Effect of Piglet Birth Weight on Carcass Muscle and Fat Content and Pork Quality – A Review

Alvarenga A.L.N., Chiarini - Garcia A.H., Cardeal P.C., Moreira L.P., Fox- croft G.R., Fontes D.O., Almeida F.R.C.L. (2012). Intra-uterine growth retardation affects birth weight and postnatal development in pigs, impairing muscle accretion, duodenal mucosa morphology and carcass traits. Reprod. Fertil. Develop., 25: 387-395.Search in Google Scholar

Ashmore C.R., Addis P.B., Doerr L. (1973). Development of muscle fibers in the fetal pig. J. Anim. Sci., 36: 1088-1093.Search in Google Scholar

Beaulieu A.D., Aalhu s J.L., Williams N.H., Patience J.F. (2010). Impact of piglet birth weight, birth order, and litter size on subsequent growth performance, carcass quality, muscle com­position and eating quality of pork. J. Anim. Sci., 88: 2767-2778.Search in Google Scholar

Bee G. (2004). Effect of early gestation feeding, birth weight, and gender of progeny on muscle fiber characteristics of pigs at slaughter. J. Anim. Sci., 82: 826-836.Search in Google Scholar

Bee G. (2007). Birth weight of litters as source of variation in postnatal growth, and carcass and meat quality. Adv. Pork Prod., 18: 191-195.Search in Google Scholar

Bee G., Calderini M. Biolley C, Guex G., Herzog W. Lindemann M.D. (2007). Changes in the histochemical proporties and meat quality traits of porcine muscles during the grow­ing-finishing period as affected by feed restriction, slaughter age, or slaughter weight. J. Anim. Sci., 85: 1030-1045.Search in Google Scholar

Berard J., Kreuzer M., Bee G. (2008). Effect of litter size and birth weight on growth, carcass and pork quality, and their relationship to postmortem proteolysis. J. Anim. Sci., 86: 2357-2368.Search in Google Scholar

Berard J., Pardo C.E., Bethaz S., Kreuzer M., Bee G. (2010). Intrauterine crowding de­creases average birth weight and affects muscle fiber hyperplasia in piglets. J. Anim. Sci., 88: 3242-3250.Search in Google Scholar

Bereta A., Eckert R. (2010). Histological profile of muscles is strictly related to pork quality (in Polish). Wiad. Zoot., 4: 65-70.Search in Google Scholar

Cagnazzo M., Te Pas M.F.W., Priem J., de Wit A.A.C., Pool M.H., Davoli R., Russo V. (2006). Comparison of prenatal muscle tissue expression profiles of two pig breeds dif­fering in muscle characteristics. J. Anim. Sci., 84: 1-10.Search in Google Scholar

Campos P.H., Silva B.A., Donze l e J.L., Oliveira R.F., Kn o l E.F. (2012). Effects of sow nutrition during gestation on within-litter birth weight variation: a review. Animal, 5: 797-806.Search in Google Scholar

Cerisuelo A., Baucells M.D., G a s a J., Coma J., Carrion D., Chapinal N.Sala R. (2009). Increased sow nutrition during midgestation affects fiber development and meat quality with no consequences on growth performance. J. Anim. Sci., 87: 729-739.Search in Google Scholar

Chilibeck P.D., Harber V.J., Bell G., Cegielski A.C., Murdoch G., MacLean I. (2005). The effect of limited overfeeding during growth on muscle characteristics: a pig model. Eat. Weight Disord., 10: 13-18.Search in Google Scholar

Davoli R., Braglia S. (2007). Molecular approaches in pig breeding to improve meat quality. Brief. Funct. Genom. Proteom., 6: 313-321.Search in Google Scholar

Dietl G., Groenveld E., Fiedler I. (1993). Genetic parameters of muscle structure traits in pig. In: Proc. 44th Annual Meeting EAAP, Aarhus, 16-19 August 1993, II, 1.8.Search in Google Scholar

Du M. (2014). Meat science and muscle biology symposium - Implants, muscle development, and meat quality. J. Anim. Sci., 92: 1-2.Search in Google Scholar

Du M., Tong J., Zhao J., Underwood K.R., Zhu M., Ford S.P., Nathanielsz P.W. (2010). Fetal program­ming of skeletal muscle development in ruminant animals. J. Anim. Sci., 88: E 51-60.Search in Google Scholar

