1. bookVolumen 22 (2022): Edición 4 (October 2022)
Detalles de la revista
Primera edición
25 Nov 2011
Calendario de la edición
4 veces al año
Acceso abierto

Effects of higher plasma growth hormone levels on subclinical ketosis in postpartum Holstein cows

Publicado en línea: 29 Oct 2022
Volumen & Edición: Volumen 22 (2022) - Edición 4 (October 2022)
Páginas: 1265 - 1272
Recibido: 24 Oct 2021
Aceptado: 29 Mar 2022
Detalles de la revista
Primera edición
25 Nov 2011
Calendario de la edición
4 veces al año

Accorsi P.A., Govoni N., Gaiani R., Pezzi C., Seren E., Tamanini C. (2005). Leptin, GH, PRL, insulin and metabolic parameters throughout the dry period and lactation in dairy cows. Reprod Domest Anim., 40: 217–223.10.1111/j.1439-0531.2005.00581.x Search in Google Scholar

Agenäs S., Burstedt E., Holtenius K. (2003). Effects of feeding intensity during the dry period. 1. Feed intake, body weight, and milk production. J Dairy Sci., 86: 870–82.10.3168/jds.S0022-0302(03)73670-4 Search in Google Scholar

Alshehabat M., Alekish M., Talafha A. (2016). Selected metabolic biochemical and enzyme activities associated with Besnoitia besnoiti infection in dairy cattle. Trop anim health prod., 48: 1301–1304.10.1007/s11250-016-1077-7 Search in Google Scholar

Caixeta L.S., Omontese B.O. (2021). Monitoring and Improving the Metabolic Health of Dairy Cows during the Transition Period. Animals (Basel), 11: 352.10.3390/ani11020352 Search in Google Scholar

Chelikani P.K., Ambrose J.D., Keisler D.H., Kennelly J.J. (2004). Effect of short-term fasting on plasma concentrations of leptin and other hormones and metabolites in dairy cattle. Domest Anim Endocri., 26, 33–48.10.1016/j.domaniend.2003.08.00314732451 Search in Google Scholar

Chen Y., Dong Z., Li R., Xu C. (2018). Changes in selected biochemical parameters (including FGF21) during subclinical and clinical ketosis in dairy cows. Med Wet., 74: 727–730.10.21521/mw.6133 Search in Google Scholar

Cooper-Prado M.J., Rubio I., Long N.M., Davis M.P., Spicer L.J., Wettemann R.P. (2018). Case Study: Effects of body weight gain and bovine somatotropin treatment of post-partum beef cows on concentrations of IGF-1, insulin, and glucose in blood plasma, luteal activity, and calf growth. The Profess Ani Scient., 34, 513–521.10.15232/pas.2018-01746 Search in Google Scholar

Csillik Z., Faigl V., Keresztes M., Galamb E., Hammon H.M., Tröscher A., Fébel H., Kulcsár M., Husvéth F., Huszenicza G., Butler W.R. (2017). Effect of pre-and postpartum supplementation with lipid-encapsulated conjugated linoleic acid on reproductive performance and the growth hormone–insulin-like growth factor-I axis in multiparous high-producing dairy cows. J Dairy Sci., 100: 5888–5898.10.3168/jds.2016-12124 Search in Google Scholar

Deniz A.B., Aksoy K., Metin M. (2020). Transition period and subclinical ketosis in dairy cattle: association with milk production, metabolic and reproductive disorders and economic aspects. Med Wet., 76: 9.10.21521/mw.6427 Search in Google Scholar

De Roos A.P., Van Den Bijgaart H.J., Hørlyk J., De Jong G. (2007). Screening for subclinical ketosis in dairy cattle by Fourier transform infrared spectrometry J Dairy Sci., 90: 1761–1766.10.3168/jds.2006-203 Search in Google Scholar

