Physico-chemical characteristics of meat after dietary supplementation of lambs with essential oils and calcium malate

 

 

M.A. Ortiz-Heredia^I; J.R. Bárcena-Gama^{I, #}; P.A. Martínez-Hernández^II; J de D. Guerrero-Rodriguez^I; S.S. González-Munoz^I; O.V. Vázquez-Mendoza^III

^IPosgrado en Ganadería, Colegio de Postgraduados Campus Montecillo, Texcoco, México, 56230
^IIPosgrado en Producción Animal, Universidad Autónoma Chapingo, Chapingo, México, 56230
^IIIFacultad de Medicina Veterinaria y Zootecnia, Universidad Autónoma del Estado de México, 50295

 

 

---

ABSTRACT

The objective of this study was to determine the effect of a mixture of essential oils (EO), calcium malate (CM), or their combination (EO + CM) on the physico-chemical characteristics of lamb meat. A total of 36, two-month-old, 20 ± 3 kg live weight, male lambs were allocated to individual cages and randomly distributed into four treatment groups: 1, basal diet (BD); 2, BD + 150 g of EO ton^-1; 3, BD + 2.5 kg of CM ton^-1; and 4: BD + 150 g EO + 2.5 kg CM ton^-1. Feed and fresh water were available ad libitum to the lambs during the 56-day experiment. There was no difference in the chemical composition of the lamb meat although collagen was higher in the EO + CM treatment. The percentage of omega-3 and eicosapentaenoic acid was higher in the OE + CM group, but there were no differences in the total percentage of saturated or unsaturated fatty acids. The shear strength of raw meat was higher in the BD group, but the shear strength of cooked meat was lower in the EO group than in the BD or CM groups. There was no difference in water retention in raw meat or in water loss in cooked meat between groups. The colour of the meat was not affected by treatment. The EO and EO + CM groups had an increase in meat tenderness and the concentration of some unsaturated fatty acids, but this did not affect the colour or chemical composition of the lamb meat.

Keywords: chemical composition, fatty acids, meat colour, tenderness

---

 

 

Introduction

The demand for animal protein will increase as the world population increases, which is projected to exceed nine billion by 2050. Meat consumption in developed countries has become reduced out of consideration for human health and the environment, but in developing countries, such as China, India, Russia, Mexico, and Brazil, the population with higher incomes seeks to acquire more and better products for consumption, such as meat, milk, and cheese (Chriki and Hocquette, 2020). As the population has greater access to meat consumption, they demand higher quality in terms of colour, flavour, softness, juiciness (Mancini and Hunt, 2005; Garmyn, 2020) and nutritional composition, mainly in the amount of saturated fatty acids present in meat that can affect human health (Junkuszew et al., 2020).

In Mexico, chemical additives, mainly ionophores, are used as modifiers of ruminal fermentation for the finishing of lambs with diets high in concentrate (Castillo et al., 2004). These compounds prevent the appearance of metabolic diseases such as acidosis and can increase the efficiency of dietary utilisation with better feed conversion, weight gain, and carcass yield (Garcia-Galicia et al., 2020). However, consumers prefer cleaner meat, without the excessive use of chemical additives.

Essential oils (EO) and organic acid salts, such as calcium malate, have been studied as substitutes for chemical additives and can be used to preserve ruminal health and improve animal performance (Ortuno et al., 2014; Malekkhahi et al., 2015; Loya-Olguin et al., 2019; García-Galicia et al., 2020; Haro et al., 2020). The published results on the use of EO in the finishing of lambs, regarding the physico-chemical characteristics of the meat, are highly variable. Smeti et al. (2013) observed no effect of rosemary EO on lipid oxidation or meat discolouration but did observe an improved polyunsaturated fatty acid level and acceptability (Smeti et al., 2018). Elsewhere, rosemary extract reduced discolouration and lipid oxidation and improved the shelf life of meat (Ortuno et al., 2014). Garcia-Galicia et al. (2020) reported that oregano oil improved meat tenderness; however, Simitzis et al. (2008) reported no changes in smoothness with oregano oil use. Studies with calcium malate and its effect on meat quality are scarce. Haro et al. (2020) reported an improvement in the colour but not in the chemical composition, pH, or fatty acid profile of the meat. These additives have the potential to modify rumen fermentation when fed to finishing lambs and, thus, modify the chemical composition, colour, tenderness, and unsaturated fatty acid content of the meat. Due to this potential, there is interest in the use of these additives to improve the productive response of animals (Salami et al., 2018), without risks to human health. However, the variability of the results requires that research be intensified to generate more reliable information.