Dwyer C.M., Fletcher J.M., Stickland N.C. (1993). Muscle cellularity and postnatal growth in the pigs. J. Anim. Sci., 71: 3339-3343.Search in Google Scholar

Dwyer C.M., Stickland N.C., Fletcher J.M. (1994). The influence of maternal nutrition on muscle fiber number development in the porcine fetus and subsequent postnatal growth. J. Anim. Sci., 72: 911-917.Search in Google Scholar

Fiedler I., Rehfeldt C., Ender K. (1991). Muscle fibre characteristics - new selection criteria? Tierzuchter, 43: 444-445.Search in Google Scholar

Fiedler I., Ender K., Wicke M., MaakS.von Lengerken G., Meyer W. (1999). Struc­tural characteristics of muscle fibres in pigs with different malignant hyperthermia susceptibility and different meat quality. Meat Sci., 53: 9-15.Search in Google Scholar

Fiedler I., Dieti G., Rehfeldt C., Wegner I., Ender K. (2004). Muscle fibre traits as ad­ditional selection criteria for muscle growth and meat quality in pig - results of simulated selection. J. Anim. Breed. Genet., 121: 331-344.Search in Google Scholar

Foxcroft G.R., Dixon W.T., Novak S., Putman C.T., Town S.C., Vinsky M.D. (2006). The biological basis for prenatal programming of postnatal performance in pigs. J. Anim. Sci., 84: E105-112.Search in Google Scholar

Foxcroft G.R., Dixon W.T.Dyck M.K.Novak S.Harding J.C.S., Almeida F.C.R.L. (2009). Prenatal programming of postnatal development in the pig. Control Pig Prod. VIII. indb., pp. 213-231.Search in Google Scholar

Gardan D., Gondret F.Van den Maagdenberg K.,BuysN.,De Smet S.Louveau I. (2008). Lipid metabolism and cellular features of skeletal muscle and subcutaneous adipose tissue in pigs differing in IGF-II genotype. Dom. Anim. Endocrinol., 34: 45-53.Search in Google Scholar

Gatford K.L., Smits R.J., Collins C.L., Argent C, De Blasio M.J., Roberts C.T., Nottle M.B., Kind K.L., Owens J.A. (2010). Maternal responses to daily maternal porcine somatotropin injections during early-mid pregnancy or early-late pregnancy in sows and gilts. J. Anim. Sci., 88: 1365-1378.Search in Google Scholar

Gentry J.G., McGlone J.J., Miller M.F., Blanton J.R. Jr. (2004). Environmental effects on pig performance, meat quality and muscle characteristics. J. Anim. Sci., 82: 209-217.Search in Google Scholar

Gondret F., Lefaucheur L., Louveau I., Lebret B. (2005 a). The long-term influences of birth weight on muscle characteristics and eating meat quality in pigs reared and fed during fatten­ing. Arch. Tierzucht, 48: 68-73.Search in Google Scholar

Gondret F., Lefaucheur L., Louveau I., Lebret B., Pichodo X., Le Cozler Y. (2005 b). Influence of piglet birth weight on postnatal growth performance tissue lipogenic capacity and muscle histological traits at market weight. Livest. Prod. Sci., 93: 137-146.10.1016/j.livprodsci.2004.09.009Search in Google Scholar

Gondret F., Lefaucheur L., Juin H., Louveau I., Lebret B. (2006). Low birth weight is associated with enlarged muscle fiber area and impaired meat tenderness of the longissimus muscle in pigs. J. Anim. Sci., 84: 93-103.Search in Google Scholar

Gonzalez - Bulnes A.Ovilo C, Lopez-Bote CJ.Astiz S.Ayuso M.,Perez-So-lana K.L., Sanchez-Sanchez R., Torres-Rovira L. (2013). Fetal and early-postnatal developmental patterns of obese-genotype piglets exposed to prenatal programming by maternal over- and undernutrition. Endocr. Metab. Immune Disord. Drug. Targets., 13: 240-249.Search in Google Scholar

Handel S.E., Stickland N.C. (1987). Muscle cellularity and birth weight. Anim. Prod., 44: 311-317.Search in Google Scholar

Hegarty P.V., All en C.E. (1978). Effect of prenatal runting on the postnatal development of skeletal muscles in swine and rats. J. Anim. Sci., 46: 1634-1640.Search in Google Scholar

