Microencapsulated carvacrol and cinnamaldehyde replace growth-promoting antibiotics: Effect on performance and meat quality in broiler chickens

BOSETTI, GILNEI E.; GRIEBLER, LETIERI; ANIECEVSKI, EDEMAR; FACCHI, CAROLINE S.; BAGGIO, CINTIAMARA; ROSSATTO, GABRIEL; LEITE, FELIPE; VALENTINI, FERNANDA D.A.; SANTO, ALICIA D.; PAGNUSSATT, HELOÍSA; BOIAGO, MARCEL M.; PETROLLI, TIAGO G.

doi:10.1590/0001-3765202020200343

Abstract

The aim was to evaluate the use of mixture of microencapsulated carvacrol and cinnamaldehyde as a replacement for growth-promoting antibiotics in broiler diets on performance, intestinal quality, organ development, carcass yields and cuts, and meat quality. In the trial were used 600 male chicks, allocated in a completely randomized design, with five treatments and eight replicates of 15 birds, reared up to 41 days of age. The treatments were: Negative Control (NC), Positive Control (PC) 30 mg/kg of virginiamycin, NC+100 mg/kg of essential oils, NC+200 mg/kg of essential oils and NC+400 mg/kg of essential oils. Essential oils were composed by a micro-encapsulated blend, with of 60% cinnamaldehyde, 30% carvacrol and 10% carrier. Birds received essential oils achieved performance equivalent to those birds received PC diets, having better development than NC broilers. No differences were found on relative organ weight, intestinal mucosa and meat quality parameters, however, higher villus:cript ratio was found in PC, NC+200 and NC+400 groups. Meat crude protein and yellowness were influenced by inclusion of carvacrol and cinnamaldehyde. It was concluded microencapsulated carvacrol and cinnamaldehyde can replace growth-promoting antibiotic in broiler diets, ensuring performance, intestinal integrity and broiler meat quality.

Key words
cinnamon; essential oils; oregano; bacterial resistance; villus

INTRODUCTION

The broiler meat production has grown substantially in recent decades, especially due to the intensive production systems, improving its importance for the global animal protein production and economy. The Food and Agriculture Organization of the United Nations (FAO 2017FAO - FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS. 2017. Cenário da demanda por alimentos [Online]. Disponível em: http://www.fao.org/brasil/noticias/detail-events/en/c/901168/. Acessado em: 12 ago 2018.
http://www.fao.org/brasil/noticias/detai... ) estimates that, by 2022, chicken meat will be the most consumed animal protein worldwide. The increase in the consumption of chicken meat is directly associated with consumer preference for healthier eating habits and with increased health and life expectancy (FAO 2017FAO - FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS. 2017. Cenário da demanda por alimentos [Online]. Disponível em: http://www.fao.org/brasil/noticias/detail-events/en/c/901168/. Acessado em: 12 ago 2018.
http://www.fao.org/brasil/noticias/detai... ). Petracci et al. (2015)PETRACCI M, MUDALAL S, SOGLIA F & CAVANI C. 2015. Meat quality in fast-growing broiler chickens. Worlds Poult Sci 71: 363-374. stated that the increase in the consumption of chicken meat is associated with its low cost as well as its nutritional profile.

To find the demand for chicken meat production, improvements in nutrition and sanitation are necessary, and the continuous use of antibiotics as growth promoters has been a tool of constant use, to maintain expected zootechnical indexes. Nevertheless, antibiotic growth-promoters generate antibiotic resistant organisms (Muro et al. 2015MURO EM, PELICIA VC, VERCESE F, SOUZA IMGP, PIMENTA GEM, OLIVEIRA RSSG & SARTORI JR. 2015. Aditivos fitogênicos e glutamina mais ácido glutâmico na dieta de frangos desafiados com coccidiose. Rev Agrar 8: 304-311.), a substantial problem for the human population. Therefore, these growth promoters have been prohibited in countries such as Sweden, Denmark, Norway and the European Union (Diarra & Malouin 2014DIARRA MM & MALOUIN F. 2014. Antibiotics in Canadian poultry productions and anticipated alternatives. Front Microbiol 5: 1-15.). In response to changes in the market for animal products, dietary strategies for broiler diets include replacement of traditional antibiotic-based growth promoters (Reis et al. 2018REIS JH ET AL. 2018. Effects of phytogenic feed additive based on thymol, carvacrol and cinnamic aldehyde on body weight, blood parameters and environmental bacteria in broilers chickens. Microb pathogen 125: 168-176., Galli e al. 2020). Among these strategies, various essential oils, including carvacrol and cinnamaldehyde extracted from oregano and cinnamon, respectively, have become prominent due to these substances possess antimicrobial activity and may, therefore, substitute antibiotic-based growth promoters (Petrolli et al. 2012PETROLLI TG, ALBINO LFT, ROSTAGNO HS, GOMES PC, TAVERNARI FC & BALBINO EM. 2012. Herbal extracts in diets for broilers. Rev Bras Zootec 41: 1683-1690., Bastos-Leite et al. 2016BASTOS-LEITE SC, ALVES EHA, SOUSA AM, GOULART CC, SANTOS JPM & SILVA JDB. 2016. Ácidos orgânicos e óleos essenciais sobre o desempenho, biometria de órgãos digestivos e reprodutivos de frangas de reposição. Acta Vet Bras 10: 201-207., Reis et al. 2018REIS JH ET AL. 2018. Effects of phytogenic feed additive based on thymol, carvacrol and cinnamic aldehyde on body weight, blood parameters and environmental bacteria in broilers chickens. Microb pathogen 125: 168-176., Zhai et al. 2018ZHAI H, LIU H, WANG S, WU J & KLUENTER AM. 2018. Potential of essential oils for poultry and pigs. Anim Nutr 4: 179-186., Galli et al. 2020GALLI GM ET AL. 2020. Combination of herbal components (curcumin, carvacrol, thymol, cinnamaldehyde) in broiler chicken feed: Impacts on response parameters, performance, fatty acid profiles, meat quality and control of coccidia and bacteria. Microb pathog 139: e103916.), in addition to their antioxidant actions, anti-inflammatory and analgesic properties (Suntres et al. 2015SUNTRES ZE, COCCIMIGLIO J & ALIPOUR M. 2015. The bioactivity and toxicological actions of carvacrol. Crit. Rev Food Sci Nutr 55: 304-318.). Zeng et al. (2015)ZENG Z, ZHANG S, WANG H & PIAO X. 2015. Essential oil and aromatic plants as feed additives in non-ruminant nutrition: a review. J Anim Sci Biotechnol 6: 1-10. reported carvacrol acts on intestinal flora balance and stimulates intestinal mucosa to increase mitosis in villus crypts, increasing the number of cells and consequently increasing villus size, resulting in improved nutrient absorption.