Therefore, the objective of the present study was to determine the effect of calcium malate, a mixture of standardized EO (thymol, carvacrol, eucalyptol, and cinnamaldehyde), and their combination on the physico-chemical characteristics related to the quality of meat from lambs finished with diets high in concentrate.

 

Material and Methods

This research was conducted in accordance with the regulations for the use and care of animals intended for research at the Colegio de Postgraduados, and the Mexican Standard for Animal Care (NOM-062-ZOO-1999).

A total of 36 male lambs (Dorset/Hampshire cross), with an initial live weight (LW) of 20 ± 3 kg at three months of age, were randomly housed in individual indoor pens of 1.50 * 2 m, with a cement floor and a bedding of sawdust, provided with a feeder and drinker. The lambs were dewormed with 1 mL 50 kg^-1 (LW) of subcutaneous Ivermectin (Ivomec F®) and had an adaptation period to the diets of 5 d, and 56 d in finishing. The diets were offered ad íibitum, twice a day, with 60% in the morning (08:00) and the remaining 40% in the afternoon (17:00). The lambs were weighed at the beginning and end of the experimental period.

A basal diet (BD) (Table 1) was formulated for lambs for a daily weight gain of 300 g d^-1 (NRC, 2007). A mixture of essential oils (EO; thymol, carvacrol, eucalyptol, and cinnamaldehyde; Emerald®, Nutryplus, Mexico), calcium malate (CM; Rumalate®, Norel, Mexico) or the combination of these was added to the basal diet. The treatments were: 1) BD; 2) BD + 150 g t^-1 EO; 3) BD + 2.5 kg t^-1 CM and 4) BD + 150 g t^-1 EO + 2.5 kg t^-1 CM.

The lambs were weighed 24 h before slaughter and then slaughtered according to the Mexican Standard for Animal Care (NOM-062-ZOO-1999). The carcasses of the lambs were washed with drinking water and left to ventilate for 2 h. Subsequently, the carcasses were weighed and 7-cm-wide samples of the Longissimus dorsi muscle (300 g) were taken and refrigerated at 4 °C for 24 h to record the post-mortem cold weight. In the Longissimus dorsi samples, pH, temperature, chemical composition, concentration of long-chain fatty acids, water retention capacity, water loss due to cooking, shear strength (cooked and raw meat), and colour were determined.

The pH was measured using a portable potentiometer with automatic temperature compensation (HANNA® instruments, HI 99163, EU), and the temperature was recorded in three different areas of the muscle (Longissimus dorsi) at 0 h and 24 h post-mortem.

The content of fat, moisture, protein, and collagen was determined in the meat using near infrared (NIR) spectroscopy equipment (FoodScan®, Foss, Denmark) in the region of 850-1050 nm, equipped with a calibration of artificial neural networks.

