

Table 3 presents carcass yield results.

Treatments had no influence (p>0.05) on carcass yield or leg, back, breast, and leg percentages. These results are consistent with those of Sartori et al. (2003), Gonçalves et al. (2002), and Pelicia (2004). However, Moreira et al. (2001) observed higher breast yield in broilers fed antibiotic-supplemented diets.

Leg meat and breast meat yield results are shown in Table 4.

The results obtained in the present study showed that the experimental treatments had no effect (p>0.05) on leg meat and breast meat yields. These results are in agreement with the studies of Maiorka (2001) and Loddi (2000), who did not find significant differences in these parameters when feeding broilers with diets supplemented with prebiotic and probiotic.

The results observed in the present experiment for carcass, parts, leg meat, and breast meat yields were expected, as several literature studies reported that prebiotics, probiotics, and antibiotics present similar effects on the control of the intestinal microflora and on the transformation of ingested feed into meat (Pelicia, 2004).

The results for Tbars number in thigh meat are presented in Table 5.

Tbars number results were significantly different among experimental treatments, both in refrigerated and frozen meat. Tbars number scale ranges from 0 to 1, with lower number indicating lower meat oxidation. Thigh meat was used to analyze Tbars number as it presents higher fat content as compared to breast muscle, and therefore, it can be subject to a higher degree of oxidation.

It is possible to observe that, under refrigeration (period 1), results showed that thigh meat as already experiencing fat oxidation, and that the flavonoid +MOS treatment presented the lowest oxidation index, whereas the antibiotic treatments, the highest. After freezing (period 2), results showed that thigh meat presented higher oxidation index that after refrigeration. The flavonoids +MOS treatment promoted lower oxidation index than the treatment probiotic 1.

There was lower meat fat oxidation both after refrigeration and freezing when birds were fed flavonoids + MOS, which may be attributed to the antioxidant effect of flavonoids, which was already described by Sebastián et al. (2003) in pork.

CONCLUSIONS

Under the conditions of the present experiment, the use of flavonoids, together with mannan oligosaccharide (MOS) was effective as compared to other additives used for the supplementation of broiler diets.

Arrived: October / 2005

Approved: April / 2007

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  • Mail Address
    Edivaldo Antônio Garcia
    Faculdade de Medicina Veterinária e Zootecnia, UNESP
    CP 560 - Distrito de Rubião Junior
    18.690-000. Botucatu, SP, Brasil
    E-mail:
  • Publication Dates

    • Publication in this collection
      24 July 2007
    • Date of issue
      Mar 2007

    History

    • Received
      Oct 2005
    • Accepted
      Apr 2007
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