Hostname: page-component-745bb68f8f-d8cs5 Total loading time: 0 Render date: 2025-02-03T14:05:23.798Z Has data issue: false hasContentIssue false
  • English
  • Français

How does barley supplementation in lambs grazing alfalfa affect meat sensory quality and authentication?

Published online by Cambridge University Press:  22 June 2018

T. Devincenzi ,
A. Prunier ,
K. Meteau  and
S. Prache
T. Devincenzi
Affiliation:
INRA, VetAgro Sup, UMR Herbivores, Université d’Auvergne, 63122 St-Genès-Champanelle, France
A. Prunier
Affiliation:
INRA, UMR1348 Physiologie, Environnement et Génétique pour l’Animal et les Systèmes d'Elevage, 35590 St-Gilles, France
K. Meteau
Affiliation:
INRA, UE1206 Elevage Alternatif et Santé des Monogastriques, Le Magneraud, 17700 St-Pierre-d’Amilly, France
S. Prache*
Affiliation:
INRA, VetAgro Sup, UMR Herbivores, Université d’Auvergne, 63122 St-Genès-Champanelle, France
*
E-mail: [email protected]
Get access

Abstract

Excessive flavour in lamb meat is undesirable for consumers and can prompt purchase resistance. Volatile indoles responsible for off-flavours accumulate more in the fat of lambs on pasture than on grain and are enhanced when lambs graze alfalfa. Here, we investigated whether barley supplementation of lambs grazing alfalfa influences meat sensory quality. Using three groups of 12 male Romane lambs, we compared three feeding regimes: alfalfa grazing (AG), alfalfa grazing + daily supplementation with barley (29 g/kg live weight0.75, AGS) and stall feeding with concentrate and hay (SF). As some of the compounds involved in meat sensory traits may act as dietary biomarkers, we also investigated potential implications for meat authentication. Although barley represented 38% of the diet in AGS lambs, it did not offer any advantage for animal average daily gain or parasitism level. Animal performance, carcass weight and fatness did not differ between feeding regimes. Dorsal fat firmness tended to be greater in AG than AGS and greater in AGS than SF. Skatole and indole concentrations in perirenal and dorsal fat were lower in SF lambs than in AG and AGS lambs (P<0.01 to P<0.0001), but did not differ between AG and AGS lambs. Yellowness, chroma and hue angle of perirenal fat were lower in SF lambs than in AG and AGS lambs (P<0.001), but did not differ between AG and AGS lambs. Absolute value of the mean integral for both perirenal fat and subcutaneous caudal fat (AVMIPF and AVMISC), quantifying the intensity of light absorption by carotenoids in perirenal and subcutaneous caudal fat, respectively, were lower in SF lambs than in AG and AGS lambs (P<0.0001 for both comparisons), but did not differ between AG and AGS lambs. Meat colour was unaffected by the treatment. We confirm that lambs grazing alfalfa accumulate high levels of volatile indoles in their fat, but we show that barley supplementation to lambs grazing alfalfa is not effective in reducing fat volatile indoles concentration and excessive odour/flavour in the meat. We also confirm that both perirenal fat skatole concentration and AVMIPF are of interest for discriminating lambs that grazed alfalfa from lambs that were stall-fed, and we show that they are not effective for discriminating supplemented from non-supplemented grazing lambs.