On account of these anti-inflammatory and antioxidant properties, essential oils have been studied with the aim of improving chicken meat quality. Kuttappan et al. (2012)KUTTAPPAN VA, LEE YS, ERF GF, MEULLENET JFC, MCKEE SR & OWENS CM. 2012. Consumer acceptance of visual appearance of broiler breast meat with varying degrees of white striping. Poult Sci 91: 1240-1247. described consumers rejected meat with poor and visual-oxidated aspect, demonstrating that people prefer meat of particular quality and appearance at the time of purchase. Due to this behavior, alternatives to access better broiler meat quality are little studied and needs to be tested. Oregano essential oil in the diets of broiler chickens reduced lipid peroxidation in broiler chicks (Arieza Nieto et al. 2018ARIEZA NIETO C, ORTIZ RE & TELLEZ GA. 2018. Effect of two chemotypes of oregano essential oil on broiler performance nutrient balance, and lipid peroxidation of breast meat during storage. Cienc Anim Bras 19: 1-15.). Luna et al. (2010)LUNA A, LÁBAQUE MC, ZYGADLO AJ & MARIN RH. 2010. Effects of thymol and carvacrol feed supplementation on lipid oxidation in broiler meat. Poult Sci 89: 366-370. comproved adequate BHT substitution by phytogenics compounds (from oregano), on thiobarbituric acid reactions (TBARS) evaluation in breasts of fresh-cut broilers. Thus, carvacrol and cinnamaldehyde may have beneficial effects in improving the quality of meat, preventing or delaying its oxidation. However, studies testing this potential effect are scarce, and its evaluation is strongly necessary.

Currently, molecules microencapsulation process has been subject of studies in poultry nutrition, since it allows the molecules to reach with better proportionality all areas of the intestine, mainly jejunum and ileum, which are sites of impacting microbial proliferation, and the microencapsulation allows phytogenic molecules to reach these regions more efficiently, generating a better intestinal health-enhancing effect, with better efficiency when compared to phytogenic molecules in free form.

Despite the fact that there have been studies on the replacement of growth promoters by essential oils, it remains unknown which essential oils and what levels of inclusion give the best results in terms of broiler meat quality. Therefore, in the present study, we aimed to evaluate the inclusion of carvacrol and cinnamaldehyde on zootechnical performance, gut histology and broiler meat quality.

MATERIALS AND METHODS

Animals and experimental design

This study was conducted in the Núcleo de Ciência e Pesquisa Aplicada à Monogástricos, from Universidade do Oeste de Santa Catarina - UNOESC Xanxerê, with a protocol submitted and approved by the animal ethics committee Comissão de Ética do Uso de Animais (CEUA/UNOESC) under protocol number 50/2017.

A total of 600 ROSS 308 male chicks were used, being vaccinated in ovo in hatchery, against Marek and Gumboro disease, and via spray on the first day of life, against infectious bronchitis. Birds were weighed and distributed on the first day of life, in a completely randomized experimental design, consisting of five treatments and eight replicates, with 15 animals in each replicate: Negative Control (NC), Positive Control (PC) (virginiamycin 15 mg/kg), NC+100 mg/kg of essential oils, NC+200 mg/kg of essential oils and NC+400 mg/kg of essential oils. The additive evaluated was a commercial formulated product (Enterosan, Konkreta Nutrition Technology, Navegantes, Brazil), being a blend of micro-encapsulated essential oils consisted of 60% cinnamaldehyde from cinnamon, 30% carvacrol from oregano and 10% of limestone as vehicle. The microencapsulation process was performed by atomization process, as described by Pereira et al. (2018)PEREIRA KC, FERREIRA DCM, ALVARENGA GF, PEREIRA MSS, BARCELOS MCS & COSTA JMC. 2018. Microencapsulação e liberação controlada por difusão de ingredientes alimentícios produzidos através da secagem por atomização: revisão. Braz J Food Tech 21: e2017083..

The animals were housed in boxes of 2-m² in a bed of wood and fed ad libitum according to Table I (Rostagno et al. 2017ROSTAGNO HS, ALBINO LFT, HANNAS MI, DONZELE JL, SAKOMURA NK, PERAZZO FG, SARAIVA A, TEIXEIRA ML, RODRIGUES PB, OLIVEIRA RF, BARRETO SLT & BRITO CO. 2017. Tabelas brasileiras para aves e suínos: composição de alimentos e exigências nutricionais. 4a ed., Viçosa: UFV, 488 p.) in tubular feeders and water supply via nipple, pens were equipped with infrared heaters to maintain thermal comfort, connected to a thermostat, with all management recommendations being according to the norms and indications of commercial farms and of the strain manuals. To simulate a sanitary challenge, 25 g/liter of aviary reused bed broilers was supplied via drinking water on the third and fourth day of age, being the only source of drinking water provided in the period.

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Table I
Ingredients and nutritional composition of the experimental diets.

Performance, carcass and organ evaluation

Evaluation of live weight, weight gain, feed intake and feed conversion were obtained by weighing all birds and residual feed at 7, 28 and 41 days of the experiment. The productive efficiency index (PEI) was calculated according to the following formula: ((live weight x viability) / (feed conversion x bird age)) * 10. At 41 days of age, after 12 hours of fasting, two birds per experimental unit were sacrificed by cervical dislocation and were manually bled, according to animal welfare norms and euthanasia norms according to the Conselho Nacional de Experimentação Animal (CONCEA) euthanasia practice guidelines (BRASIL/MCTI 2013BRASIL. 2013. Ministério da Ciência, Tecnologia e Inovação. Diretrizes para a prática de eutanásia do CONCEA. 1a ed., Brasília: MCTI, 54 p.). After slaughter, the birds were scalded, plucked, eviscerated, washed and then the carcasses were weighed to obtain the weight of the hot carcass without having undergone the cooling process in a refrigerator to avoid changes in meat quality. Carcass weighing, organs (liver, heart, ventricle, proventriculus and small intestine), and commercial cuts (breast with bone, leg, thigh, back and wings) were performed, to determine carcass yield and cuts, being calculated as the ratio of their respective weights and body weight, expressed as percentages. For the evaluation, two birds per replication, with average replicate weigh, being weighed individually 12 hours before slaughter and were weighed again after slaughter to determine carcass, cuts and organs yield.

Gut morphometry evaluation

For intestinal villi and crypts evaluation, small intestine fragments were collected for intestinal histological analysis (Labiocel 2002LABIOCEL - LABORATÓRIO DE BIOLOGIA CELULAR DA FACULDADE DE MEDICINA DA UNIVERSIDADE FEDERAL DE SÃO PAULO. 2002. Manual de técnicas em histologia e biologia celular do laboratório de biologia celular da faculdade de medicina da Universidade de São Paulo. 1a ed., São Paulo: Labiocel, 89 p.). The collected intestinal samples were embedded in paraffin and sectioned between 4 and 6 μm using a microtome and fixed on histological slides. The slides were stained using a hematoxylin technique for further analysis using Imagepro Plus 1.3.2 (1994) (40x magnification) under an optical microscope. For each slide, 30 villi and 30 crypts were selected and measured to obtain the mean value of each segment. For the evaluation of the villus/crypt ratio, the value of the height of intestinal villi was divided by the depth value of the adjacent crypt.

Meat quality

After slaughter (approximately 30 minutes), pH evaluations were performed to obtain the initial pH and after rigor mortis to obtain the final pH, in the breast muscle at three points through direct insertion of an electrode (Hanna model HI99163). Meat quality parameters were also determined, including color (lightness L*, intensity of red (a*) and intensity of yellow (b*)), water retention capacity (WRC), cooking losses (CL), shear force (SF), lipid oxidation, moisture content, mineral matter (MM), crude protein (CP) and total lipids. After determination of pH, the breasts were dissected (removed from the bone) to determine the coloration of the breast muscle using a Minolta Chroma Meter CR-300 colorimeter (Minolta Camera Co. Ltd., Osaka, Japan), previously calibrated, with readings in triplicate. The results were expressed in three dimensions, L* (lightness), a* (intensity of red), and b* (intensity of yellow).

