Modeling of daily body weights and body weight changes of Nordic Red cows.

Increased availability of automated weighing systems have made it possible to record massive amounts of body weight (BW) data in a short time. If the BW measurement is unbiased, the changes in BW reflect the energy status of the cow and can be used for management or breeding purposes. The usefulness of the BW data depends on the reliability of the measures. The noise in BW measurements can be smoothed by fitting a parametric or time series model into the BW measurements. This study examined the accuracy of different models to predict BW of the cows based on daily BW measurements and investigated the usefulness of modeling in increasing the value of BW measurements as management and breeding tools. Data included daily BW measurements, production, and intake from 230 Nordic Red dairy cows. The BW of the cows was recorded twice a day on their return from milking. In total, the data included 50,594 daily observations with 98,418 BW measurements. A clear diurnal change was present in the BW of the cows even if they had feed available 24 h. The daily average BW were used in the modeling. Five different models were tested: (1) a cow-wise fixed second-order polynomial regression model (FiX) including the exponential Wilmink term, (2) a random regression model with fixed and random animal lactation stage functions (MiX), (3) MiX with 13 periods of weighing added (PER), (4) natural cubic smoothing splines with 8 equally spaced knots (SPk8), and (5) spline model with no restriction on knots but a smoothing parameter corresponding to a fit of 5 degrees of freedom (SPdf5). In the original measured BW data, the within-animal variation was 6.4% of the total variance. Modeling decreased the within animal variation to levels of 2.9 to 5.1%. The smallest day-to-day variation and thereafter highest day-to-day repeatabilities were with PER and MiX models. The usability of modeled BW as energy balance (EB) indicator were evaluated by estimating relationships between EB, or EB indicators, and modeled BW change. In all cases the modeling increased the correlation and thus the reliability of the BW measurements. From all of the tested models, the best predictive value was attained by the random regression model with fixed and random animal lactation stage functions. Based on results, modeling of BW significantly increases the usefulness of BW as an EB predictor and management indicator.

[1]  R Core Team,et al.  R: A language and environment for statistical computing. , 2014 .

[2]  E. Mäntysaari,et al.  Energy efficiency and its relationship with milk, body, and intake traits and energy status among primiparous Nordic Red dairy cattle. , 2012, Journal of dairy science.

[3]  N. Friggens,et al.  On-farm estimation of energy balance in dairy cows using only frequent body weight measurements and body condition score. , 2012, Journal of dairy science.

[4]  M A Stevenson,et al.  The effect of clinical lameness on liveweight in a seasonally calving, pasture-fed dairy herd. , 2012, Journal of dairy science.

[5]  E. Mäntysaari,et al.  Predicting early lactation energy balance in primiparous Red Dairy Cattle using milk and body traits , 2010 .

[6]  E. Stamer,et al.  Evaluation of five lactation curve models fitted for fat:protein ratio of milk and daily energy balance. , 2010, Journal of dairy science.

[7]  C. Dechow,et al.  The genetic relationship of body weight and early-lactation health disorders in two experimental herds. , 2010, Journal of dairy science.

[8]  M. Friger,et al.  Associations among patterns in daily body weight, body condition scoring, and reproductive performance in high-producing dairy cows. , 2009, Journal of dairy science.

[9]  P. Mäntysaari,et al.  Effect of concentrate feeding strategy on the performance of dairy cows fed total mixed rations , 2008 .

[10]  Juha Nousiainen,et al.  Recent developments in forage evaluation with special reference to practical applications , 2008 .

[11]  N. Friggens,et al.  On the use of milk composition measures to predict the energy balance of dairy cows. , 2007, Journal of dairy science.

[12]  F. Buckley,et al.  Genetics of grass dry matter intake, energy balance, and digestibility in grazing irish dairy cows. , 2007, Journal of dairy science.

[13]  P. Huhtanen,et al.  Evaluation of the factors affecting silage intake of dairy cows: a revision of the relative silage dry-matter intake index. , 2007, Animal : an international journal of animal bioscience.

[14]  P. Mäntysaari,et al.  Effect of feeding frequency of a total mixed ration on the performance of high-yielding dairy cows. , 2006, Journal of dairy science.

[15]  T. Yan,et al.  Effects of dairy cow genotype with two planes of nutrition on energy partitioning between milk and body tissue. , 2006, Journal of dairy science.

[16]  N. St-Pierre,et al.  Prediction and evaluation of urine and urinary nitrogen and mineral excretion from dairy cattle. , 2006, Journal of dairy science.

[17]  J W West,et al.  Effects of heat-stress on production in dairy cattle. , 2003, Journal of dairy science.

[18]  G. C. Emmans,et al.  Genetic evaluation of dairy bulls for energy balance traits using random regression , 2001 .

[19]  L R Schaeffer,et al.  Relationships between energy balance and health traits of dairy cattle in early lactation. , 2000, Journal of dairy science.

[20]  T. Yan,et al.  Impact of recent research on energy feeding systems for dairy cattle , 2000 .

[21]  L. Kaal-Lansbergen,et al.  Modeling of energy balance in early lactation and the effect of energy deficits in early lactation on first detected estrus postpartum in dairy cows. , 1999, Journal of dairy science.

[22]  A. Bannink,et al.  Intake and excretion of sodium, potassium, and nitrogen and the effects on urine production by lactating dairy cows. , 1999, Journal of dairy science.

[23]  N. Gengler,et al.  Phenotypic variation in live weight and live-weight changes of lactating Holstein-Friesian cows , 1999 .

[24]  E. Maltz The body weight of the dairy cow: III. Use for on-line management of individual cows , 1997 .

[25]  R. Erdman,et al.  Factors affecting body tissue mobilization in early lactation dairy cows. 1. Effect of dietary protein on mobilization of body fat and protein. , 1997, Journal of dairy science.

[26]  R. F. Veerkamp,et al.  Sources of genetic variation in energetic efficiency of dairy cows , 1995 .

[27]  Y. Chilliard,et al.  Body composition of dairy cows according to lactation stage, somatotropin treatment, and concentrate supplementation. , 1991, Journal of dairy science.

[28]  J. Pedersen,et al.  A Nordic proposal for an energy corrected milk (ECM) formula , 1991 .

[29]  A. Chwalibog Energetic efficiency of milk production in Jersey cows , 1991 .

[30]  R. D. Goodrich,et al.  Within-herd variation in energy utilization for maintenance and gain in beef cows. , 1990, Journal of animal science.

[31]  Thomas B Farver,et al.  A Body Condition Scoring Chart for Holstein Dairy Cows , 1989 .

[32]  J.B.M. Wilmink,et al.  Adjustment of test-day milk, fat and protein yield for age, season and stage of lactation , 1987 .

[33]  C. R. Henderson Applications of linear models in animal breeding , 1984 .

[34]  C. Ferrell,et al.  Growth, development and composition of the udder and gravid uterus of beef heifers during pregnancy. , 1976, Journal of animal science.

[35]  Fisheries for Scotland. Energy allowances and feeding systems for ruminants , 1975 .