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Revista Brasileira de Ciência Avícola - Nutritional and microbiological evaluation of meat and bone meal produced in the state of Minas Gerais

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Revista Brasileira de Ciência Avícola

Print version ISSN 1516-635X

Rev. Bras. Cienc. Avic. vol.5 no.1 Campinas Jan./Apr. 2003

http://dx.doi.org/10.1590/S1516-635X2003000100007 

Nutritional and microbiological evaluation of meat and bone meal produced in the state of Minas Gerais

 

 

Sartorelli SAI; Bertechini AGII; Fassani EJIII; Kato RKIII; Fialho ETII

IMaster of Science (Animal Production)
IIProfº - Depto. de Zootecnia - UFLA, Lavras - MG - Brasil
IIIPh.D student - Depto. de Zootecnia – UFLA/CAPES, Lavras - MG - Brasil

Correspondence

 

 


ABSTRACT

The present study investigated the chemical composition and metabolizable energy levels of ten meat and bone meals (MBM) produced in Minas Gerais state (Experiment I) and evaluated the growth performance of broilers fed with diets containing those MBM (Experiment II). In the first experiment, energy values (apparent metabolizable energy [AME] and corrected apparent metabolizable energy [AMEn]) of ten different MBM were determined using the traditional method with total collection of excreta. Four hundred forty 21 day-old Hubbard broilers were used. A reference corn and soybean meal-based diet was replaced in 20% by the feed containing MBM to be tested. A completely randomized experimental design was used with eleven treatments (one reference diet and ten MBM), four repetitions per treatment and 10 birds per repetition (5 males and 5 females). In the second experiment, five MBMs from the ten analyzed in Experiment 1 were used as phosphorus source and compared to a diet containing bicalcium phosphate. The growth performance of the broilers fed with these diets was analyzed, considering two ages of the onset of MBM inclusion in the diet (1 or 7 days of age). One-day-old Hubbard broilers (1,320 birds) were housed in 44 plots with 30 birds per experimental unit. The experiment consisted of 11 treatments in a 5x2 factorial arrangement, with five sources of MBM, two ages for the onset of inclusion, and a reference treatment without addition of MBM. The results obtained showed a great variation in the chemical composition and apparent metabolizable energy of the evaluated meals. No significant differences were found on the performance of broilers fed diets with different MBM or the diet with bicalcium phosphate as phosphorus source. The performance of broilers was not significantly influenced by the onset of MBM inclusion in the diets.

Keywords: Broilers, ingredient, meat and bone meal, metabolizable energy, Salmonella


 

 

INTRODUCTION

During the last years, beef cattle production in Brazil has increased, which resulted in an higher production of slaughter by-products that can be used in animal feeding. The meat and bone meal (MBM) can be considered the main slaughter by-product, because of the greatest proportion of materials and residues that cannot be used in human nutrition and are thus used to produce MBM. Minas Gerais State has contributed for the increase in the production of this ingredient because it has one of the most important bovine herds of Brazil.

Nowadays, poultry industry consumes most of the MBM produced in that state. MBM is considered to be a good source of amino acids, as well as a source of minerals and vitamins. For a long time, MBM has been used mainly as a source of high quality protein, an essential raw material to elaborate diets for animals in need of protein with high biological value. Besides, it also contains phosphorus, an important mineral in animal metabolism. The increase in soybean meal utilization resulted in a decrease in the use of MBM as the main protein source. Thus, it became the first choice as a phosphorus source, due to the high cost of the inorganic sources for that mineral. In spite of the great use of MBM in chicken diets, the nutritional composition of the many MBMs that can be found in Minas Gerais is not yet known. Several farms and food industries produce diets based on nutrient requirement tables compiled abroad, such as NRC (1994). Nevertheless, due to different production and processing processes, the chemical composition and energy values presented by these tables are different from the values reported by brazilian authors, such as nutrient requirements from the Centro Nacional de Pesquisa em Suínos e Aves (Embrapa, 1991) and Rostagno et al. (2000).