Water retention capacity (WRC) was determined as described by Hamm (1960)HAMM R. 1960. Biochemistry of meat hydration. Advan Food Res Ac P 10: 355-463., using approximately 2.0 grams of boned breast. Cooking losses (CL) were determined as recommended by Honikel (1998)HONIKEL KO. 1998. Reference methods for the assessment of physical characteristics of meat. Meat Sci 49: 447-457.. The evaluation of the shear force (SF) of the meat was carried out using a texturometer (TA-XT.plus), which samples of five replicates being obtained from each treatment and cut into cubes of 1.5 x 1.5 cm each and placed with the fibers perpendicular to a Warner-Bratzler Shear Force blade, to evaluate the shear force of the sample, operating at 30 cm/min and measuring the maximum shear force, expressed as kgf.

For the evaluation of lipid oxidation, 5 grams of chicken breast meat samples were used; 25 ml of 7.5% trichloroacetic acid were added, homogenizations were carried out for 2 minutes, 5 ml of the filtrate were pipetted and transferred to test tubes with 5 ml of 0.02 M thiobarbituric acid solution. The tubes were capped and brought to boiling temperature in a water bath for 40 minutes. After this period, they were cooled in running water and read at absorbance 538 nm. To determine the centesimal composition of the meat, after obtaining the weight of the wet and frozen samples, they were lyophilized (LS 3000, Terroni) for 72 hours at -40°C under vacuum. Subsequently, the samples were again weighed to obtain dry weight and then samples were ground. The residual moisture content was removed by oven drying at 105°C for at least 8 hours and ash was obtained by incineration in a muffle at 600°C for 4 hours (Silva & Queiroz 2009SILVA DJ & QUEIROZ AC. 2009. Análise de alimentos: métodos químicos e biológicos. 3a ed., Viçosa: UFV, 235 p.). To determine quantities of meat protein, we used the methodology of the Association of Official Analysis Chemists (AOAC 2016AOAC - ASSOSSIATION OF OFICIAL ANALYTICAL CHEMISTS. 2016. Official methods of analysis. 20th ed., Arlington: Association of Official Analytical Chemists, 3172 p.) and values were expressed as natural matter. To quantify total lipid content of the meat, we used the extraction method of Bligh-Dyer (1959)BLIGH EG & DYER WJ. 1959. A rapid method of total lipid extraction and purification. Can J Biochem Phys 37: 911-917..

Statistical analysis

All variables were subjected to the normality test (Shapiro–Wilk), the variables that did not have a normal distribution were transformed into logarithms. All data were subjected to analysis of variance (ANOVA) and in cases of significant difference, means were subjected to the Tukey test at p<0.05 of significance, using the statistical platform R.

RESULTS

Zootechnical performance

Birds fed PC diet presented higher LW and WG (p<0.05) when compared to birds received 100, 200 and 400 mg/kg of essential oils and birds fed NC diet in 1 - 7-day old phase (Table II). Chickens fed diet containing essential oils, in all doses evaluated, showed same performance when compared to birds consuming the NC diet. No differences were observed (p>0.05) on FI and FC in 1-7 day-period. At 1 to 28 and 1 to 41 days of age, birds showed different performance (p<0.05) for LW, WG, FI, FC and PEI parameters, which birds fed NC diet showed lower performance when compared to birds fed PC diet and birds consuming diets containing essential oils. Were also observed birds fed essential oils obtained same performance as PC birds.

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Table II
Effects of inclusion of carvacrol and cinnamaldehyde in diets of broiler chickens on live weight (LW), weight gain (WG), feed intake (FI), feed gain ratio (FGR) and productive efficiency index (IPE).

Organ, carcass and commercial cuts yield

Data analyzed for small intestine (SI), ventricle, proventriculus, liver and heart relative weight (Table III) and for carcass yield (CR) and commercial cuts of breast, thigh, overcoat, wing and back (Table IV), showed no alterations (p>0.05) on these parameters. No alterations were found (p>0.05) between broilers fed NC, PC or NC supplemented essential oils diets.

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Table III
Effect of inclusion of carvacrol and cinnamaldehyde in broiler diets on the relative weight (%) of the small intestine (SI), ventricle, proventriculus, liver and heart compared to live weight expressed as a percentage.

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Table IV
Effects of inclusion of carvacrol and cinnamaldehyde on carcass yield (CY) and commercial cuts (breast, leg, thigh, wing and back) of broiler chickens expressed as percentages.

Gut morphometry

Results showed in Table V demonstrated no difference (p>0.05) of villus height or crypt depth among broilers fed all different diets. The villus/crypt ratio differed (p<0.05), which birds received NC diet presented smaller villus/crypt ratios than those who received PC diets. The villus/crypt ratio of the birds receiving essential oils did not differ from PC and NC birds.

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Table V
Effect of the inclusion of carvacrol and cinnamaldehyde in broilers diets on villus height, crypt depth and villus/crypt ratios.

Broiler meat quality

As demonstrated in Table VI, no alteration were found in broiler meat (p>0.05) fed all diets on water cooking losses (WCL), Shear Force (SF) and lipid oxidation or reaction to thiobarbituric acid (TBARS). For water retention capacity (WRC) in chicken breasts, there was a reduction (p<0.05) on meat of broilers fed CN+100 diet when compared to birds fed CN, CN+200 and CN+400 diets. The nutritional composition of broiler chicks (crude protein, lipids, moisture and mineral matter) under different treatments (Table VI) showed no alterations (p>0.05) on fat, moisture and mineral matter among groups. However, crude protein meat levels showed differences (p<0.05) which meat of broilers fed NC and NC+400 diets showed higher CP content than broilers fed PC diet. Data obtained for lightness (L*), intensity of red (a*) and intensity of yellow (b*) are presented in Table VI, having no difference (p>0.05) for lightness and intensity of red parameters, however, the intensity of yellow was higher (p<0.05) in PC and NC+100 groups than NC and NC+400 broiler groups. The initial and final pH evaluation were not affected (p>0.05) by the treatments tested.

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Table VI
Effect of inclusion of carvacrol and cinnamaldehyde in diets on broiler meat quality and nutritional content.

