TY - JOUR
T1 - Prediction of metabolic clusters in early-lactation dairy cows using models based on milk biomarkers
AU - GplusE
AU - De Koster, J.
AU - Salavati, M.
AU - Grelet, C.
AU - Crowe, M. A.
AU - Matthews, E.
AU - O'Flaherty, R.
AU - Opsomer, G.
AU - Foldager, L.
AU - Hostens, M.
AU - Alan, Fahey
AU - Fiona, Carter
AU - Elizabeth, Matthews
AU - Andreia, Santoro
AU - Colin, Byrne
AU - Pauline, Rudd
AU - Roisin, O'Flaherty
AU - Sinead, Hallinan
AU - Claire, Wathes
AU - Zhangrui, Cheng
AU - Ali, Fouladi
AU - Geoff, Pollott
AU - Dirk, Werling
AU - Beatriz Sanz, Bernardo S.
AU - Conrad, Ferris
AU - Alistair, Wylie
AU - Matt, Bell
AU - Mieke, Vaneetvelde
AU - Kristof, Hermans
AU - Sander, Moerman
AU - Hannes, Bogaert
AU - Jan, Vandepitte
AU - Leila, Vandevelde
AU - Bonny, Vanranst
AU - Klaus, Ingvartsen
AU - Martin Tang, Sorensen T.
AU - Johanna, Hoglund
AU - Susanne, Dahl
AU - Soren, Ostergaard
AU - Janne, Rothmann
AU - Mogens, Krogh
AU - Else, Meyer
AU - Leslie, Foldager
AU - Charlotte, Gaillard
AU - Jehan, Ettema
AU - Tine, Rousing
AU - Torben, Larsen
AU - de, de Oliveira
AU - Cinzia, Marchitelli
AU - Federica, Signorelli
AU - Francesco, Napolitano
N1 - Funding Information:
This project received funding from the European Union's Seventh Framework Programme (Brussels, Belgium) for research, technological development, and demonstration under grant agreement no. 613689. The views expressed in this publication are the sole responsibility of the authors and do not necessarily reflect the views of the European Commission.
Publisher Copyright:
© 2019 American Dairy Science Association
PY - 2019/3
Y1 - 2019/3
N2 - The aim of this study was to describe metabolism of early-lactation dairy cows by clustering cows based on glucose, insulin-like growth factor I (IGF-I), free fatty acid, and β-hydroxybutyrate (BHB) using the k-means method. Predictive models for metabolic clusters were created and validated using 3 sets of milk biomarkers (milk metabolites and enzymes, glycans on the immunogamma globulin fraction of milk, and Fourier-transform mid-infrared spectra of milk). Metabolic clusters are used to identify dairy cows with a balanced or imbalanced metabolic profile. Around 14 and 35 d in milk, serum or plasma concentrations of BHB, free fatty acids, glucose, and IGF-I were determined. Cows with a favorable metabolic profile were grouped together in what was referred to as the “balanced” group (n = 43) and were compared with cows in what was referred to as the “other balanced” group (n = 64). Cows with an unfavorable metabolic profile were grouped in what was referred to as the “imbalanced” group (n = 19) and compared with cows in what was referred to as the “other imbalanced” group (n = 88). Glucose and IGF-I were higher in balanced compared with other balanced cows. Free fatty acids and BHB were lower in balanced compared with other balanced cows. Glucose and IGF-I were lower in imbalanced compared with other imbalanced cows. Free fatty acids and BHB were higher in imbalanced cows. Metabolic clusters were related to production parameters. There was a trend for a higher daily increase in fat- and protein-corrected milk yield in balanced cows, whereas that of imbalanced cows was higher. Dry matter intake and the daily increase in dry matter intake were higher in balanced cows and lower in imbalanced cows. Energy balance was continuously higher in balanced cows and lower in imbalanced cows. Weekly or twice-weekly milk samples were taken and milk metabolites and enzymes (milk glucose, glucose-6-phosphate, BHB, lactate dehydrogenase, N-acetyl-β-D-glucosaminidase, isocitrate), immunogamma globulin glycans (19 peaks), and Fourier-transform mid-infrared spectra (1,060 wavelengths reduced to 15 principal components) were determined. Milk biomarkers with or without additional cow information (days in milk, parity, milk yield features) were used to create predictive models for the metabolic clusters. Accuracy for prediction of balanced (80%) and imbalanced (88%) cows was highest using milk metabolites and enzymes combined with days in milk and parity. The results and models of the present study are part of the GplusE project and identify novel milk-based phenotypes that may be used as predictors for metabolic and performance traits in early-lactation dairy cows.
AB - The aim of this study was to describe metabolism of early-lactation dairy cows by clustering cows based on glucose, insulin-like growth factor I (IGF-I), free fatty acid, and β-hydroxybutyrate (BHB) using the k-means method. Predictive models for metabolic clusters were created and validated using 3 sets of milk biomarkers (milk metabolites and enzymes, glycans on the immunogamma globulin fraction of milk, and Fourier-transform mid-infrared spectra of milk). Metabolic clusters are used to identify dairy cows with a balanced or imbalanced metabolic profile. Around 14 and 35 d in milk, serum or plasma concentrations of BHB, free fatty acids, glucose, and IGF-I were determined. Cows with a favorable metabolic profile were grouped together in what was referred to as the “balanced” group (n = 43) and were compared with cows in what was referred to as the “other balanced” group (n = 64). Cows with an unfavorable metabolic profile were grouped in what was referred to as the “imbalanced” group (n = 19) and compared with cows in what was referred to as the “other imbalanced” group (n = 88). Glucose and IGF-I were higher in balanced compared with other balanced cows. Free fatty acids and BHB were lower in balanced compared with other balanced cows. Glucose and IGF-I were lower in imbalanced compared with other imbalanced cows. Free fatty acids and BHB were higher in imbalanced cows. Metabolic clusters were related to production parameters. There was a trend for a higher daily increase in fat- and protein-corrected milk yield in balanced cows, whereas that of imbalanced cows was higher. Dry matter intake and the daily increase in dry matter intake were higher in balanced cows and lower in imbalanced cows. Energy balance was continuously higher in balanced cows and lower in imbalanced cows. Weekly or twice-weekly milk samples were taken and milk metabolites and enzymes (milk glucose, glucose-6-phosphate, BHB, lactate dehydrogenase, N-acetyl-β-D-glucosaminidase, isocitrate), immunogamma globulin glycans (19 peaks), and Fourier-transform mid-infrared spectra (1,060 wavelengths reduced to 15 principal components) were determined. Milk biomarkers with or without additional cow information (days in milk, parity, milk yield features) were used to create predictive models for the metabolic clusters. Accuracy for prediction of balanced (80%) and imbalanced (88%) cows was highest using milk metabolites and enzymes combined with days in milk and parity. The results and models of the present study are part of the GplusE project and identify novel milk-based phenotypes that may be used as predictors for metabolic and performance traits in early-lactation dairy cows.
KW - dairy cow
KW - metabolic clustering
KW - milk biomarker
KW - prediction
UR - http://www.scopus.com/inward/record.url?scp=85060529750&partnerID=8YFLogxK
U2 - 10.3168/jds.2018-15533
DO - 10.3168/jds.2018-15533
M3 - Article
C2 - 30692010
AN - SCOPUS:85060529750
SN - 0022-0302
VL - 102
SP - 2631
EP - 2644
JO - Journal of Dairy Science
JF - Journal of Dairy Science
IS - 3
ER -