The determination of long-chain fatty acids (FA) in meat was conducted according to the method of Jenkins (2010), with esterification and trans-esterification catalysed by 5% methanolic hydrogen chloride. The prepared meat samples were analysed using gas chromatography (HP6890 gas chromatograph with FID detector, with automatic injector) with a chromatographic column (100 m X 0.25 mm * 0.20 urn; SUPELCO SP-2560). FA were quantified as methyl esters (FAME) (French et al., 2000). The FAME were separated and the amounts of saturated FA (SFA), monounsaturated FA (MUFA), and polyunsaturated FA (PUFA) were determined using gas chromatography. The indices of fatty acids of interest for human health were calculated as:

The water retention capacity (WRC) was determined using the centrifugation method (Leal et al., 2015). Five-gram samples of finely minced meat without fatty tissue were placed in 50 mL centrifuge tubes (Nalgen), homogenised with 8 mL of 0.6 M sodium chloride solution, and refrigerated at 4 °C. Subsequently, they were centrifuged for 15 min at 15,652 * g in a centrifuge (model J2-HS, BECKMAN). The excess was decanted and the final volume was measured using the following equation:

where Vi = initial volume of 0.6M NaCl solution (8 mL); Vs = volume recovered from the supernatant (after centrifugation); and m = sample weight (5 g). The results were reported as the volume of solution (in mL) retained in 100 g of meat.

The amount of water lost during cooking was determined according to the method of Bejerholm and Aaslyng (2004). Fillets of 5 g and 1.5 cm thickness were cut from raw meat after 24 h of maturation and were fried in a pan at 155 °C, turning the meat every 2 min until it reached an internal temperature of 70 °C. Subsequently, the samples were cooled for 15 min at room temperature (20-25 °C) and weighed. The following equation was used to determine the water loss:

where: LWC is the percentage cooking loss; Pi = initial weight of the sample; and Pf = the final weight of the sample.

The shear strength of both raw and cooked meat was measured using the Warner-Bratzler (SFWB) method and was determined in accordance with the provisions of AMSA (1995). The fillets were cooked and then the same methodology described above was used to determine the PPC. Raw and cooked fillets were perforated transversely (parallel to muscle fibres) at three different sites. Shear force was measured using a Warner-Bratzler (WB) cell with a triangular groove cutting edge, mounted on a Salter Model 235 (Warner-Bratzler meat shear, GR manufacturing Co. 1317 Collins LN, Manhattan, Kansas, 66502, USA) associated with a texture meter (TAXT Express Standard, Stable Micro Systems Surrey, UK). This method was used to measure the force required (kg cm^-2) to cut the fillet of meat. The data are expressed in kg force.

Fat tissue was manually removed from each meat sample and three colour measurements were made in different areas at 0, 3, 6, 12, 24, 48, 72, 96, 120, 144, 168 and 192 h post-mortem, using a brand meat colorimeter (Konica Minolta CM-700 d).

A randomised complete block design was used, and all data were analysed using the Shapiro-Wilk test to determine normality. The data on chemical composition, fatty acid profile, shear force, water retention capacity, and meat cooking losses were analysed using the PROC GLM in SAS 9.4, with the type of diet, block (with two experimental units per treatment), inside block, and their interactions as fixed effects. The statistical model was:

where: Yijk = observation k in treatment i and block j; u = the overall mean; n = the effect of treatment, i; pj = the effect of block, j; (Tβ)ij = the interaction effect of treatment i and block j; and £yk = the random error with mean 0 and variance σ².

Meat colour data were analysed with the PROC MIXED tool in SAS 9.4 in a design of measures repeated over time, where the type of diet (TRAT: BD, EO, CM, EO + CM), hours of storage (TIME: 0 to 192 h), and its interaction (TRATxTIME) were considered as fixed effects, while an individual lamb within treatment was considered as a random effect. The covariance structure was compound symmetry. The statistical model was:

where: u = the overall mean; n = the effect of treatment i; tk = the effect of time k; (T*t)ik = the effect of the interaction between treatment i and time k; δ_ij = random error with mean 0 and variance σ² q, the variance between animals (subjects) within treatment, equal to the covariance between repeated measures within animals; and £yk = the random error with mean 0 and variance σ², the variance between measurements within animals. When differences were detected, the comparison of means was performed by Tukey's test considering differences with a = 0.05 and trends when a = 0.1.