DISCUSSION

Inclusion of essential oils improved performance of birds when we compared broilers consuming NC diet, and essential oils may substitute for growth-promoting antibiotics without loss of performance. As substitutes for antibiotic-based growth promoters, carvacrol and cinnamaldehyde have been analyzed in several studies (Petrolli et al. 2012PETROLLI TG, ALBINO LFT, ROSTAGNO HS, GOMES PC, TAVERNARI FC & BALBINO EM. 2012. Herbal extracts in diets for broilers. Rev Bras Zootec 41: 1683-1690., Alarcon 2017, Reis et al. 2018REIS JH ET AL. 2018. Effects of phytogenic feed additive based on thymol, carvacrol and cinnamic aldehyde on body weight, blood parameters and environmental bacteria in broilers chickens. Microb pathogen 125: 168-176., Galli et al. 2020GALLI GM ET AL. 2020. Combination of herbal components (curcumin, carvacrol, thymol, cinnamaldehyde) in broiler chicken feed: Impacts on response parameters, performance, fatty acid profiles, meat quality and control of coccidia and bacteria. Microb pathog 139: e103916.), yielding conflicting results. The live weight and weight gain in the first phase evaluated (1 to 7 days) presented in Table III, demonstrated 100 mg/kg essential oils inclusion improved the indices compared to the NC treatment and the levels of greater inclusion of essential oils. The performance of the birds that received 100 mg/kg of essential oils was equal to the performance of the birds that received the PC diet, an equivalence also found by Alarcon et al. (2017)ALARCON MFF, TROTTIER N, STEIBEL JP, LUNEDO R, CAMPOS DMB, SANTANA AM, PIZAURO JÚNIOR JM, FURLAN RL & FURLAN LR. 2017. Interference of age and supplementation of direct-fed microbial and essential oil in the activity of digestive enzymes and expression of genes related to transport and digestion of carbohydrates and proteins in the small intestine of broilers. Poult sci 96: 2920-2930.. The lower bird performance of that received greater inclusion of essential oils can be explained by the possible irritability of the intestinal mucosa of the birds, with reduction of the intestinal surface and consequent lower absorptive area, according to the hypothesis of Windisch et al. (2009)WINDISCH W, ROHRER E & SCHEDLE K. 2009. Phytogenic feed additives to young piglets and poultry: Mechanisms and application. In: Phytogenics in animal nutrition: natural concepts to optimize gut health and performance. Nottingham: Nottingham University Press, 1st ed., p. 19-38..

In LW, WG, FI and FC evaluation, there was influence of the essential oil blend inclusion in the phases 1 to 35 and 1 to 41 days of age when compared to the birds that received the NC diet in the same periods. Birds supplemented with NC+100, NC+200 and NC+400 obtained an equivalent performance to the PC diet birds. These results confirm the beneficial action of essential oils on improving performance, as substitutes for growth promoters, corroborating the results found of Petrolli et al. (2012)PETROLLI TG, ALBINO LFT, ROSTAGNO HS, GOMES PC, TAVERNARI FC & BALBINO EM. 2012. Herbal extracts in diets for broilers. Rev Bras Zootec 41: 1683-1690. and Reis et al. (2018)REIS JH ET AL. 2018. Effects of phytogenic feed additive based on thymol, carvacrol and cinnamic aldehyde on body weight, blood parameters and environmental bacteria in broilers chickens. Microb pathogen 125: 168-176..

In the present study, essential oil blend presented satisfactory results in the substitution of the growth promoters for the indices mentioned in Table III, without performance reduction compared to the birds receiving diets containing growth promoters during the 1- to 41-day phase. The explanation for this equivalence of zootechnical performance between the birds that received the essential oil blend and the birds that received growth promoter is explained by the equilibrium of the intestinal microbiota of the birds by essential oils, as found by Reis et al. (2018)REIS JH ET AL. 2018. Effects of phytogenic feed additive based on thymol, carvacrol and cinnamic aldehyde on body weight, blood parameters and environmental bacteria in broilers chickens. Microb pathogen 125: 168-176. and Galli et al. (2020)GALLI GM ET AL. 2020. Combination of herbal components (curcumin, carvacrol, thymol, cinnamaldehyde) in broiler chicken feed: Impacts on response parameters, performance, fatty acid profiles, meat quality and control of coccidia and bacteria. Microb pathog 139: e103916., giving better intestinal mucosa development, stimulation of the enzymatic secretion and better nutrient digestion and absorption. Our results agree with those of Petrolli et al. (2012)PETROLLI TG, ALBINO LFT, ROSTAGNO HS, GOMES PC, TAVERNARI FC & BALBINO EM. 2012. Herbal extracts in diets for broilers. Rev Bras Zootec 41: 1683-1690. who evaluated the same parameters at 1 to 41 days of age with the inclusion of essential oils and demonstrated the same efficiencies with the substitute growth promoters.

PEI is an index used by commercial meat producers to generate value for the integrated producers in agroindustry. This evaluation is a general summary of flock development, being an integration of body weight, viability, age of birds and feed conversion. The PEI is an important tool of analysis for the use of the essential oil blend as a substitute growth promoter. In the present study, the PEI demonstrated that essential oils could indeed serve as substitutes for antibiotic-based growth promoters; the results were similar to those obtained by the birds that received the PC diet, and in both diets the birds obtained better results than birds consuming NC diets. The results obtained in this study are in accordance with those found by Petrolli et al. (2012)PETROLLI TG, ALBINO LFT, ROSTAGNO HS, GOMES PC, TAVERNARI FC & BALBINO EM. 2012. Herbal extracts in diets for broilers. Rev Bras Zootec 41: 1683-1690. for the evaluation of PEI, where the diets with essential oils showed similar indexes as those consuming positive control diets, both being superior to indexes generated by the negative control diet, reinforcing the hypothesis that essential oils may be used as substitute growth promoters.

Health challenges in non-ruminant production systems mainly involve the digestive tract, including villus height, crypt depth, and villus/crypt ratio. In the present study, villus height and crypt depth were not influenced by the various types of diets. Greater villus height correlates with greater absorptive area will in the intestinal mucosa, as described by Galli et al. (2020)GALLI GM ET AL. 2020. Combination of herbal components (curcumin, carvacrol, thymol, cinnamaldehyde) in broiler chicken feed: Impacts on response parameters, performance, fatty acid profiles, meat quality and control of coccidia and bacteria. Microb pathog 139: e103916., with consequent better nutrient absorption and rates of zootechnical performance, including weight gain and feed conversion. We observed differences in villus/crypt ratios, where the birds that received the PC, NC+100, NC+200 and NC+400 diets had better LW and FC performance than birds consuming the NC diet. Infectious intestinal agents cause destruction at the level of the small intestine, decreasing the size of the villi. By contrast, in the crypts there is an increase in the production of enterocytes in order to increase the cells in the intestinal mucosa. In the present study, there were no enteric challenges of infectious agents, which explains our results.

Considering the influence of the blend of essential oils on the villi and crypt, it was expected that there would be some influence on the small intestine, ventricle, proventriculus, liver and heart organs. In the present study, we did not observe changes in organ and viscera weight of broilers supplemented with essential oils. This fact may be related to the inclusion levels of the essential oils and because the birds did not face major health challenges. Similar results to that found in this study were also found by Bastos-Leite et al. (2016)BASTOS-LEITE SC, ALVES EHA, SOUSA AM, GOULART CC, SANTOS JPM & SILVA JDB. 2016. Ácidos orgânicos e óleos essenciais sobre o desempenho, biometria de órgãos digestivos e reprodutivos de frangas de reposição. Acta Vet Bras 10: 201-207..