Du X., Chen L., Huang D., PengZ., Zhao, C., Zhang Y., Zhu Y., Wang Z., Li X., Liu G. (2017). Elevated apoptosis in the liver of dairy cows with ketosis. Cell Physio Biochem., 43: 568–578.10.1159/000480529 Search in Google Scholar

Du X., Zhu Y., Peng Z., Cui Y., Zhang Q., Shi Z., Guan Y., Sha X., Shen T., Yang Y., Li X. (2018). High concentrations of fatty acids and β-hydroxybutyrate impair the growth hormone-mediated hepatic JAK2-STAT5 pathway in clinically ketotic cows.J Dairy Sci., 101: 3476–3487.10.3168/jds.2017-13234 Search in Google Scholar

Duffield T., Lissemore K., McBride B., Leslie K. (2009). Impact of hyperketonemia in early lactation dairy cows on health and production. J Dairy Sci., 92: 571–580.10.3168/jds.2008-1507 Search in Google Scholar

IBM Corp. (2013). IBM SPSS Statistics for Windows, Version 22.0. IBM Corp., Armonk, NY. El-Kasrawy N.I., Swelum A.A., Abdel-Latif M.A. et al. (2020). Efficacy of Different Drenching Regimens of Gluconeogenic Precursors during Transition Period on Body Condition Score, Production, Reproductive Performance, Subclinical Ketosis and Economics of Dairy Cows. Animals (Basel), 10: 937.10.3390/ani10060937734149232485796 Search in Google Scholar

Enjalbert, F., Nicot, M., Bayourthe C., Moncoulon R. (2001). Ketone bodies in milk and blood of dairy cows: Relationship between concentrations and utilization for detection of subclinical ketosis. J Dairy Sci., 84: 583–589.10.3168/jds.S0022-0302(01)74511-0 Search in Google Scholar

Esposito G., Irons P.C., Webb E.C., Chapwanya A. (2014). Interactions between negative energy balance, metabolic diseases, uterine health and immune response in transition dairy cows. Ani Reproduc Sci., 144: 60–71.10.1016/j.anireprosci.2013.11.007 Search in Google Scholar

Flint D.J., Gardner M. (1994). Evidence that growth hormone stimulates milk synthesis by direct action on the mammary gland and that prolactin exerts effects on milk secretion by maintenance of mammary deoxyribonucleic acid content and tight junction status. Endocrino., 135: 1119–1124.10.1210/endo.135.3.8070355 Search in Google Scholar

Flores J., García J.E., Mellado J., Gaytán L., De Santiago A., Bosque M.M. (2019). Effect of growth hormone on milk yield and reproductive performance of subfertile Holstein cows during extended lactations. Span J Agri Res., 17: 11.10.5424/sjar/2019171-13842 Search in Google Scholar

Gabai G., Cozzi G., Rosi F., Andrighetto I., Bono G. (2002). Glucose or essential amino acid infusions in late pregnant and early lactating Simmenthal cows failed to induce a leptin response. J Vet Med Ser A., 49: 73–80.10.1046/j.1439-0442.2002.jv419.x Search in Google Scholar

Garry B., Ganche E., Hennessy D., O’Donovan M., Murphy J.P., Kennedy E. (2021). Restricting dairy cow access time to pasture in autumn: The effects on milk production, grazing behaviour and DM intake of late lactation dairy cows. Animal, 15: 100335.10.1016/j.animal.2021.100335 Search in Google Scholar

Gross J., van Dorland H. A., Bruckmaier R., Schwarz F. (2011). Performance and metabolic profile of dairy cows during a lactational and deliberately induced negative energy balance with subsequent realimentation. J Dairy Sci., 94: 1820–1830.10.3168/jds.2010-3707 Search in Google Scholar

Gross J.J., Bruckmaier R.M. (2019). Metabolic challenges in lactating dairy cows and their assessment via established and novel indicators in milk. Animal, 13: 75–81.10.1017/S175173111800349X Search in Google Scholar