 

Results and Discussion

There were no differences in meat moisture, protein, and fat content (P >0.05) between treatments (Table 2). The average values concurred with those reported by Junkuszew et al. (2020), and the absence of effects of EO or CM concurred with those reported by Yagoubi et al. (2018), Smeti et al. (2018), and Rivaroli et al. (2016) in cattle; and by Haro et al. (2020) in lambs. It is likely that the amounts used of the additives were not sufficient to substantially modify ruminal fermentation to affect the rate of fat or muscle protein deposition (Malekkhahi et al., 2015). Collagen is the most abundant protein molecule in the body and maintains the health of the muscles. It is important to determine collagen content as it varies depending on the breed, productive aptitude, precocity, and age of the subject. In animals with a high growth rate, the rate of protein and collagen replacement is high (Rivaroli et al., 2016). In this study, collagen content was lower (P <0.05) in the BD and CM groups than in the EO or EO + CM groups, which may be related to the lower weight gain of lambs supplemented with these same additives (Ortiz et al., 2021).

The pH at 24 h post-mortem was higher than the initial pH (P <0.05) in the meat of the lambs supplemented with EO or EO + CM (Table 2). The final pH values were similar to those reported by Yagoubi et al. (2018), but lower than those reported by Smeti et al. (2018). Post-mortem pH is a highly important parameter in meat quality, since after 24 h, glycogen reserves are depleted and pH stabilizes (Yagoubi et al., 2018). A pH at 24 h post-mortem within 5.5-5.6 is associated with a light colour of the meat and shows an adequate slaughter process, while a pH >5.6 is associated with dark meat, which is common in heavy animals in a state of stress at slaughter with less muscle glycogen stores (Smeti et al., 2018). McGeehin et al. (2001) reported that the most important factors affecting pH at 24 h postmortem were sex, cold carcass weight (R² = 0.80) and, to a lesser extent, age, and environmental temperature. The pH at 24 h post-mortem in the meat of lambs from the EO or EO + CM groups was probably related to the higher (P <0.05) weight of the cold carcass (Ortiz et al., 2021).

There were no differences (P >0.05) between groups in the total fatty acid content of lamb meat. No differences (P >0.05) between groups were observed in the content of saturated, mono-unsaturated, or polyunsaturated fatty acids between treatments (Table 3). However, the content of C20: 5 n-3 and omega 3 in the group with EO+CM was higher (P <0.05) than in the group with EO, but there were no differences (P >0.05) in the total content of omega 6 fatty acids or omega 9 between groups.

The P/S and PUFA/SFA ratios tended to be higher (P <0.1) in the fat of the lambs from the EO+CM group than in the other groups. These results concur with those reported by Diaz et al. (2005) in the intramuscular fat of lambs fed diets without additives. The total concentration of omega 3 was higher than the 0.66% reported by Haro et al. (2020) in lambs supplemented with malic acid, but lower than the 1.87% reported by García-Galicia et al. (2020) in lambs supplemented with oregano essential oil. A low omega 6/omega 3 ratio is desirable as a means of reducing high-incidence chronic diseases in Western societies and developing countries (Junkuszew et al., 2020). In the current study, the omega 6/omega 3 ratio of the control group was 5.3, but in the group with EO + CM, it was 4.6. Junkuszew et al. (2020) found an omega 6/omega 3 ratio of 8.83 in lambs but in adult ewes, the ratio was 4.5, similar to that observed in the current study. The omega 6/omega 3 ratio depends mainly on nutrition and, especially, on the sources of fatty acids and their metabolism in the rumen, as reported by Romero-Bernal et al. (2017), who supplemented lambs with ryegrass hay, fishmeal, or soybean meal. The profile of predominant fatty acids in the rumen depends on whether the lambs are finished on grazing or on high-starch diets, as well as the type of ruminal fermentation modifier included in the diet (García-Galicia et al., 2020). High omega 3 with an omega 6/omega 3 ratio of 4 has been associated with a 70% decrease in human mortality from cardiovascular disease, and a ratio of 2.5 reduces rectal cancer cell proliferation (Simopoulos, 2008). The P/S and PUFA/SFA ratios indicate the antithrombotic potential (ATT), which is an index that takes into account the specific roles of individual fatty acids on human health.

