This study investigated the inclusion of grape pomace silage (GPS; 0, 10, 20 and 30%) were evaluated in diets of lambs on nutrient intake and digestibility, nitrogen balance and ingestive behavior. Four lambs of the Santa Inês breed with weight of 21.93 ± 0.87 kg and approximately seven months old, were housed in metabolic cages and distributed in a 4x4 latin square design. The treatments consisted of four diets with the inclusion of 0, 10, 20 and 30% GPS in diets. The nutrient intake was observed an increasing linear behavior for ether extract (EE) intake (P<0.05) according to the increase of EE in the diets, caused by content of EE of seeds in GPS. The diets did not differ in the digestibility coefficients of nutrients and nitrogen balance (P>0.05), with average digestibility of dry matter digestibility (DDM) of 678.6 ± 0.62 g kg^-1 DM and average retention of 239.78 g kg^-1 N ingested of N. The ingestive behavior the diets were influenced (P<0.05) by only the length of time that the animals remained idle in standing. This parameter showed a quadratic behavior with a maximum point estimated at 17.73 % of GPS (P=0.041). In conclusion, the use of GPS can be used until inclusion level of 30 % without negatively affecting the parameters evaluated.

Kodagoda KHGK, Marapana RAUJ. Utilization of fruit processing by-products for industrial applications: A review. Intern J Sci Nutr 2017;2:24-30.

Barreto FM, Lima POA, Souza CMSA, et al. Uso de coprodutos de frutas tropicais na alimentação de ovinos no semiárido do Brasil. Arch Zootec 2014;3:17-131.

Mazza PHS, Jaeger SMPL, Silva FL, et al. Effect of dehydrated residue from acerola (Malpighia emarginata DC.) fruit pulp in lamb diet on intake, ingestive behavior, digestibility, ruminal parameters and N balance. Livest Sci 2020;103938.

De Evan T, Cabezas A, De La Fuente J, et al. Feeding Agroindustrial byproducts to light lambs: influence on growth performance, diet digestibility, nitrogen balance, ruminal fermentation, and plasma metabolites. Animals 2020;10:4-600.

Eleonora N, Dobrei A, Dobrei A, et al. Grape pomace in sheep and dairy cows feeding. J Hort Forest Biotechnol 2014;18:146-150.

Zhang N, Hoadley A, Patel J, et al. Sustainable options for the utilization of solid residues from wine production. Waste Manag 2017;60:173–183.

Gülcü M, Uslu N, Özcan MM, et al. The investigation of bioactive compounds of wine, grape juice and boiled grape juice wastes. J Food Process Preserv 2019;43:e13850.

Baumgärtel T, Kluth H, Epperlein K, et al. A note on digestibility and energy value for sheep of different grape pomace. Small Ruminant Res 2007;67:302–306.

Calderón-Cortés JF, González-Vizcarra VM, Pétriz-Celaya Y, et al. Energy value of unfermented dried grape pomace as substitute of alfalfa hay in diets for growing lambs. Austral J Vet Sci 2018;63:59–63.

Chikwanha CO, Muchenjeb V, Noltec EJ, et al. Grape pomace (Vitis vinifera L. cv. Pinotage) supplementation in lamb diets: Effects on growth performance, carcass and meat quality. Meat Sci 2019;147:6-12.

Massaro Junior FL, Bumbieris Junior VH, Zanin E, et al. Effect of storage time and use of additives on the quality of grape pomace silages. J Food Process Preserv 2020; e14373.

Zhao JX, Li Q, Zhang RX, et al. Effect of dietary grape pomace on growth performance, meat quality and antioxidant activity in ram lambs. Anim Feed Sci Technol 2018;236:76–85.

Gao X, Tang F, Zhang F, et al. Effects of the supplementation of distillers’ grape residues on ruminal degradability, whole tract digestibility and nitrogen metabolism in sheep. Arch Anim Nutr 2019;1–15.

Kearl LC. Nutrient requirements of ruminants in developing countries. Logan: Utah State University/ International Feedstuffs Institute, 1982.

Coelho Da Silva JF, Leão MI. Fundamentos de nutrição dos ruminantes. Piracicaba: Livroceres, São Paulo. 1979.

Schneider BH, Flat WP. The evaluation of feeds through digestibility experiments. Athens: The University of Georgia Press; 1975.

Decandia M, Sitzia M, Cabiddu A, Kababya D, Molle G. The use of polyethylene glycol to reduce the anti-nutritional effects of tannins in goat fed woody species. Small Ruminant Res 2000;38:2157-2164.

AOAC International. Association of Official Analytical Chemists. Official methods of analysis. 15th ed. Arlington, VA: AOAC International; 1990.

Mizubuti IY, Pinto AP, Pereira ES, et al. Métodos laboratoriais de avaliação de alimentos para animais. Londrina: EDUEL. 2009.

Van Soest PJ. User of detergents in the analyses of fibrous feeds. II. A rapid method for the determination of fibers and lignin. J Assoc Official Agricult Chemists1963; 46:829-835.

Detmann E, Souza MA, Valadares Filho SC, et al. Métodos para análise de alimentos: INCT: Ciência Animal. Visconde do Rio Branco: Suprema. 2012.

Sniffen CJ, O’connor JD, Van Soest PJ, et al. A net carbohydrate and protein availability. J Anim Sci 1992;70:3562-3577.