Heyer A., Andersson H.K., Linberg J.E., Lundstrom K. (2004). Effect of extra maternal feed supply in early gestation on sow and piglet performance and production and meat quality of growing/finishing pigs. Acta Agricult. Scandin. Sect. A-Anim. Sci., 54: 44-55.Search in Google Scholar

Hill R.A., Connor E.E., Poulos S.P., Welsh T.H., Gabler N.K. (2010). Growth and develop­ment symposium: fetal programming in animal production. J. Anim. Sci., 88 (E Suppl.): 38-39.Search in Google Scholar

Karlsson A., Enfalt A.C., E s s en - Gu s tav s s on B., Lundstrom K., Rydhmer L., Stern S. (1993). Muscle histochemical and biochemical properties in relation to meat quality dur­ing selection for increased lean tissue growth rate in pigs. J. Anim. Sci., 71: 930-938.Search in Google Scholar

Karlsson A.H., K l o n t R.E., Fernandez X. (1999). Skeletal muscle fibres as factors for pork quality. Livest. Prod. Sci., 60: 255-269.Search in Google Scholar

Karunaratne J., Bayol S., Ashton C., Stickland N. (2007). Potential mechanisms for the nutritional control of muscle composition in developing pigs. Arch. Tierzucht, 50, p. 05.Search in Google Scholar

Klont R.E., Eikelenboom G., Brocks L. (1998). Muscle fibre type and meat quality. In: Proc. 44th Int. Congr. Meat Sci. Tech., Barcelona, L9, pp. 98-105.10.1016/S0309-1740(98)90050-XSearch in Google Scholar

Kristensen L., Therkildsen M., Riis B., S0rensen M.T., Oksbjerg N., Purs- l o w P.P., Ertbjerg P. (2002). Dietary-induced changes of muscle growth rate in pigs: Effects on in vivo and postmortem muscle proteolysis and meat quality. J. Anim. Sci., 80: 2862-2871.Search in Google Scholar

Larzul C, Lefaucheur L., Ecolan P., Gogue J., TalmantA., Sellier P., Monin G. (1997). Phenotypic and genetic parameters for longissimus muscle fibre characteristics in relation to growth, carcass and meat quality traits in Large White pigs. J. Anim. Sci., 75: 3126-3137.Search in Google Scholar

Larzul C, L e Roy P., Gogue J., Talmant A., Jacquet B., Lefaucheur L., Ecolan P., Sellier P., M o n i n G. (1999). Selection for reduced muscle glycolytic potential in Large White pigs. II. Correlated responses in meat quality and muscle compositional traits. Genet. Sel. Evol., 31: 61-76.Search in Google Scholar

Lawlor P.G., Lynch P.B., O’Connell M.K., McNamara L., Reid P., Stickland N.C. (2007). The influence of over feeding sows during gestation on reproductive performance and pig growth to slaughter. Arch. Tierzucht, Special Issue, 50: 82-91.Search in Google Scholar

Lefaucheur L. (2001). Myofiber typing and pig meat production. Slov. Veter. Res., 38: 5-28.Search in Google Scholar

Lefaucheur L. (2006). Myofibre typing and its relationships to growth performance and meat qual­ity. Arch. Tierzucht, Dummerstorf, 49: 4-17.Search in Google Scholar

Lefaucheur L., Edom F., Ecolan P., Butler-Browne G.S. (1995). Pattern of muscle fiber type formation in the pig. Dev. Dyn., 203: 27-41.Search in Google Scholar

Lefaucheur L., Ecolan P., Barzic Y.M., Marion J., Dividich J. (2003). Early postnatal food intake alters myofiber maturation in pig skeletal muscle. J. Nutr., 133: 140-147.Search in Google Scholar

Lefaucheur L., Ecolan P., Lebret B., Damon M. Louveau I. Sellier P., Gil­bert H. (2005). Influence of divergent selection on residual feed intake in the growing pig on muscle compositional traits. Arch. Anim. Breed., Special Issue 1, 51: 117-122.Search in Google Scholar

Lefaucheur L., Lebret B., Ecolan P., Galian M. Damon M. Louveau I. Pru- nierA., Sellier P., Gilbert H. (2008). Selection divergente pour la consommation alimentaire residuelle chez le porc: effets sur les proprietes musculaires et la qualite de la viande. J. Rech. Porc. France, 40: 83-84.Search in Google Scholar