Keywords

skatolespectroscopycolourpasture-feedingalfalfa
Type
Research Article
Information
animal , Volume 13 , Issue 2 , February 2019 , pp. 427 - 434
Copyright
© The Animal Consortium 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Batorek, N, Škrlep, M, Prunier, A, Louveau, I, Noblet, J, Bonneau, M and Čandek-Potokar, M 2012. Effect of feed restriction on hormones, performance, carcass traits, and meat quality in immunocastrated pigs. Journal of Animal Science 90, 45934603.Google Scholar
Bonneau, M and Chevillon, P 2012. Acceptability of entire male pork with various levels of androstenone and skatole by consumers according to their sensitivity to androstenone. Meat Science 90, 330337.Google Scholar
Brainard, DH 2003. Color appearance and color difference specification. In The science of color (ed. KS Steven), pp. 191216. Elsevier Science Ltd, Amsterdam, the Netherlands.Google Scholar
Devincenzi, T, Prunier, A, Meteau, K, Nabinger, C and Prache, S 2014. Influence of fresh alfalfa supplementation on fat skatole and indole concentration and chop odour and flavour in lambs grazing a cocksfoot pasture. Meat Science 98, 607614.Google Scholar
Dian, PHM, Chauveau-Duriot, B, Prado, IN and Prache, S 2007. A dose–response study relating the concentration of carotenoid pigments in blood and reflectance spectrum characteristics of fat to carotenoid intake level in sheep. Journal of Animal Science 85, 30543061.Google Scholar
Fisher, AV, Enser, M, Richardson, RI, Wood, JD, Nute, GR, Kurt, E, Sinclair, LA and Wilkinson, RG 2000. Fatty acid composition and eating quality of lamb types derived from four diverse breed x production systems. Meat Science 55, 141147.Google Scholar
Hassoun, P and Bocquier, F 2007. Alimentation des ovins. In Alimentation des bovins, ovins et caprins Besoins des animaux – Valeurs des aliments (ed. INRA), pp 121136. Editions Quæ, Versailles, France.Google Scholar
Huang, Y, Andueza, D, de Oliveira, L, Zawadzki, F and Prache, S 2015. Visible spectroscopy on carcass fat combined with chemometrics to distinguish pasture-fed, concentrate-fed and concentrate-finished pasture-fed lambs. Meat Science 101, 512.Google Scholar
Molle, G, Decandia, M, Cabiddu, A, Landau, SY and Cannas, A 2008. An update on the nutrition of dairy sheep grazing Mediterranean pastures. Small Ruminant Research 77, 93112.Google Scholar
Oliveira, L, Carvalho, P C F and Prache, S 2012. Fat spectro-colorimetric characteristics of lambs switched from a low to a high dietary carotenoid level for various durations before slaughter. Meat Science 92, 644650.Google Scholar
Prache, S and Theriez, M 1999. Traceability of lamb production systems: carotenoids in plasma and adipose tissue. Animal Science 69, 2936.Google Scholar
Prache, S, Béchet, G and Thériez, M 1990. Effects of concentrate supplementation and herbage allowance on the performance of grazing suckling lambs. Grass and Forage Science 45, 423429.Google Scholar
Prache, S, Priolo, A and Grolier, P 2003. Effect of concentrate finishing on the carotenoid content of perirenal fat in grazing sheep: its significance for discriminating grass-fed, concentrate-fed and concentrate-finished grazing lambs. Animal Science 77, 225234.Google Scholar
Prache, S, Huang, Y and Andueza, D 2018. To what extent is a breed-specific database necessary to differentiate meat from pasture-fed and stall-fed lambs using visible spectroscopy? Animal, https://doi.org/10.1017/S1751731117003366.Google Scholar
Priolo, A, Micol, D and Agabriel, J 2001. Effects of grass feeding systems on ruminant meat colour and flavour. A review. Animal Research 50, 185200.Google Scholar
Priolo, A, Micol, D, Agabriel, J, Prache, S and Dransfield, E 2002. Effect of grass or concentrate feeding systems on lamb carcass and meat quality. Meat Science 62, 179185.Google Scholar
Raynaud, JP 1970. Etude de l’efficacité́ d’une technique de coproscopie quantitative pour le diagnostic de routine et le contrôle des infestations parasitaires des bovins, ovins, équins et porcins. Annales de Parasitologie 45, 321342.Google Scholar
Ripoll, G, Albertí, P and Joy, M 2012. Influence of alfalfa grazing-based feeding systems on carcass fat colour and meat quality of light lambs. Meat Science 90, 457464.Google Scholar
Santé-Lhoutellier, V, Engel, E and Gatellier, P 2008. Assessment of the influence of diet on lamb meat oxidation. Food Chemistry 109, 573579.Google Scholar
Schreurs, NM, Marotti, DM, Tavendale, MH, Lane, GA, Barry, TN, Lopez-Villalobos, N and McNabb, WC 2007a. Concentration of indoles and other rumen metabolites in sheep after a meal of fresh white clover, perennial ryegrass or Lotus corniculatus and the appearance of indoles in the blood. Journal of the Science of Food and Agriculture 87, 10421051.Google Scholar
Schreurs, NM, McNabb, WC, Tavendale, MH, Lane, GA., Barry, TN, Cummings, T, Fraser, K, Lopez-Villalobos, N and Ramirez-Restrepo, CA 2007b. Skatole and indole concentration and the odour of fat from lambs that had grazed perennial ryegrass/white clover pasture or Lotus corniculatus . Animal Feed Science and Technology 138, 254271.Google Scholar
Schwarz, MW, Cowan, WB and Beatty, JC 1987. An experimental comparison of RGB, YIQ, LAB, HSV, and opponent color models. Association for Computing Machinery Transactions Graphics 6, 123158.Google Scholar
Sheath, GW, Coulon, JB and Young, OA 2001. Grassland management and animal product quality. In Proceedings of the 42nd International Grassland Congress, 11–21 February 2001, São Paulo, Brazil, pp. 1019–1026.Google Scholar
Vasta, V and Priolo, A 2006. Ruminant fat volatiles as affected by diet. A review. Meat Science 73, 218228.Google Scholar
Young, OA, Berdagué, JL, Viallon, C, Rousset-Akrim, S and Theriez, M 1997. Fat-borne volatiles and sheep meat odour. Meat Science 45, 183200.Google Scholar
Young, OA, Lane, G A, Priolo, A and Fraser, K 2003. Pastoral and species flavour in lambs raised on pasture, lucerne or maize. Journal of the Science of Food and Agriculture 83, 93104.Google Scholar
Supplementary material: File

Devincenzi et al. supplementary material 1

Devincenzi et al. supplementary material

Download Devincenzi et al. supplementary material 1(File)
File 28.7 KB