This research was undertaken to study the chemical and energetic compositions, presence of microorganisms and foreign bodies, as well as to evaluate the performance of birds fed diets containing MBMs produced in Minas Gerais State.

 

MATERIAL AND METHODS

Two experiments using broiler chickens were conducted. Experiment 1 determined the chemical composition and metabolizable energy (ME), and the presence of microorganisms and foreign bodies in MBMs produced in Minas Gerais State using an assay with one-day-old broilers.

Experiment 2 was conducted to evaluate the performance of broilers fed with 5 different MBMs that had been analyzed in Experiment 1, at 2 different ages of inclusion onset (1 and 7 days). The MBMs chosen were according to the standard classification of the Divisão de Fiscalização de Alimentos para Animais (Difisa, 1989). MBM percentage in the diets was adjusted so that equal phosphorus levels were supplemented to all treatments.

Experiment 1 used 440 Hubbard broilers aging 21 days and housed randomly in 44 cages in batteries. The birds were given 11 experimental diets: one reference diet (Table 1) and 10 experimental diets in which 20% of the experimental diet was substituted by the diets containing the MBMs. A completely randomized experimental design was used, with 4 repetitions per treatment, and 10 birds per repetition (5 of each sex). Mean body weight was 690 g when they were housed. After 3 days of pre-experimental period, feces were collected for 5 days, using the total collection method. The average minimum and maximum temperatures registered during the trial were 20.0 and 31.5oC, respectively.

 

 

Dry matter, crude protein, ash, ether extract, calcium and MBM were evaluated according AOAC (1990), and gross energy were determined in calorimeter "Parr" 1271 model.

Apparent metabolizable energy (AME) and corrected apparent metabolizable energy (AMEn) of the MBMs were determined according to Matterson et al. (1965). The chemical composition of the reference and experimental diets is shown in Table 2.

Microbiological analysis were performed according to the methods described by the American Public Health Association (Speck, 1984), and microscopic evaluations were made according to the method approved by the American Association of Feed Microscopists (AAFM, 1992).

In Experiment 2, 1320 one-day-old Hubbard broiler chicks were used. The birds were weighed (mean=41.5 g), allocated in 44 cages (4 per treatment) with 30 birds per experimental unity. Average minimum and maximum temperatures were 18.0 and 28.4ºC, respectively. During the experimental phase, birds were given water and feed ad libitum. A randomized experimental design was used, with 11 treatments in a 5 x 2 factorial scheme (five MBMs as phosphorus source and 2 ages for the onset of MBM inclusion in the diet, 1 or 7 days) and an extra treatment with dicalcium phosphate as phosphorus source (Table 3). Inclusion level of MBM in the diets was calculated so that all treatments had the same amount of phosphorus provided. The composition of the experimental starter diets (1 to 21 days) is shown in Table 4 and the composition of the grower diets (21 to 42 days) is shown in Table 5. Diets were formulated using the ingredient composition tables of Rostagno et al. (2000), except the metabolizable energy values of MBMs, which were determined in Experiment 1.

Weight gain (g), feed intake (g) and feed conversion (g/g) were evaluated and data were statistically analyzed using the software SANEST (Statistical Analysis System) as described by Sarries et al. (1992). Performance means were compared using Tukey's test (Experiment 2).

 

RESULTS AND DISCUSSION

Experiment 1

Chemical composition (Table 6) and the presence of contaminants (Table 7) were different among the MBMs analysed in Minas Gerais state. Considering the contamination by Mesophilus, molds and yeasts, all samples were classified as of good quality according to the criteria established by Andriguetto et al. (1990). Coliforms were found in two MBM samples (Table 7). According to the considered criteria (Andriguetto et al., 1990), 80% of the MBMs were within the acceptable range for that characteristic. Salmonella contamination was detected in 90% of the MBMs, an undesirable feature considering that the presence of that microorganism might occur by cross contamination during slaughter due to the contact of the carcass with the feathers or the intestinal content. It was also observed the presence of hair (20%), skull/horn (40%) and leather/collagen (60%) in the MBMs. Routine analysis does not usually detect these foreign bodies that are considered protein sources of low biological value. Even small quantities of contaminants such as plastic, vegetable crude fiber, blood and innards indicates failures during processing.