Lengerken G., Wicke M., Maak K. (1997). Stress susceptibility and meat quality situation and prospects in animal breeding and research. Arch. Anim. Breed., 40: 163-171.Search in Google Scholar

Losel D., Kalbe C., Rehfeldt C. (2009). L-carnitine supplementation during suckling intensi­fies the early postnatal skeletal myofiber formation in piglets of low birth weight. J. Anim. Sci., 87: 2216-2226.Search in Google Scholar

Maltin C.A., Warkup C.C., Matthews K.R., Grant C.M., Porter A.D., Delday M.I. (1997). Pig muscle characteristics as a source of variation in eating quality. Meat Sci., 47: 237-248.Search in Google Scholar

Markham T.C.W., Latorre R.M., Lawlor P.G., Ashton C.J., McNamara L.B., Nat­ ter R., Rowlerson A., Stickland N.C. (2009). Developmental programming of skeletal muscle phenotype/metabolism. Animal. Cambridge Univ. Press, 3: 1001-1012.Search in Google Scholar

Mascarello F., Stecchini M.L., Rowlerson A., Ballocchi E. (1992). Tertiarymyotubes in postnatal growing pig muscle detected by their myosin isoform composition. J. Anim. Sci., 70: 1806-1813.Search in Google Scholar

McNamara L.B., Giblin L., Markham T., Stickland N.C., Berry D.P., O’Reilly J.J., Lynch P.B., Kerry J.P., Lawlor P.G. (2011). Nutritional intervention during gestation alters growth, body composition and gene expression patterns in skeletal muscle of pig offspring. Animal, 8: 1195-1206.Search in Google Scholar

Metges O.C. (2005). Effects of pre- and postnatal exposure to maternal low and high dietary protein levels on body mass development and energy expenditure in rat progeny. Arch. Anim. Breed., Spe­cial Issue, 49, p. 55.Search in Google Scholar

Metges O.C., Dietrich N., Kucia M., Langhammer M., Numberg G., Rehfeldt C. (2008). Glucose tolerance and muscle characteristics in mice offspring are nutritionally programmed by a maternal high protein diet. Arch. Anim. Breed., Special Issue, 51: 27-28.Search in Google Scholar

Migdal W., Wojtysiak D., Pasciak P. (2005). The histochemical profile of fatteners’ muscles depending on the type of muscles, gender and breed of fatteners, their body weight, and feeding. Zywnosc. Suppl., 3 (44): 157-168.Search in Google Scholar

MLC (1993). A Blueprint for Lean and Tender Pork. Meat and Livestock Commission, Milton Keynes.Search in Google Scholar

Nissen P.M., Jorgensen P.F., Oksbjerg N. (2004). Within-litter variation in muscle fiber char­acteristics, pig performance, and meat quality traits. J. Anim. Sci., 82: 414-421.Search in Google Scholar

Oksbjerg N., Petersen J.S., S0reness I.L., Henckel P., Vestergaard M., Ertb- jerg P., M0ller A.J., Bejerholm C., St0ier S. (2000). Long-term changes in performance and meat quality of Danish landrace pigs: A study on current compared with an unimproved genotype. Anim. Sci., 71: 81-92.Search in Google Scholar

Oksbjerg N., Nissen P.M., Therkildsen M., M0ller H.S., Larsen L.B., Ander­ sen M., Young J.F. (2013). Meat Science and Muscle Biology Symposium: In utero nutrition related to fetal development, postnatal performance, and meat quality of pork. J. Anim. Sci., 91: 1443-1453.Search in Google Scholar

Osterc J. (1974). Diameter and number of muscle fibers in musculus longissimus dorsi in connection with production properties of some cattle breeds. PhD Thesis, University of Ljubljana, pp. 1-67.Search in Google Scholar

Petersen J.S., Henckel P., Oksbjerg N., Serense M.T. (1998). Adaptations in muscle fibre characteristics induced by physical activity in pigs. J. Anim. Sci., 66: 733-740.Search in Google Scholar

Picard B., Lefaucheur L., Berri C., Duclos M.J. (2002). Muscle fibre ontogenesis in farm animal species. Reprod. Nutr. Devel., 42: 415-431.Search in Google Scholar

Ponsuksili S., Nguyen Trong Ngu,Murani E., Schellander K., Wimmers K. (2008). Relative abundance of MyHC isoform transcripts and its association with muscularity and meat quality. Arch. Anim. Breed., Special Issue, 151, p. 40.Search in Google Scholar