Grummer R.R. (2008). Nutritional and management strategies for the prevention of fatty liver in dairy cattle. The Vet J., 176: 10–20.10.1016/j.tvjl.2007.12.033 Search in Google Scholar

Hayirli A., Grummer R., Nordheim E., CrumpP. (2003). Models for predicting dry matter intake of Holsteins during the prefresh transition period. J Dairy Sci., 86: 1771–1779.10.3168/jds.S0022-0302(03)73762-X Search in Google Scholar

He, B.X., Du X.H., Du Y.L., He Q.Q., Mohsin M.A. (2018). Association of Prepartum Hypoleptinemia and Postpartum Subclinical Ketosis in Holstein Dairy Cows. Pak Vet J., 38: 404–408.10.29261/pakvetj/2018.087 Search in Google Scholar

Herdt T.H. (2000). Ruminant adaptation to negative energy balance: Influences on the etiology of ketosis and fatty liver. Veterinary Clinics: Food Ani Pract., 16: 215–230.10.1016/S0749-0720(15)30102-X Search in Google Scholar

Huang Y., Li Y., He B., Hu J., Mohsin. M.A.., Yu H., Wang P., Zhang P., Du Y., Huang L., Shen W. (2019). The Influence of Ketosis on the Rectal Microbiome of Chinese Holstein Cows. Pak Vet J., 39: 175–180.10.29261/pakvetj/2019.041 Search in Google Scholar

Huang Y., Oikonomou, G., Hu, J., Li, Y., Du, X., Du, Y., Liu, Y., Zhang, P., Wang, P., Yu, H. and Tu, J., 2019a. Effect of feeding grape seed Proanthocyanidin extract on production performance, metabolic and anti-oxidative status of dairy cattle. Arquivo Brasileiro de Medicina Veterinária e Zootecnia., 71: 1207–1216.10.1590/1678-4162-10957 Search in Google Scholar

Itle A., Huzzey J., Weary D., Von Keyserlingk M. (2015). Clinical ketosis and standing behavior in transition cows. J Dairy Sci., 98: 128–134.10.3168/jds.2014-7932 Search in Google Scholar

Knob D.A., Thaler Neto A., Schweizer H., Weigand AC., Kappes R., Scholz A.M. (2021). Energy Balance Indicators during the Transition Period and Early Lactation of Purebred Holstein and Simmental Cows and Their Crosses. Animals (Basel), 11: 309.10.3390/ani11020309 Search in Google Scholar

KongF., Yang, J., Zhen Z., Liang T., Zhu D., Gao R., Xie G. (2015). Gene cloning and molecular characterization of a β-glucosidase from Thermotoga naphthophila RUK-10: an effective tool for synthesis of galacto-oligosaccharide and alkyl galactopyranosides. Chem Res Chin Univ., 31: 774–780.10.1007/s40242-015-5179-y Search in Google Scholar

Kronfeld D.S. (1965). Growth hormone-induced ketosis in the cow. J Dairy Sci., 48: 342–346.10.3168/jds.S0022-0302(65)88225-X Search in Google Scholar

Muiño R., Hernández J., Benedito J.L., Castillo C. (2021). Effects of Calving Body Condition Score on Blood Acid–Base Balance of Primiparous Holstein-Friesian Dairy Cows in a Commercial Dairy Farm: A Case Study. Animals (Basel), 11: 2075.10.3390/ani11072075 Search in Google Scholar

Overton T.R., Waldron M.R. (2004). Nutritional management of transition dairy cows: strategies to optimize metabolic health. J Dairy Sci., 87: 105–19.10.3168/jds.S0022-0302(04)70066-1 Search in Google Scholar

Pascottini O.B., Leroy J.L.M.R., Opsomer G. (2020). Metabolic Stress in the Transition Period of Dairy Cows: Focusing on the Prepartum Period. Animals (Basel), 10: 1419.10.3390/ani10081419 Search in Google Scholar