Higher carcass yield and meat cuts are the objectives of genetic improvements and animal nutrition, both of which are important for the poultry sector in general. Differences in carcass yields and cuts may be influenced by temperature, nutrition, genetics and hygiene. In our trial, there was no difference for carcass, breast, leg, thigh, wing and dorsum yields. The inclusion of essential oils in broiler diets may improve the deposition of muscle tissue by stimulating pancreatic enzymes, resulting in better digestion of amino acids; therefore, there were expected differences in carcass yields and cuts, which did not occur in the present study. The data found for carcass yields and commercial cuts are similar to those found by Rizzo et al. (2010)RIZZO PV, MENTEM JFM, RACANICCI AMC, TRALDI AB, SILVA CS & PEREIRA PWZ. 2010. Extratos vegetais em dietas para frangos de corte. Rev. Bras. Zootec 39: 801-807. and Zamora et al. (2017)ZAMORA GM, MELÉNDEZ LAD & HUME ME. 2017. Performance, blood parameters, and carcass yield of broiler chickens supplemented with Mexican oregano oil. Rev Bras Zootec 46: 515-520..

Characteristics of meat composition, as well as visual quality, are important to obtain products that are more acceptable to the consumer market. Some quality analyses were carried out to identify the color of the meat, to help prevent inadequate management during transport and slaughter, as well as to identify myopathies that may cause consumers to reject the meat on the basis of appearance. The rates of water cooking losses (WCL), water retention capacity (WRC) and shear force (SF) are related to the meat content indexes. The values obtained from WCL and SF did not show any difference between the treatments, suggesting that the inclusion of carvacrol and cinnamaldehyde in the broiler diet does not affect meat tenderness. Variations in temperature, caloric stress and housing densities affect WCL and SF, on account of altered cellular integrity and increased membrane osmotic activity. In the present study, the birds did not show the variations mentioned above, possibly explaining the non-differentiation of the values obtained. Due to WRC evaluation, there was a difference between the diets, with the inclusion of 100 mg/kg of essential oils in the diet showed lower water retention capacity, suggesting lower yield and lower final quality of the product.

The evaluation of TBARS is an index of lipid peroxidation evaluated through the formation of products from the oxidation reaction, used to determine the degree of tissue damage; increasing in these levels suggest greater damage to cell membranes (Bozkurt et al. 2016BOZKURT M ET AL. 2016. Effect of anticoccidial monensin with oregano essential oil on broilers experimentally challenged with mixed Eimeria spp. Poult Sci 95: 1858-1868.). The inclusion of essential oils did not influence TBARS values. The inclusion of essential oils may have an antioxidant action (Galli et al. 2020GALLI GM ET AL. 2020. Combination of herbal components (curcumin, carvacrol, thymol, cinnamaldehyde) in broiler chicken feed: Impacts on response parameters, performance, fatty acid profiles, meat quality and control of coccidia and bacteria. Microb pathog 139: e103916.), which stimulates the production of the enzymes superoxide dismutase and glutathione S-transferase and catalase (Hashemipour et al. 2013HASHEMIPOUR H, KERMANSHAHI H, GOLIAN A & VELDKAMP T. 2013. Effect of thymol and carvacrol feed supplementation on performance, antioxidant enzyme activities, fatty acid composition, digestive enzyme activities, and immune response in broiler chickens. Poult Sci 92: 2059-2069.), possibly influencing the oxidation rates of meat. The values found in the evaluation of the TBARS may be explained by correct management during the rearing of the broilers. These values are different from those found by Masouri et al. (2015)MASOURI B, SALARI S, KHOSRAVINIA H, TABATABAEI VS & MOHAMMADABADI T. 2015. Effects of dietary Satureja khuzistanica essential oils and α-tocopherol on productive performance, organ weights, blood lipid constituents and antioxidative potential in heat stressed broiler chicks. Eur. Poult Sci 79: 11-14. and Kanani et al. (2017)KANANI PB, DANESHYAR M, ALIAKBARLU J & HAMIAN F. 2017. Effect of dietary turmeric and cinnamon powders on meat quality and lipid peroxidation of broiler chicken under heat stress condition. Vet Res Forum 8: 163-169., who found different TBARS values in broilers fed with essential oils.

The world’s population is increasingly demanding meat with lower percentages of fat, because of heart disease rate increased heart disease rate. The inclusion of the blend of essential oils in the diet of broilers did not interfere with the parameters of fat, moisture and mineral matter in broiler meat at 41 days of age, suggesting that the supply of a source of essential oils in the diet of birds did not affect the deposition of fat in breast meat. Furthermore, we observed that crude protein levels in the meat of the birds that received 400 mg/kg of essential oils and the NC diet were higher than those of the PC treatment, suggesting greater protein synthesis.

The coloration of fresh chicken meat is considered a significant factor in the moment of consumer acquisition of meat (Kuttappan et al. 2012). These authors found, in a study with chicken breasts with three degrees of white stripping, consumers rejection above 50%. The color of the meat is an indicative of meat quality. It may range from pale red to shades of gray. Meat color is related to the type of muscle fibers, myoglobin and hemoglobin in the blood. Both iron-associated substances and those reacting with oxygen may alter the coloration of the meat (Petracci et al. 2015). The inclusion of carvacrol and cinnamaldehyde in broiler diets did not influence the lightness parameters and the redness (a*) of the chicken meat, however, birds received PC, NC+100 and NC+200 mg/kg essential oils differed from the others, presenting higher yellowness b*. This higher value observed breast meat may be explained by the greater body development of the birds that received the PC diet, lower WRC and lower CP, however, this compromises the aesthetic quality of the marketed product (Kuttappan et al. 2013KUTTAPPAN VA, BREWER VB, MAUROMOUSTAKOS A, MCKEE SR, EMMERT JL, MEULLENET JF & OWENS CM. 2013. Estimation of factors associated with the occurence of white striping in broiler breast fillets. Poult Sci 92: 811-819.), and may also be related to a myopathy called white striping.

The pH evaluation is used as parameter of meat quality, with pH 5.8 to 5.9 considered normal at six hours after the slaughter. In chicken meat is used to indicate meat quality, and six-hour post-mortem chicken meat should have pH between 5.8 to 5.9 (Petracci et al. 2015PETRACCI M, MUDALAL S, SOGLIA F & CAVANI C. 2015. Meat quality in fast-growing broiler chickens. Worlds Poult Sci 71: 363-374.). In the present study (Table VI) the values obtained for pH were between 5.84 and 5.98 at four hours after slaughter, explaining the values slightly above the desired parameters. pH values after 24 hours of slaughter above 6.2 can be an indicative of DFD (Dark, firm, dry) meat due to the retention of large amounts of water, affecting shelf life. However, values below 5.8 at less than 4 hours after slaughter may indicate poor water retention in addition to the soft and pale appearance, suggesting meat called PSE (pale, soft, exudative) (Guerrero et al. 2013GUERRERO A, VALERO MV, CAMPO MM & SAÑUDO C. 2013. Some factors that affect ruminant meat quality: from the farm to the fork. Acta Sci 4: 335-347).

The inclusion of microencapsulated carvacrol and cinnamaldehyde in broiler diets replaces adequately antibiotic growth promoters, maintaining performance, carcass and commercial cuts yield. Additionally, ensures broiler intestinal morphometry and chicken meat quality parameters up to 41 days of age.

ACKNOWLEGMENTS

We would like to thank Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), for scholarship providing. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001.