Powell S.E., Aberle A.D. (1980). Effects of birth weight on growth and carcass composition of swine. J. Anim. Sci., 50: 860-867.Search in Google Scholar

Powell S.E., Aberle A.D. (1981). Skeletal muscle and adipose tissue cellularity in runt and normal birth weight swine. J. Anim. Sci., 52: 748-756.Search in Google Scholar

Rehfeldt C., Kuhn G. (2006). Consequences of birth weight for postnatal growth performance and carcass quality in pigs as related to myogenesis. J. Anim. Sci., 84: E 113-123.Search in Google Scholar

Rehfeldt C., Fiedler I., Dietl G., Ender K. (2000). Myogenesis and postnatal skeletal muscle cell growth as influenced by selection. Liv. Prod. Sci., 66: 177-188.Search in Google Scholar

Rehfeldt C., Henning M., Fiedler I. (2008 a). Consequence of pig domestication for skeletal muscle growth and cellularity. Livest. Sci., 116: 30-41.10.1016/j.livsci.2007.08.017Search in Google Scholar

Rehfeldt C., Tuchscherer A., Hartung M., Kuhn G. (2008 b). A second look at the influ­ence of birth weight on carcass and meat quality in pigs. Meat Sci., 78: 170-175.10.1016/j.meatsci.2007.05.02922062267Search in Google Scholar

Rehfeldt C, Te Pas M.F.W, Wimmers K., B r am e l d J.M., Ni s s en P.M., B err i C. Va­l ente L.M.P, Power D.M., Picard B., Stickland N.C., Ok sb j erg N. (2011 a). Advanc­es in research on the prenatal development of skeletal muscle in animals in relation to the quality of muscle-based food. I. Regulation of myogenesis and environmental impact. Animal, 5: 703-717.10.1017/S175173111000208922439993Search in Google Scholar

Rehfeldt C. Te Pas M.F.W. Wimmers K. Brameld J.M. Nissen P.M. Berri C. Valente L.M.P. Power D.M. Picard B. Stickland N.C. Oksbjerg N. (2011 b). Advances in research on the prenatal development of skeletal muscle in animals in relation to the quality of muscle-based food. II - Genetic factors related to animal performance and advances in methodology. Animal, 5: 718-730.10.1017/S175173111000245422439994Search in Google Scholar

Rehfeldt C. Stabenow B. Pfuhl R. Block J. Nurnberg G. Otten W. Met- g e s C.C., K a l b e C. (2012). Effects of limited and excess protein intakes of pregnant gilts on car­cass quality and cellular properties of skeletal muscle and subcutaneous adipose tissue in fattening pigs. J. Anim. Sci., 90: 184-196.10.2527/jas.2011-423421890499Search in Google Scholar

Rekiel A. Bartosik J. Wi§cek J. Batorska M. Kuczynska B. Loj ek A. (2014 a). Effect of piglet birth weight on selected characteristics of pork. Ann. Anim. Sci., 14: 967-975.10.2478/aoas-2014-0033Search in Google Scholar

Rekiel A., Wi 9 cek J., Batorska M., Kulisiewicz J. (2014 b). Effect of sow prolificacy and nutrition on pre- and postnatal growth of progeny - a review. Ann. Anim. Sci., 14: 3-15.10.2478/aoas-2013-0060Search in Google Scholar

Ruusunen M., Puolanne E. (2004). Histochemical properties of fibre types in muscles of wild and domestic pigs and the effect of growth rate on muscle fibre properties. Meat Sci., 67: 533-539.Search in Google Scholar

Schinckel A.P., Einstein M.E., Jung s t M.E., Booher S., Newman S. (2010). Evaluation of impact of pig birth weight on grow-finish performance, backfat depth and loin depth. Profess. Anim. Scient., 26: 193-205.Search in Google Scholar

Sollero B.P., Guimaraes S.E.F., Ri l ing ton V.D., Tempelman R.J. Raney N.E., Steibel J.P., Guimaraes J.D., Lopes P.S., Lopes M.S., Ernst C.W. (2011). Transcriptional profiling during foetal skeletal muscle development of Piau and Yorkshire-Landrace cross-bred pigs. Anim. Genet., 42: 600-612.Search in Google Scholar