The shear strength of cooked meat from lambs supplemented with EO was lower (P <0.05) than in the BD or CM groups but similar to the EO+CM group. The shear strength of raw meat in the BD group was higher (P <0.05) than in the EO group but similar to that of the other groups (Table 4).

The reduction in the shear strength of cooked lamb meat from lambs supplemented with essential EO concurs with that reported by García-Galicia et al. (2020) in lambs supplemented with oregano essential oil but is different to that reported by Simitsiz et al. (2008), who did not observe differences using the same supplement. Some of the intrinsic factors that affect meat texture are collagen content and solubility, sarcomere diameter, intramuscular fat content, and calpain proteolysis during aging (García-Galicia et al., 2020). There is a positive association between fat content and meat tenderness (Watkins et al., 2013). In the current investigation, an analysis of contrasts showed that the fat content in the meat of lambs supplemented with EO tended (P = 0.06) to be 18% higher than in the other groups, which may explain the greater softness of the lamb meat from the EO group.

There were no differences between treatments (P >0.05) in the water retention capacity or water loss due to cooking in the meat (Table 4). This agrees with the report of Haro et al. (2020) in lambs supplemented with EO, and by Abdelmalek et al. (2019) and Smeti et al. (2020) when using myrtle or rosemary oil as supplements. Atti et al. (2013) wrote that the more acidic the pH of the meat, the higher the water loss. In this investigation, the meat did not show a decrease in pH 24 h postmortem, which may explain the observed result.

There were no differences between treatments (P >0.05) in the measured parameters (L*, a*, b*, and C*) of meat colour or treatment * time interactions. These results agree with those reported by Ortuno et al. (2014), Smeti et al. (2018), and Yagoubi et al. (2018), who did not observe differences in the colour parameters (L*, a*, b*, C*, and H*) when using rosemary oil, but are in contrast to those of Haro et al. (2020), who reported differences in the meat colour parameters of lambs supplemented with oregano essential oil. Ortuno et al. (2014) reported that time modifies all colour parameters, turning the meat from bright red to brown. Here, this was reported in terms of CIELab coordinates, with an increase in L*, b*, and H* accompanied by a reduction in a* and C* in meat from all groups. The colour of the meat is affected by numerous factors such as breed, diet, age, weight and stress at slaughter, and the storage conditions of the meat, among others (Haro et al., 2020). In the current study, the conditions of diet, breed, management in the finishing process, and slaughter were similar; thus, it is thought that the doses of EO or CM used were insufficient to generate a detectable change. The colour of the meat is crucial in ensuring positive consumer appreciation, as consumers normally associate a bright red colour with fresh, quality meat (Wood et al., 2008). Meat with an L* value >34 is acceptable, and meat with an L* close to 44 is considered the ideal acceptability value for 95% of consumers (Khliji et al., 2010). In this study, the parameter, L*, had an average of 40.8, indicating that the meat was within a range of medium acceptability.

 

Conclusions

Essential oils, either alone or combined with calcium malate, in the diet of finishing lambs improve the pH of meat, increase the tenderness of cooked meat, and increase the total content of omega 3 fatty acids, all without modifying the colour, chemical composition or water retention capacity. This means that these additives can improve the quality of lamb meat. It is suggested that the investigation of these additives continue, and that the quantity as a supplement in high concentrate diets be increased for finishing lambs.

 

Acknowledgments

The authors express their gratitude to the line of generation and/or application of knowledge (LGAC) of the Livestock postgraduate program of the Colegio de Postgraduados for the facilities provided.