All samples were classified as meat and bone meal according to the requirements of Divisão de Fiscalização de Alimentos para Animais (Difisa, 1989), with phosphorus levels above 3.8%, independent of the protein content. The maximum allowed calcium:phosphorus ratio is 2.2: 1 (Difisa, 1989) and all samples fulfilled that requirement. Similar results were found by Coelho (1983) and Azevedo (1997).

The protein content of the analyzed samples should be 40 to 55%, according to Difisa (1989) and Rostagno et al. (2000). Thus, the samples were graded as: MBM type 40: samples 03, 04, 05 and 06; MBM type 45: sample 07; MBM type 50: samples 08 and 09; MBM type 55: sample 10. Samples 01 and 02 did not fit any standard. Crude protein (CP) results lower than 40% were also observed by Azevedo (1997) in three samples out of nine analyzed samples (30.47; 37.14 and 39.06%). Samples within the same protein class showed variations in the chemical composition. The variation might result from the fact that neither the equipment nor the raw material used to produce MBM have been standardized. The maximum water content allowed by the Department of Agriculture is 8.0% (Difisa, 1989). Therefore, MBM samples 02, 04, 06 and 07 have higher levels than the standard (8.24; 8.66; 8,94 and 9.04%, respectively).

The minimum ether extract value allowed by Difisa (1989) is 8.0%, and all analyzed samples showed values similar to the standard. According to Difisa (1989), the maximum ash values for MBM types 40, 45, 50 and 55 are 43; 36; 32 and 28%, respectively.

Samples 01 and 02 showed higher values, 43.65 and 44.15%, respectively. However, crude protein levels of these samples were lower than the standard value (40). MBM samples 01 and 02 had crude protein values of 34.99 and 36.52% respectively.

Gross energy values (GE) varied greatly among samples. This was expected due to the discrepant ash values. Sample 10 had a high GE content (4,226 kcal/kg) as a result of the high crude protein content (56.30%) and low mineral matter content (23.93%); followed by sample 07 (4,011 kcal/kg), which did not show a high protein content, but showed a high content of ether extract (15.98%) and a low mineral matter level (30.50%). A low GE content was observed in MBM 01 (2,626 kcal/kg), probably because of the smaller protein content (34.99%) found in the same sample together with one of the largest ash levels (43.65%). Azevedo (1997) also found variable GE values (2,986 to 4,320 kcal/kg) giving strong evidence in the relation between GE and mineral matter.

The values of AME found for the different MBM samples varied from 1,024 to 2,671 kcal/kg DM (Table 8). These AME values were higher than the values reported in the ingredient composition table from Rostagno et al. (2000) for the same protein standard level. Analyzed samples graded as protein standard 40 showed AME values from 2,032 to 2,379 kcal/kg DM whereas the table shows 1,945 kcal/kg DM. For the standard 45, 2,671 kcal/kg DM of the analyzed sample against 2,004 kcal/kg DM of the table. For the standard 50 values from 2,025 to 2,438 kcal/kg DM against 2,227 kcal/kg DM of the table and for the standard 55 the value of 2,241 kcal/kg DM against 2,286 kcal/kg DM. The latter was the only result lower than the values reported by Rostagno et al. (2000).

 

 

AMEn values decreased after they were corrected for nitrogen balance (NB), except for MBM 01 and 04, which increased from 1,151 to 1,218 kcal/kg DM and 2,032 to 2,080 kcal/kg DM, respectively. The average AMEn values obtained in our study was 98.22% of the EMU values. Coelho (1983), Azevedo (1997) and Albino et al. (1992) also observed AMEn values lower than AME.

Experiment 2

The performance of the birds using the evaluated MBMs was inside the normal values (Tables 9, 10 and 11), and no significant differences (p>0.05) was seen among them at 7, 14, 21, 28, 35 and 42 days of age. These results indicate that a good nutrient supply was provided by the meals. Furthermore, when the specific energetic content of each MBM was corrected, the performance of the birds was similar. Regarding the day of MBM inclusion onset in the diet in the initial phase (1 or 7 days), the final body weight of the birds was not significantly different (p>0.05) between ages (Table 9).