Staun H. (1968). Diameter and number of muscle fibres and their relation to meatiness and meat qual­ity in Danish Landrace pigs. 366. Beretning fraforsogslaboratoriet. National Res. Inst. Anim. Sci., Copenhagen, Denmark, pp. 1-121.Search in Google Scholar

Staun H. (1972). The nutritional and genetic influence on number and size of muscle fibres and their response to carcass quality in pigs. World Rev. Anim. Prod., 3: 18-26.Search in Google Scholar

Stinckens A. Van den Maagdenberg K. Luyten L. Georges M. De Smet S. Buys N. (2007). The RYR1 g.1843C>T mutation is associated with the effect of the IGF2 intron- 3-g3072G>A mutation on muscle hypertrophy. Anim. Genet., 38: 67-71.10.1111/j.1365-2052.2006.01558.x17257191Search in Google Scholar

Świątkiewicz M. (2010). The effect of feeding intensity of pregnant and lactating sows on their reproductive indices, meat quality and fattening results of progeny (in Polish). Rocz. Nauk. Zoot., Monogr. Rozpr., Wyd. IZ PIB, Krakow, 43: 1-86.Search in Google Scholar

Te Pas M.F.W. Keuning E. Hulsegge B. Hoving-Bolink A.H. Evans G. Mul­der H.A. (2010). Longissimus muscle transcriptome profiles related to carcass and meat quality traits in fresh meat Pietrain carcasses. J. Anim. Sci., 88: 4044-4055.10.2527/jas.2010-295220833764Search in Google Scholar

Van den Maagdenberg L. Stinckens A.Claeys E.Buys N. De Smet S. (2008). Effect of the insulin-like growth factor-II and RYR1 genotype in pigs on carcass and meat quality traits. Meat Sci., 80: 293-303.10.1016/j.meatsci.2007.12.00822063334Search in Google Scholar

Wigmore R.M., Dun g l i s on G.F. (1998). The generation of fiber diversity during myogenesis. Int. J. Dev. Biol., 42: 117-125.Search in Google Scholar

Wigmore P.M.C., Stickland N.C. (1983). Muscle development in large and small pig fetuses. J. Anat., 137: 235-245.Search in Google Scholar

Wimmers K, Mu rani E., Te Pas M.F.W., Chang K.C., Davoli R., Merls J.W.M., Henne H.Muraniova M. da Costa N. Harlizius B., Schellander L. Boll I. Braglia S., d e Wit A.A.C., Cagnazzo M. Fontanesi L., Pr in s D. Ponsuksili S. (2007). Associations of functional candidate genes derived from gene expression profiles of prenatal porcine muscle tissue with meat quality and muscle deposition. Anim. Genet., 3: 474-484.Search in Google Scholar

Wimmers K., Murani E., Ponsuksili S. (2010). Functional genomics and genetical genomics approaches towards elucidating networks of genes affecting meat performance in pigs. Brief. Funct. Genom. Proteom., 9: 251-258.Search in Google Scholar

Wolter B.F., Ellis M., Corrigan B.P., De Decker J.M. (2002). The effect of birth weight and feeding of supplemental milk replacer to piglets during lactation on preweaning and postweaning growth performance and carcass characteristics. J. Anim. Sci., 80: 301-308.Search in Google Scholar

Wu G., Bazer F.W., Wallace J.M., Spencer T.E. (2006). Board-invited review: Intrauterine growth retardation: implications for the animal sciences. J. Anim. Sci., 84: 2316-2337.Search in Google Scholar

Wu G., Bazer F.D., Datta S., Gao H., Johnson G.A., Lassala A., Li P., Satter­ field M.C., Spencer T.E. (2008). Intrauterine growth retardation in livestock: implications, mechanisms and solutions. Arch. Anim. Breed., 51, Special Issue, 1: 4-10.Search in Google Scholar

Wu G., Bazer F.W., Burghardt R.C., Johnson G.A., Kim S.W., Li X.L., Satter­ field M.C., Spencer T.E. (2010). Impacts of amino acid nutrition on pregnancy outcome in pigs: mechanisms and implications for swine production. J. Anim. Sci., 88 (13 Suppl.): E 195-204.Search in Google Scholar

Wu G., Bazer F.W., Satterfield M.C., Li X., Wang X., Johnson G.A., Burgh ardt R.C., Dai Z., Wang J., Wu Z. (2013). Impacts of arginine nutrition on embryonic and fetal develop­ment in mammals. Amino Acids. 4, Published online: 04 June 2013. Search in Google Scholar