REFERENCES

ALARCON MFF, TROTTIER N, STEIBEL JP, LUNEDO R, CAMPOS DMB, SANTANA AM, PIZAURO JÚNIOR JM, FURLAN RL & FURLAN LR. 2017. Interference of age and supplementation of direct-fed microbial and essential oil in the activity of digestive enzymes and expression of genes related to transport and digestion of carbohydrates and proteins in the small intestine of broilers. Poult sci 96: 2920-2930.
ARIEZA NIETO C, ORTIZ RE & TELLEZ GA. 2018. Effect of two chemotypes of oregano essential oil on broiler performance nutrient balance, and lipid peroxidation of breast meat during storage. Cienc Anim Bras 19: 1-15.
AOAC - ASSOSSIATION OF OFICIAL ANALYTICAL CHEMISTS. 2016. Official methods of analysis. 20th ed., Arlington: Association of Official Analytical Chemists, 3172 p.
BASTOS-LEITE SC, ALVES EHA, SOUSA AM, GOULART CC, SANTOS JPM & SILVA JDB. 2016. Ácidos orgânicos e óleos essenciais sobre o desempenho, biometria de órgãos digestivos e reprodutivos de frangas de reposição. Acta Vet Bras 10: 201-207.
BLIGH EG & DYER WJ. 1959. A rapid method of total lipid extraction and purification. Can J Biochem Phys 37: 911-917.
BRASIL. 2013. Ministério da Ciência, Tecnologia e Inovação. Diretrizes para a prática de eutanásia do CONCEA. 1a ed., Brasília: MCTI, 54 p.
BOZKURT M ET AL. 2016. Effect of anticoccidial monensin with oregano essential oil on broilers experimentally challenged with mixed Eimeria spp. Poult Sci 95: 1858-1868.
DIARRA MM & MALOUIN F. 2014. Antibiotics in Canadian poultry productions and anticipated alternatives. Front Microbiol 5: 1-15.
FAO - FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS. 2017. Cenário da demanda por alimentos [Online]. Disponível em: http://www.fao.org/brasil/noticias/detail-events/en/c/901168/ Acessado em: 12 ago 2018.
» http://www.fao.org/brasil/noticias/detail-events/en/c/901168/
GALLI GM ET AL. 2020. Combination of herbal components (curcumin, carvacrol, thymol, cinnamaldehyde) in broiler chicken feed: Impacts on response parameters, performance, fatty acid profiles, meat quality and control of coccidia and bacteria. Microb pathog 139: e103916.
GUERRERO A, VALERO MV, CAMPO MM & SAÑUDO C. 2013. Some factors that affect ruminant meat quality: from the farm to the fork. Acta Sci 4: 335-347
HAMM R. 1960. Biochemistry of meat hydration. Advan Food Res Ac P 10: 355-463.
HASHEMIPOUR H, KERMANSHAHI H, GOLIAN A & VELDKAMP T. 2013. Effect of thymol and carvacrol feed supplementation on performance, antioxidant enzyme activities, fatty acid composition, digestive enzyme activities, and immune response in broiler chickens. Poult Sci 92: 2059-2069.
HONIKEL KO. 1998. Reference methods for the assessment of physical characteristics of meat. Meat Sci 49: 447-457.
KANANI PB, DANESHYAR M, ALIAKBARLU J & HAMIAN F. 2017. Effect of dietary turmeric and cinnamon powders on meat quality and lipid peroxidation of broiler chicken under heat stress condition. Vet Res Forum 8: 163-169.
KUTTAPPAN VA, BREWER VB, MAUROMOUSTAKOS A, MCKEE SR, EMMERT JL, MEULLENET JF & OWENS CM. 2013. Estimation of factors associated with the occurence of white striping in broiler breast fillets. Poult Sci 92: 811-819.
KUTTAPPAN VA, LEE YS, ERF GF, MEULLENET JFC, MCKEE SR & OWENS CM. 2012. Consumer acceptance of visual appearance of broiler breast meat with varying degrees of white striping. Poult Sci 91: 1240-1247.
LABIOCEL - LABORATÓRIO DE BIOLOGIA CELULAR DA FACULDADE DE MEDICINA DA UNIVERSIDADE FEDERAL DE SÃO PAULO. 2002. Manual de técnicas em histologia e biologia celular do laboratório de biologia celular da faculdade de medicina da Universidade de São Paulo. 1a ed., São Paulo: Labiocel, 89 p.
LUNA A, LÁBAQUE MC, ZYGADLO AJ & MARIN RH. 2010. Effects of thymol and carvacrol feed supplementation on lipid oxidation in broiler meat. Poult Sci 89: 366-370.
MASOURI B, SALARI S, KHOSRAVINIA H, TABATABAEI VS & MOHAMMADABADI T. 2015. Effects of dietary Satureja khuzistanica essential oils and α-tocopherol on productive performance, organ weights, blood lipid constituents and antioxidative potential in heat stressed broiler chicks. Eur. Poult Sci 79: 11-14.
MURO EM, PELICIA VC, VERCESE F, SOUZA IMGP, PIMENTA GEM, OLIVEIRA RSSG & SARTORI JR. 2015. Aditivos fitogênicos e glutamina mais ácido glutâmico na dieta de frangos desafiados com coccidiose. Rev Agrar 8: 304-311.
PEREIRA KC, FERREIRA DCM, ALVARENGA GF, PEREIRA MSS, BARCELOS MCS & COSTA JMC. 2018. Microencapsulação e liberação controlada por difusão de ingredientes alimentícios produzidos através da secagem por atomização: revisão. Braz J Food Tech 21: e2017083.
PETRACCI M, MUDALAL S, SOGLIA F & CAVANI C. 2015. Meat quality in fast-growing broiler chickens. Worlds Poult Sci 71: 363-374.
PETROLLI TG, ALBINO LFT, ROSTAGNO HS, GOMES PC, TAVERNARI FC & BALBINO EM. 2012. Herbal extracts in diets for broilers. Rev Bras Zootec 41: 1683-1690.
REIS JH ET AL. 2018. Effects of phytogenic feed additive based on thymol, carvacrol and cinnamic aldehyde on body weight, blood parameters and environmental bacteria in broilers chickens. Microb pathogen 125: 168-176.
RIZZO PV, MENTEM JFM, RACANICCI AMC, TRALDI AB, SILVA CS & PEREIRA PWZ. 2010. Extratos vegetais em dietas para frangos de corte. Rev. Bras. Zootec 39: 801-807.
ROSTAGNO HS, ALBINO LFT, HANNAS MI, DONZELE JL, SAKOMURA NK, PERAZZO FG, SARAIVA A, TEIXEIRA ML, RODRIGUES PB, OLIVEIRA RF, BARRETO SLT & BRITO CO. 2017. Tabelas brasileiras para aves e suínos: composição de alimentos e exigências nutricionais. 4a ed., Viçosa: UFV, 488 p.
SILVA DJ & QUEIROZ AC. 2009. Análise de alimentos: métodos químicos e biológicos. 3a ed., Viçosa: UFV, 235 p.
SUNTRES ZE, COCCIMIGLIO J & ALIPOUR M. 2015. The bioactivity and toxicological actions of carvacrol. Crit. Rev Food Sci Nutr 55: 304-318.
WINDISCH W, ROHRER E & SCHEDLE K. 2009. Phytogenic feed additives to young piglets and poultry: Mechanisms and application. In: Phytogenics in animal nutrition: natural concepts to optimize gut health and performance. Nottingham: Nottingham University Press, 1st ed., p. 19-38.
ZAMORA GM, MELÉNDEZ LAD & HUME ME. 2017. Performance, blood parameters, and carcass yield of broiler chickens supplemented with Mexican oregano oil. Rev Bras Zootec 46: 515-520.
ZHAI H, LIU H, WANG S, WU J & KLUENTER AM. 2018. Potential of essential oils for poultry and pigs. Anim Nutr 4: 179-186.
ZENG Z, ZHANG S, WANG H & PIAO X. 2015. Essential oil and aromatic plants as feed additives in non-ruminant nutrition: a review. J Anim Sci Biotechnol 6: 1-10.

