1. bookVolume 14 (2014): Edizione 1 (January 2014)
Dettagli della rivista
License
Formato
Rivista
eISSN
2300-8733
ISSN
1642-3402
Prima pubblicazione
25 Nov 2011
Frequenza di pubblicazione
4 volte all'anno
Lingue
Inglese
Accesso libero

Effect of sow prolificacy and nutrition on preand postnatal growth of progeny – a review

Pubblicato online: 13 Feb 2014
Volume & Edizione: Volume 14 (2014) - Edizione 1 (January 2014)
Pagine: 3 - 15
Dettagli della rivista
License
Formato
Rivista
eISSN
2300-8733
ISSN
1642-3402
Prima pubblicazione
25 Nov 2011
Frequenza di pubblicazione
4 volte all'anno
Lingue
Inglese

Ashton C., Bayol S., Mcentee G., Maltby V., Stickland N. (2005). Prenatal influences on skeletal muscle development in mammals, birds and fish. Arch. Tierz., Dummerstorf, 48: 4-10.Search in Google Scholar

Beaulieu A.D., Aalhus 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

Bérard 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

Bérard 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

Boulot S., Quesnel H., Quiniou N. (2010). Management of high prolificacy in French herds: can we alleviate side effects on piglet survival? Pig Industry, Engormix.Search in Google Scholar

Brown L.D., Green A.S., Limesand S.W., Rozance P.J. (2011). Maternal amino acid supplementation for intrauterine growth restriction. Front. Biosci. (Schol Ed), 1, 3: 428-444.Search in Google Scholar

Brüssow K.P., Wähner M., Jaśkowski J.M. (2011). Biological limit of fecundity in sows - do they exist? EJPAU, 14, p. 3.Search in Google Scholar

Campos P.H., Silva B.A.N., Donzele J.L., Oliveira R.F.M., Knol E.F. (2012). Effects of sow nutrition during gestation on within-litter birth weight variation:areview. Animal, 6: 797-806.Search in Google Scholar

Canario L., Lundgren H., Haandlykken M., Rydhamer L. (2010). Genetics of growth in piglets and the association with homogeneity of body weight within litters. J. Anim. Sci., 88: 1240-1247.Search in Google Scholar

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

Chen Z.Y., Dziuk P.J. (1993). Influence of initial length of uterus per embryo and gestation stage on prenatal survival, development, and sex ratio in the pig. J. Anim. Sci., 71: 1895-1901.Search in Google Scholar

Chmurzyńska A. (2010). Fetal programming - link between early nutrition, DNAmethylation and complex diseases. Nutr. Rev., 68 (2): 87-98.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: E51-E60.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

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-E112.Search in Google Scholar

Funston R.N., Larson D.M., Vonnahme K.A. (2010). Effects of maternal nutrition on conceptus growth and offspring performance: implications for beef cattle production. J. Anim. Sci., 88: E205-E215.Search in Google Scholar

Gatford K.L., Ekert J.E., Blackmore K., De Blasio M.J., Boyce J.M., Owens J.A., Campbell R.G., Owens P.C. (2003). Variable maternal nutrition and growth hormone treatment in the second quarter of pregnancy in pigs alter semitendinosus muscle in adolescent progeny. Br. J. Nutr., 90: 283-293.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

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

Herpin P., Damon M., Le Dividich J. (2002). Development of thermoregulation and neonatal survival in pigs. Livest. Prod. Sci., 78: 25-45.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

Ishida M., Hiramatsu Y., Masuyama H., Mizutani Y., Kudo T. (2002). Inhibition of placental ornithine decarboxylase by DL-[alpha]-difluoro-methyl ornithine causes fetal growth restriction in rat. Life Sci., 70: 1395-1405.Search in Google Scholar

Johnson R.K., Nielsen M.K., Casey D.S. (1999). Responses in ovulation rate, embryonal survival, and litter traits in swine to 14 generations of selection to increase litter size. J. Anim. Sci., 77: 541-557.Search in Google Scholar

Koczanowski J., Kopyra M., Orzechowska B., Tyra M., Żak G., Nowicki J. (2006). Effect of feeding level after mating on embryo survival in purebred and crossbred gilts. Ann. Anim. Sci., Suppl., 2/2: 357-361.Search in Google Scholar

Lawlor P.G., Lynch P.B., Caffrey P.J., O ' Doherty J.V. (2002). Effect of pre- and postweaning management on subsequent pig performance to slaughter and carcass quality. Anim. Sci., 75: 245-256. Search in Google Scholar

Articoli consigliati da Trend MD

Pianifica la tua conferenza remota con Sciendo