Raboisson D., Mounié M., Maigne E. (2014). Diseases, reproductive performance, and changes in milk production associated with subclinical ketosis in dairy cows: A meta-analysis and review. J Dairy Sci., 97: 7547–7563.10.3168/jds.2014-8237 Search in Google Scholar

Reynolds C., Aikman P., Lupoli B., Humphries D., Beeve, D. (2003). Splanchnic metabolism of dairy cows during the transition from late gestation through early lactation J Dairy Sci., 86: 1201–1217.10.3168/jds.S0022-0302(03)73704-7 Search in Google Scholar

Sangalli J.R., Sampaio R.V., Del Collado M., da Silveira J.C., De Bem T.H.C., Perecin F., Smith L.C., Meirelles F.V. (2018). Metabolic gene expression and epigenetic effects of the ketone body β-hydroxybutyrate on H3K9ac in bovine cells, oocytes and embryos. Sci Rep., 8: 1–18.10.1038/s41598-018-31822-7 Search in Google Scholar

Silva P.R., Soares H.F., Braz W.D., Bombardelli G.D., Clapper J.A., Keisler D.H., Chebel R.C. (2017). Effects of treatment of periparturient dairy cows with recombinant bovine somatotropin on health and productive and reproductive parameters. J Dairy Sci., 100, 3126–3142.10.3168/jds.2016-1173728215881 Search in Google Scholar

Strączek I., Młynek K., Danielewicz A. (2021). The Capacity of Holstein-Friesian and Simmental Cows to Correct a Negative Energy Balance in Relation to Their Performance Parameters, Course of Lactation, and Selected Milk Components. Animals (Basel), 11: 1674.10.3390/ani11061674 Search in Google Scholar

Wang X., Li X., Zhao C., Hu P., Chen H., Liu Z., Liu G., Wang Z. (2012). Correlation between composition of the bacterial community and concentration of volatile fatty acids in the rumen during the transition period and ketosis in dairy cows. Appl Environ Microbio., 78: 2386–2392.10.1128/AEM.07545-11 Search in Google Scholar

Wang Y., Huo P., Sun Y., Zhang Y. (2019). Effects of Body Condition Score Changes During Peripartum on the Postpartum Health and Production Performance of Primiparous Dairy Cows. Animals (Basel), 9: 1159.10.3390/ani9121159 Search in Google Scholar

Wang Y.P.; Cai M., Hua D.K., Zhang F., Jiang L.S., Zhao Y.G., Wang,H., Nan X.M., Xiong B.H. (2020). Metabolomics reveals effects of rumen-protected glucose on metabolism of dairy cows in early lactation. Ani Feed Sci and Techn., 269: 114620.10.1016/j.anifeedsci.2020.114620 Search in Google Scholar

[42]. Williams W.F., Lee S.D., Head HH., Lynch J. (1963). Growth hormone effects on bovine blood plasma fatty acid concentration and metabolism. J Dairy Sci., 46: 1405140–8.10.3168/jds.S0022-0302(63)89290-5 Search in Google Scholar

[10]. Wu Z.L., Chen S.Y., Jia X., Wang J., Lai S.J. (2020). Metabolomic and Proteomic Profiles Associated With Ketosis in Dairy Cows. Front in Genetics, 11: 1542.10.3389/fgene.2020.551587 Search in Google Scholar

Xia C., Wang Z., Liu G.W., Zhang H.Y., Zhang C, Xu C. (2009). Changes of plasma metabolites, hormones, and mRNA expression of liver PEPCK-C in spontaneously ketotic dairy cows. Asian-Australas j Anim Sci., 23, 47–51.10.5713/ajas.2010.70307 Search in Google Scholar

Youssef M., El-Ashker M. (2017). Significance of insulin resistance and oxidative stress in dairy cattle with subclinical ketosis during the transition period. Tropl Ani Health Produc., 49: 239–244.10.1007/s11250-016-1211-6 Search in Google Scholar

Artículos recomendados de Trend MD