Publication Dates

Publication in this collection
11 Dec 2020
Date of issue
2020

History

Received
17 Mar 2020
Accepted
28 July 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ALARCON MFF, TROTTIER N, STEIBEL JP, LUNEDO R, CAMPOS DMB, SANTANA AM, PIZAURO JÚNIOR JM, FURLAN RL & FURLAN LR. 2017. Interference of age and supplementation of direct-fed microbial and essential oil in the activity of digestive enzymes and expression of genes related to transport and digestion of carbohydrates and proteins in the small intestine of broilers. Poult sci 96: 2920-2930.

[2] ARIEZA NIETO C, ORTIZ RE & TELLEZ GA. 2018. Effect of two chemotypes of oregano essential oil on broiler performance nutrient balance, and lipid peroxidation of breast meat during storage. Cienc Anim Bras 19: 1-15.

[3] AOAC - ASSOSSIATION OF OFICIAL ANALYTICAL CHEMISTS. 2016. Official methods of analysis. 20th ed., Arlington: Association of Official Analytical Chemists, 3172 p.

[4] BASTOS-LEITE SC, ALVES EHA, SOUSA AM, GOULART CC, SANTOS JPM & SILVA JDB. 2016. Ácidos orgânicos e óleos essenciais sobre o desempenho, biometria de órgãos digestivos e reprodutivos de frangas de reposição. Acta Vet Bras 10: 201-207.

[5] BLIGH EG & DYER WJ. 1959. A rapid method of total lipid extraction and purification. Can J Biochem Phys 37: 911-917.

[6] BRASIL. 2013. Ministério da Ciência, Tecnologia e Inovação. Diretrizes para a prática de eutanásia do CONCEA. 1a ed., Brasília: MCTI, 54 p.

[7] BOZKURT M ET AL. 2016. Effect of anticoccidial monensin with oregano essential oil on broilers experimentally challenged with mixed Eimeria spp. Poult Sci 95: 1858-1868.

[8] DIARRA MM & MALOUIN F. 2014. Antibiotics in Canadian poultry productions and anticipated alternatives. Front Microbiol 5: 1-15.

[9] FAO - FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS. 2017. Cenário da demanda por alimentos [Online]. Disponível em: http://www.fao.org/brasil/noticias/detail-events/en/c/901168/ Acessado em: 12 ago 2018.
» http://www.fao.org/brasil/noticias/detail-events/en/c/901168/

[10] GALLI GM ET AL. 2020. Combination of herbal components (curcumin, carvacrol, thymol, cinnamaldehyde) in broiler chicken feed: Impacts on response parameters, performance, fatty acid profiles, meat quality and control of coccidia and bacteria. Microb pathog 139: e103916.

[11] GUERRERO A, VALERO MV, CAMPO MM & SAÑUDO C. 2013. Some factors that affect ruminant meat quality: from the farm to the fork. Acta Sci 4: 335-347

[12] HAMM R. 1960. Biochemistry of meat hydration. Advan Food Res Ac P 10: 355-463.

[13] HASHEMIPOUR H, KERMANSHAHI H, GOLIAN A & VELDKAMP T. 2013. Effect of thymol and carvacrol feed supplementation on performance, antioxidant enzyme activities, fatty acid composition, digestive enzyme activities, and immune response in broiler chickens. Poult Sci 92: 2059-2069.

[14] HONIKEL KO. 1998. Reference methods for the assessment of physical characteristics of meat. Meat Sci 49: 447-457.

[15] KANANI PB, DANESHYAR M, ALIAKBARLU J & HAMIAN F. 2017. Effect of dietary turmeric and cinnamon powders on meat quality and lipid peroxidation of broiler chicken under heat stress condition. Vet Res Forum 8: 163-169.

[16] KUTTAPPAN VA, BREWER VB, MAUROMOUSTAKOS A, MCKEE SR, EMMERT JL, MEULLENET JF & OWENS CM. 2013. Estimation of factors associated with the occurence of white striping in broiler breast fillets. Poult Sci 92: 811-819.

[17] KUTTAPPAN VA, LEE YS, ERF GF, MEULLENET JFC, MCKEE SR & OWENS CM. 2012. Consumer acceptance of visual appearance of broiler breast meat with varying degrees of white striping. Poult Sci 91: 1240-1247.

[18] LABIOCEL - LABORATÓRIO DE BIOLOGIA CELULAR DA FACULDADE DE MEDICINA DA UNIVERSIDADE FEDERAL DE SÃO PAULO. 2002. Manual de técnicas em histologia e biologia celular do laboratório de biologia celular da faculdade de medicina da Universidade de São Paulo. 1a ed., São Paulo: Labiocel, 89 p.

[19] LUNA A, LÁBAQUE MC, ZYGADLO AJ & MARIN RH. 2010. Effects of thymol and carvacrol feed supplementation on lipid oxidation in broiler meat. Poult Sci 89: 366-370.

[20] MASOURI B, SALARI S, KHOSRAVINIA H, TABATABAEI VS & MOHAMMADABADI T. 2015. Effects of dietary Satureja khuzistanica essential oils and α-tocopherol on productive performance, organ weights, blood lipid constituents and antioxidative potential in heat stressed broiler chicks. Eur. Poult Sci 79: 11-14.

[21] MURO EM, PELICIA VC, VERCESE F, SOUZA IMGP, PIMENTA GEM, OLIVEIRA RSSG & SARTORI JR. 2015. Aditivos fitogênicos e glutamina mais ácido glutâmico na dieta de frangos desafiados com coccidiose. Rev Agrar 8: 304-311.

[22] PEREIRA KC, FERREIRA DCM, ALVARENGA GF, PEREIRA MSS, BARCELOS MCS & COSTA JMC. 2018. Microencapsulação e liberação controlada por difusão de ingredientes alimentícios produzidos através da secagem por atomização: revisão. Braz J Food Tech 21: e2017083.

[23] PETRACCI M, MUDALAL S, SOGLIA F & CAVANI C. 2015. Meat quality in fast-growing broiler chickens. Worlds Poult Sci 71: 363-374.

[24] PETROLLI TG, ALBINO LFT, ROSTAGNO HS, GOMES PC, TAVERNARI FC & BALBINO EM. 2012. Herbal extracts in diets for broilers. Rev Bras Zootec 41: 1683-1690.

[25] REIS JH ET AL. 2018. Effects of phytogenic feed additive based on thymol, carvacrol and cinnamic aldehyde on body weight, blood parameters and environmental bacteria in broilers chickens. Microb pathogen 125: 168-176.