Age had no effect (p>0.05) on weight gain, feed conversion and feed intake at 7, 14, 21, 28, 35 and 42 days of age (Tables 9, 10 and 11, respectively). Thus, changes in the levels of inclusion (with different protein) did not influence the final energy content, even with differences in the metabolizable energy value for the several MBMs.

 

CONCLUSIONS

The analyzed MBMs showed variation in chemical composition with high Salmonella contamination, and the AME and AMEn values of the MBMs was different with average values of 2,025 and 1,989 kcal/kg, respectively.

Performance of broilers fed MBMs was similar when the nutrition levels of the diet were balanced, and the MBMs used in the initial phase had no detrimental effect on the studied parameters. The source of phosphorus, MBM or dicalcium phosphate, did not affect performance.

 

REFERENCES

Albino LFT, Rostagno HS, Tafuri ML, Silva MA. Determinação dos valores de energia metabolizável aparente e verdadeira de alguns alimentos para aves, usando diferentes métodos. Revista da Sociedade Brasileira de Zootecnia, 1992; 26 (6): 1047-1058        [ Links ]

AAFM - American Association of Feed Microscopists. Manual of microscopic analysis of feedstuffs. 3ed. 1992. 211p.        [ Links ]

Andriguetto JM, Perly L, Minardi I, Gemael A, Flemming JS, Souza GA, Filho AB. As bases e os fundamentos da nutrição animal. 4ed. São Paulo: Nobel, 1990. 369p.        [ Links ]

AOAC - Association of Official Analytical Chemist. Official methods of analysis. 15 ed. Arlington, 1990. 1230p.        [ Links ]

Azevedo DMS. Fatores que afetam os valores de energia metabolizável da farinha de carne e ossos para aves. [Dissertação de Mestrado]. Viçosa:UFV, 1997. 68p.        [ Links ]

Coelho MGR. Valores energéticos e de triptofano metabolizável de alimentos para aves, usando duas metodologias. [Dissertação de Mestrado].Viçosa:UFV, 1983. 77p.        [ Links ]

Difisa - Divisão de Fiscalização de Alimentos para Animais. Padrões oficiais de matérias primas destinadas à alimentação animal. Brasília:DIFISA, 1989. 40p.        [ Links ]

EMBRAPA - Empresa Brasileira Agropecuária. Tabela de composição química e valores energéticos de alimentos para suínos e aves. Embrapa-CNPSA: Concórdia, 1991; (19): 97.        [ Links ]

Matterson LD, Potter LM, Stutz MW, Singsen EP. The metabolizable energy of feed ingredients for chickens. University of Connecticut Storrs. Agricultural Experiment Station, 1965. 11p.        [ Links ]

NRC - National Research Council. Nutrient requirements of poultry. 9 ed. Washington: D.C., 1994. 71p.        [ Links ]

Rostagno HS, Albino LTF, Donzele JL, Gomes PC, Ferreira AS, Oliveira RF, Lopes DC. Tabelas brasileiras para aves e suínos; Composição de alimentos e exigências nutricionais. Viçosa:UFV – Imprensa Universitária. 141p. 2000.        [ Links ]

Sarries GA, Alves MC, Oliveira JCC. SANEST – Sistema de análise estatística para DOS. Piracicaba: ESALQ/CIAGRI, 58p. 1992.        [ Links ]

Speck ML. Compedium of methods for the microbiological examination of foods. Washington: APHA/Technical Committee on Microbiological for Foods. 1984. 914p.        [ Links ]

 

 

Correspondence to
Antonio Gilberto Bertechini
Depto. de Zootecnia - Universidade Federal de Lavras Caixa Postal 37
37200-000 - Lavras - MG - Brasil
E-mail: bertechi@ufla.br

Arrived: May 2002
Approved: October 2002