 

Authors' Contributions

MAOH conducted the research and wrote the manuscript, under the supervision of JRBG. PAMH collaborated in laboratory analyses. JDGR collaborated in lamb handling, slaughter, and carcass characterisation. OVVM led the data analysis and interpretation of results. A critical revision of the version to be published was performed by JRBG, SSGM, and MAOH.

 

Conflict of Interest Declaration

The authors certify that they have no affiliations with any organization or entity with any financial or non-financial interest in the subject matter or materials discussed in this manuscript.

 

References

AMSA (1995). Research guidelines for cookery, sensory evaluation, and instrumental tenderness measurements of fresh meat. Chicago: American Meat Science Association (AMSA) & National Livestock and Meat Board.         [ Links ]

Atti, N., Methlouthi, N., Saidi, C., & Mahouachi, M., 2013. Effects of extruded linseed on muscle physicochemical characteristics and fatty acid composition of lambs. J. Appl. Anim. Res. 41(4), 404-409. https://doi.org/10.1080/09712119.2013.792730        [ Links ]

Bejerholm, C., & Aaslyng, M. D., 2004. The influence of cooking technique and core temperature on results of a sensory analysis of pork-depending on the raw meat quality. Food. Qual. Prefer. 15(1), 19-30. https://doi.org/10.1016/s0950-3293(03)00018-1        [ Links ]

Ben Abdelmalek, Y., Smeti, S., Mekki, I., Hajji, H., Essid, I., & Atti, N., 2019. Rehabilitation of Barbarine cull ewes using rosemary residues and linseed: Effect on weight gain, carcass characteristics, and meat quality. Animal 13(4), 879-887. https://doi.org/10.1017/s175173111800215x        [ Links ]

Castillo, C., Benedito, J. L., Méndez, J., Pereira, V., López-Alonso, M., Miranda, M., & Hernandez, J., 2004. Organic acids as a substitute for monensin in diets for beef cattle. Anim. Feed Sci. Technol. 115(1-2), 101-116. https://doi.org/10.1016/j.anifeedsci.2004.02.001        [ Links ]

Chriki, S., & Hocquette, J.-F., 2020. The myth of cultured meat: A review. Front. Nutr. 7, 7. https://doi.org/10.3389/fnut.2020.00007        [ Links ]

Garcia-Galicia, I. A., Arras-Acosta, J. A., Huerta-Jimenez, M., Rentería-Monterrubio, A. L., Loya-Olguin, J. L., Carrillo-Lopez, L. M., Alarcon-Rojo, A. D., 2020. Natural oregano essential oil may replace antibiotics in lamb diets: Effects on meat quality. Antibiotics 9(5), 248. https://doi.org/10.3390/antibiotics9050248        [ Links ]

Garmyn, A. 2020. Consumer preferences and acceptance of meat products. Foods 9(6), 708. https://doi.org/10.3390/foods9060708        [ Links ]

Haro, A., de Evan, T., de la Fuente Vázquez, J., Díaz, M. T., Gonzalez Cano, J., & Carro, M. D., 2020. Effect of a diet supplemented with malic acid-heat (MAH)-treated sunflower on carcass characteristics, meat composition, and fatty acid profile in growing lambs. Animals 10(3), 487. https://doi.org/10.3390/ani10030487        [ Links ]

Jenkins, T., 2010. Technical note: Common analytical errors yielding inaccurate results during analysis of fatty acids in feed and digesta samples. J. Dairy Sci. 93(3), 1170-1174. https://doi.org/10.3168/jds.2009-2509        [ Links ]

Junkuszew, A., Nazar, P., Milerski, M., Margetin, M., Brodzki, P., & Bazewicz, K., 2020. Chemical composition and fatty acid content in lamb and adult sheep meat. Arch. Anim. Breed. 63(2), 261-268. https://doi.org/10.5194/aab-63-261-2020        [ Links ]