[26] RIZZO PV, MENTEM JFM, RACANICCI AMC, TRALDI AB, SILVA CS & PEREIRA PWZ. 2010. Extratos vegetais em dietas para frangos de corte. Rev. Bras. Zootec 39: 801-807.

[27] ROSTAGNO HS, ALBINO LFT, HANNAS MI, DONZELE JL, SAKOMURA NK, PERAZZO FG, SARAIVA A, TEIXEIRA ML, RODRIGUES PB, OLIVEIRA RF, BARRETO SLT & BRITO CO. 2017. Tabelas brasileiras para aves e suínos: composição de alimentos e exigências nutricionais. 4a ed., Viçosa: UFV, 488 p.

[28] SILVA DJ & QUEIROZ AC. 2009. Análise de alimentos: métodos químicos e biológicos. 3a ed., Viçosa: UFV, 235 p.

[29] SUNTRES ZE, COCCIMIGLIO J & ALIPOUR M. 2015. The bioactivity and toxicological actions of carvacrol. Crit. Rev Food Sci Nutr 55: 304-318.

[30] WINDISCH W, ROHRER E & SCHEDLE K. 2009. Phytogenic feed additives to young piglets and poultry: Mechanisms and application. In: Phytogenics in animal nutrition: natural concepts to optimize gut health and performance. Nottingham: Nottingham University Press, 1st ed., p. 19-38.

[31] ZAMORA GM, MELÉNDEZ LAD & HUME ME. 2017. Performance, blood parameters, and carcass yield of broiler chickens supplemented with Mexican oregano oil. Rev Bras Zootec 46: 515-520.

[32] ZHAI H, LIU H, WANG S, WU J & KLUENTER AM. 2018. Potential of essential oils for poultry and pigs. Anim Nutr 4: 179-186.

[33] ZENG Z, ZHANG S, WANG H & PIAO X. 2015. Essential oil and aromatic plants as feed additives in non-ruminant nutrition: a review. J Anim Sci Biotechnol 6: 1-10.

Ingredient (kg/ton)	Initial (1-21 days)	Final (22-41 days)
Corn	544	578.66
Soybean meal (46%)	361.65	309
Soybean oil	27.79	44.89
Dicalcium phosphate	18.3	18.64
Limestone	8.25	8.41
Salt	3.25	3.32
DL-Methionine (99%)	2.6	3.11
L-Lysine HCl	2.25	1.94
Choline chloride (60%)	1.0	1.0
Supplemental vitamins¹	15	15.0
Supplemental minerals²	15	15.0
Calculated values
Metabolic energy (kcal/kg)	2950	3100
Crude protein (g/kg)	215.00	194.00
Lysine dig. (g/kg)	12.00	10.50
Methionine dig. (g/kg)	5.44	5.05
Met. + Cys. dig. (g/kg)	8.39	7.75
Threonine dig. (g/kg)	7.55	6.84
Tryptophan dig. (g/kg)	2.46	2.13
Arginine dig. (g/kg)	14.14	12.27
Valine dig. (g/kg)	9.25	8.20
Calcium (g/kg)	9.02	8.24
Available phosphate (g/kg)	4.51	4.10
Sodium, g/kg	1.70	2.05
Potassium, g/kg	8.49	7.46
Chloride, g/kg	3.77	3.56

		Treatments
		NC	PC	NC+100	NC+200	NC+400	P-value	CV (%)
1 to 7 days	LW (g)	136 b	147 a	140 ab	137 b	138 b	0.004	3.88
	WG (g)	89 b	100 a	93 ab	90 b	91 b	0.008	6.62
	FI (g)	135	139	134	133	135	0.669	7.26
	FGR (g)	1.506	1.391	1.440	1.475	1.489	0.535	9.61

1 to 28 days	LW (g)	1110 b	1229 a	1196 a	1176 a	1201 a	0.000	3.13
	WG (g)	1062 b	1182 a	1148 a	1129 a	1153 a	0.000	3.62
	FI (g)	1595 b	1658 a	1645 ab	1632 ab	1675 a	0.000	2.13
	FGR (g)	1504 a	1402 b	1432 b	1446 ab	1453 ab	0.003	3.35

1 to 41 days	LW (g)	2089 b	2309 a	2265 a	2245 a	2279 a	0.000	3.59
	WG (g)	2040 b	2262 a	2217 a	2198 a	2231 a	0.000	3.60
	FI (g)	3340 b	3513 a	3513 a	3502 a	3513 a	0.001	2.61
	FGR (g)	1.636 a	1.553 b	1.584 b	1.593 b	1.575 b	0.000	1.57
	IPE	308 b	362 a	343 a	341 a	350 a	0.000	6.25

		Treatments
	NC	PC	NC+100	NC+200	NC+400	P-value	CV (%)
SI	2.62	2.41	2.63	2.55	2.50	0.113	10.27
Ventricle	1.80	1.78	1.83	1.59	1.91	0.064	13.28
Proventriculus	0.48	0.43	0.44	0.43	0.43	0.084	14.49
Liver	2.06	2.05	2.11	2.15	2.05	0.534	9.78
Heart	0.50	0.46	0.48	0.49	0.47	0.337	14.20

	Treatments
	NC	PC	NC+100	NC+200	NC+400	P-value	CV (%)
CY	73.86	74.74	73.87	74.48	73.98	0.424	1.88
Breast	33.91	34.24	33.48	34.61	34.07	0.764	7.03
Leg	12.84	12.60	12.50	12.47	12.66	0.811	7.33
Thigh	14.60	14.58	14.74	14.57	14.75	0.989	9.00
Wing	11.08	10.95	11.42	10.68	11.09	0.300	8.65
Back	26.94	25.49	26.32	26.11	26.14	0.445	8.20

	Treatments
	NC	PC	NC+100	NC+200	NC+400	P-value	CV (%)
Villus height (µm)	389	442	372	424	433	0.2271	15.36
Crypt depth (µm)	73.23	61.76	60.80	62.20	65.07	0.0615	12.95
Villus/crypt ratio	5.35c	7.15a	6.06bc	6.84ab	6.70ab	0.0001	10.00

	Treatments
	NC	PC	NC+100	NC+200	NC+400	P-value	CV (%)
WCL (%)	13.54	12.10	13.00	12.66	11.31	0.651	19.99
WRC (%)	79.13^a	74.11^ab	71.39^b	78.09^a	78.78^a	0.000	4.12
SF kgf/cm²	3.535	3.088	2.434	3.158	3.382	0.128	21.70
TBARS TMP/kg	9.492	9.203	9.560	10.105	9.781	0.440	7.91
CP (%)	26.886^a	25.745^b	26.418^ab	25.918^ab	26.788^a	0.013	2.02
Fat (%)	2.464	1.657	2.210	1.670	2.678	0.136	32.97
Moisture (%)	63.338	63.422	61.206	60.844	60.336	0.173	3.93
MM (%)	4.618	4.142	4.902	4.408	4.670	0.716	19.33
L*	50.18	50.53	53.42	51.01	49.54	0.173	4.90
a*	2.320	2.897	2.632	2.857	2.824	0.453	18.17
b*	3.416^b	6.448^a	6.442^a	5.192^ab	3.700^b	0.004	27.91
Initial pH	6.14	6.12	6.12	6.18	6.07	0.893	3.11
Final pH	5.90	5.94	5.84	5.87	5.98	0.262	1.80