Tilley JMA, Terry RA. A two-stage technique for the in vitro digestion of forage crops. J British Grass Society 1963;18:104-111.

Martin P, Bateson P. Measuring behavior. 2nd ed. Cambridge: Cambridge University Press; 1993.

Johnson TR, Combs DK. Effects of prepartum diet, inert rumen bulk, and dietary polyethylene glycol on dry matter intake of lactating dairy cows. J Dairy Sci 1991; 74:933-944.

Bürger PJ, Pereira JC, Queiroz AC, et al. Comportamento ingestivo em bezerros holandeses alimentados com dietas contendo diferentes níveis de concentrado. Rev Bras Zootec 2000;29:236- 242.

Shinagawa FB, Santana FC, Torres LRO, Mancini-Filho J. Grape seed oil: a potential functional food. Food Sci Technol 2015; 35:399-406.

Palmquist DL, Mattos WRS. Metabolismo de lipídeos. In: Berchielli, TT, et al. Nutrição de ruminantes. Jaboticabal: FUNEP, Cap.10, 2006:287-310.

NRC. Nutrient requirements of small ruminants: Sheep, goats, cervids, and new world camelids. 1th. Washington, DC: National Academy Pres; 2007.

Mertens DR. Predicting intake and digestibility using mathematical models of ruminal function. J Dairy Sci 1987;64:1548-1558.

Barroso DD, Araújo GGL, Silva D, Medina FT. Resíduo desidratado de vitivinícolas associado a diferentes fontes energéticas na alimentação de ovinos: consumo e digestibilidade aparente. Ciênc Agrotec 2006;30:67-773.

Zalikarenab L, Pirmohammadi R, Teimuriyansari A. Chemical composition and digestibility of dried white and red grape pomace for ruminants. J Anim Vet Adv 2007;9:1107-1111.

Pirmohammadi R, Golgasemgarebagh A, Azari MA. Effects of ensiling and drying of white grape pomace on chemical composition, degradability and digestibility for ruminants. J Anim Vet Adv 2007;6:1079-1082.

Rogério MCP, Costa HHA, Ximenes LJF, Neiva JNM. Utilização de subprodutos agroindustriais na alimentação de novilhas leiteiras. In: Produção de bovinos no nordeste do Brasil: desafios e resultados, Fortaleza: Banco do Nordeste do Brasil, Cap. 11,2011:263-297.

Vasconcelos AM, Leão MI, Valadares Filho SC, et al. Parâmetros ruminais, balanço de compostos nitrogenados e produção microbiana de vacas leiteiras alimentadas com soja e seus subprodutos. Rev Bras Zootec 2010;39:425-433.

Menezes DR, Araújo GGL, Oliveira RL, et al. Balanço de nitrogênio e medida do teor de uréia no soro e na urina como monitores metabólicos de dietas contendo resíduo de uva de vitivinícolas para ovinos. Ver Bras Saúde Prod Anim 2006;4:169–175.

Almeida SCJ, Figueiredo MD, Azevedo KK. Intake, digestibility, microbial protein production, and nitrogen balance of lambs fed with sorghum silage partially replaced with dehydrated fruit by-products. Trop Anim Health Prod 2019;51:619-627.

Van Soest PJ. Nutritional ecology of the ruminant. New York: Cornell University Press; 1994.

Min BR, Barry TN, Attwood GT, McNabb WC. The effect of condensed tannins on the nutrition and healt of ruminants fed fresh tempeate forages: a review. Anim Feed Sci Tech 2003;106:3-19.

Oliveira SG, Berchielli TT. Potencial da utilização de taninos na conservação de forragens e nutrição de ruminantes - revisão. Arch Vet Sci 2007;12:1-9.

Cardoso AR, Carvalho S, Galvani DB, Pires BD, Gasperin CC, Garziera B, Garcia RPA. Comportamento ingestivo de cordeiros alimentados com dietas contendo diferentes níveis de fibra em detergente neutro. Ciência Rural 2006;36:604-609.

Missio RL, Brandana IL, Alves Filho DC, et al. Comportamento ingestivo de tourinhos terminados em confinamento, alimentados com diferentes níveis de concentrado na dieta. Rev Bras Zootec 2010;39:1571-1578.

Hubner CH, Pires CC, Galvani DB. Comportamento ingestivo de ovelhas em lactação alimentadas com dietas contendo diferentes níveis de fibra em detergente neutro. Ciência Rural, 2008;38:1078-1084.

Henz EL, Silva LDF, Bumbieris Junior, VH, et al. Evaluation and characterization of triticale silage (x. Triticosecale wittmack) to replace Sorghum bicolor (L.) Moench (S. vulgare Pers.) silage as feed for beef cattle. Sem Ciências Agrar 2020;4:335-344.

Carvalho GGP, Pires AJV, Silva RR, Ribeiro LSO, Chagas DMT. Comportamento ingestivo de ovinos Santa Inês alimentados com dietas contendo farelo de cacau. Rev Bras Zootec 2008;37:660-665.

Bastos VPM, Carvalho PGG, Pires AJV, et al. Ingestive behavior and nitrogen balance of confined Santa Ines lambs fed diets containing soybean hulls. Asian-Aust J Anim Sci 2014;27:24-29.