Khliji, S., van de Ven, R., Lamb, T., Lanza, M., & Hopkins, D., 2010. Relationship between consumer ranking of lamb colour and objective measures of colour. Meat Sci. 85(2), 224-229. https://doi.org/10.1016/j.meatsci.2010.01.002        [ Links ]

Leal-Gutiérrez, J. D., Jiménez-Robayo, L. M., Ariza, M., Manrique, C., López, J., Martínez, C., Jiménez, A., 2015. Polimorfismos de los genes CAPN1, CAST, DES, PRKAG3 Y RYR1 asociados a la capacidad de retención de agua en crudo y cocinado en carne de bovino en cruces Bos indicus y Bos taurus en Colombia. Arch. Zootec. 64(245), 29-35. https://doi.org/10.21071/az.v64i245.371        [ Links ]

Loya-Olguin, J. L., Ávila Ramos, F., Martínez González, S., García Galicia, I. A., Alarcón Rojo, A. D., & Escalera Valente, F., 2019. DL-malic acid supplementation improves the carcass characteristics of finishing Pelibuey lambs. Rev. Mex. Cienc. Pecu. 10(2), 460-472. https://doi.org/10.22319/rmcp.v10i2.4454        [ Links ]

Malekkhahi, M., Tahmasbi, A. M., Naserian, A. A., Danesh Mesgaran, M., Kleen, J. L., & Parand, A. A., 2015. Effects of essential oils, yeast culture, and malate on rumen fermentation, blood metabolites, growth performance, and nutrient digestibility of Baluchi lambs fed high-concentrate diets. J. Anim. Physiol. Anim. Nutr. 99(2), 221-229. 10.1111/jpn.12230        [ Links ]

Mancini, R., & Hunt, M., 2005. Current research in meat colour. Meat Sci. 71(1), 100-121. https://doi.org/10.1016/j.meatsci.2005.03.003        [ Links ]

McGeehin, B., Sheridan, J. J., & Butler, F., 2001. Factors affecting the pH decline in lamb after slaughter. Meat Sci. 58(1), 79-84. 10.1016/s0309-1740(00)00134-0        [ Links ]

Ortiz-Heredia, M. A., Hernández-Martínez, P. A., Guerrero-Rodriguez, J. de D., Gonzalez-Munoz, S. S., & Bárcena-Gama, J. R., 2021. Finalización de corderos con malato de calcio y aceites esenciales en la dieta. Rev. Mex. Agroecosistemas 8 (1), 64-71. Recuperado el 5 de noviembre de 2021, de https://www.voaxaca.tecnm.mx/revista/docs/RMAE%20vol%208_Sup1_2021/RMAE_Vol8_Sup1_2021(AMPA-2020).pdf        [ Links ]

Ortuno, J., Serrano, R., Jordan, M. J., & Banón, S., 2014. Shelf life of meat from lambs given essential oil-free rosemary extract containing carnosic acid plus carnosol at 200 or 400 mg kg^-1. Meat Sci. 96(4), 14521459. https://doi.org/10.1016/j.meatsci.2013.11.021        [ Links ]

Rivaroli, D. C., Guerrero, A., Velandia Valero, M., Zawadzki, F., Eiras, C. E., Campo, M. D. M., Nunes Do Prado, I., 2016. Effect of essential oils on meat and fat qualities of crossbred young bulls finished in feedlots. Meat Sci. 121, 278-284. https://doi.org/10.1016/j.meatsci.2016.06.017        [ Links ]

Romero-Bernal, J., Almaraz, E. M., Ortega, O. A. C., Salas, N. P., & González-Ronquillo, M., 2017. Chemical composition and fatty acid profile in meat from grazing lamb diets supplemented with ryegrass hay, fishmeal, and soya bean meal as PUFA sources. Ciênc. Rural, 47(4). https://doi.org/10.1590/0103-8478cr20160533        [ Links ]

Salami, S. A., Valenti, B., Bella, M., O'Grady, M. N., Luciano, G., Kerry, J. P., Newbold, C. J., 2018. Characterization of the ruminal fermentation and microbiome in lambs supplemented with hydrolysable and condensed tannins. FEMS Microbiol. Ecol. https://doi.org/10.1093/femsec/fiy061        [ Links ]

Simitzis, P. E., Deligeorgis, S. G., Bizelis, J. A., Dardamani, A., Theodosiou, I., & Fegeros, K., 2008. Effect of dietary oregano oil supplementation on lamb meat characteristics. Meat Sci. 79(2), 217-223. https://doi.org/10.1016/j.meatsci.2007.09.005        [ Links ]

Simopoulos, A., 2008. The importance of the omega-6:omega-3 fatty acid ratio in cardiovascular disease and other chronic diseases, Exp. Biol. M. 233, 674-688. 10.3181/0711-MR-311        [ Links ]

Smeti, S., Atti, N., Mahouachi, M., & Munoz, F., 2013. Use of dietary rosemary (Rosmarinus officinalis L.) essential oils to increase the shelf life of Barbarine light lamb meat. Small Rumin. Res. 113(2-3), 340-345. https://doi.org/10.1016/j.smallrumres.2013.04.001        [ Links ]

Smeti, S., Hajji, H., Mekki, I., Mahouachi, M., & Atti, N., 2018. Effects of dose and administration form of rosemary essential oils on meat quality and fatty acid profile of lamb. Small Rumin. Res. 158, 62-68. https://doi.org/10.1016/j.smallrumres.2017.10.007        [ Links ]

Smeti, S., Tibaoui, S., Bertolín, J. R., Yagoubi, Y., Mekki, I., Joy, M., & Atti, N., 2020. Effects of myrtle (Myrtus communis L.) essential oils as dietary antioxidant supplementation on carcass and meat quality of goat meat. J. Anim. Physiol. Anim. Nutr. 105(3), 452-461. https://doi.org/10.1111/jpn.13483        [ Links ]

Watkins, P. J., Frank, D., Singh, T. K., Young, O. A., & Warner, R. D., 2013. Sheepmeat flavor and the effect of different feeding systems: A review. J. Agric. Food Chem. 61(15), 3561 -3579. https://doi.org/10.1021/jf303768e        [ Links ]

Wood, J. D., Enser, M., Fisher, A. V., Nute, G. R., Sheard, P. R., Richardson, R. I., Hughes, S. I., & Whittington, F. M., 2008. Fat deposition, fatty acid composition, and meat quality: A review. Meat Sci. 78(4), 343-358. 10.1016/j.meatsci.2007.07.019        [ Links ]

Yagoubi, Y., Hajji, H., Smeti, S., Mahouachi, M., Kamoun, M., & Atti, N., 2018. Growth performance, carcass and noncarcass traits, and meat quality of Barbarine lambs fed rosemary distillation residues. Animal 12(11), 2407-2414. https://doi.org/10.1017/s1751731118000071        [ Links ]

Yagoubi, Y., Joy, M., Ripoll, G., Mahouachi, M., Bertolín, J., & Atti, N., 2018b. Rosemary distillation residues reduce lipid oxidation, increase alpha-tocopherol content, and improve fatty acid profile of lamb meat. Meat Sci. 136, 23-29. https://doi.org/10.1016/j.meatsci.2017.10.007        [ Links ]

Yagoubi, Y., Smeti, S., ben Saïd, S., Srihi, H., Mekki, I., Mahouachi, M., & Atti, N., 2021. Carcass traits and meat quality of fat-tailed lambs fed rosemary residues as a part of concentrate. Animals 11(3), 655. https://doi.org/10.3390/ani11030655        [ Links ]

 

 

Submitted 16 February 2022
Accepted 4 November 2022
Published 27 August 2023

 

 

# Corresponding author rbarcena@colpos.mx