A decision support system to improve individual cattle management. 1. A mechanistic, dynamic model for animal growth

Abstract A deterministic and mechanistic growth model was developed to dynamically predict growth rate, accumulated weight, days required to reach target body composition, carcass weight (CW) and composition of individual beef cattle for use in individual cattle management systems. The model can predict either average daily gain (ADG) when dry matter intake (DMI) is known or dry matter required (DMR) when ADG is known. For both scenarios, the following parameters are required: metabolizable energy of the diet and length of feeding period, animal characteristics [age, gender, breed, initial body weight (BW), body condition score, and adjusted final BW at 28% empty body fat (EBF)] and environmental information (temperature, humidity, hours of sunlight, wind speed, mud, hair depth, and hair coat). Two iterative methods based on gain composition were derived to compute the efficiency of metabolizable energy to net energy for growth (NE g ). This growth model was evaluated with data from 362 individually fed steers with measured body composition and feed energy values predicted with the NRC (2000). The iterative method that used a decay equation to adjust NE g based on the proportion of retained energy as protein showed the best prediction of ADG and final BW. When dry matter intake was known, the model accounted for 89% of the variation with bias of −2.6% in predicting individual animal ADG and explained 83% of the variation with bias of −1% in estimating the observed BW at the actual total days on feed. When ADG was known, the growth model predicted the dry matter required for that ADG with only 2% of bias and r 2 of 74%. A sub-model was developed to predict accumulated body fat (FAT) for use in predicting carcass quality and yield grades (YG) during growth. With the unadjusted NE g method, this sub-model explained 84% of the variation and had −14.3% of bias in actual body fat when animal ADG was known. Additionally, an equation developed with 407 animals to predict YG from EBF (%) had an r 2 of 0.49. Equations developed to predict CW from empty BW that adjust for stage of growth accounted for 89% of the variation with a 3 kg of bias. In conclusion, this dynamic growth model can predict animal performance and body composition within an acceptable degree of accuracy.

[1]  J. Black,et al.  Effect of feeding system on performance and carcass characteristics of yearling steers, steer calves and heifer calves. , 1980, Journal of Animal Science.

[2]  D. Fox,et al.  Adjusting Nutrient Requirements of Beef Cattle for Animal and Environmental Variations , 1988 .

[3]  B. Young Temperature-induced changes in metabolism and body weight of cattle (Bos taurus). , 1975, Canadian journal of physiology and pharmacology.

[4]  R. Jarrige Ruminant nutrition : recommended allowances and feed tables , 1989 .

[5]  W. Garrett Energy utilization by growing cattle as determined in 72 comparative slaughter experiments. , 1980 .

[6]  G. P. Lofgreen,et al.  A system for expressing net energy requirements and feed values for growing and finishing beef cattle. , 1968 .

[7]  J. A. Stuedemann,et al.  Effect of nutritional level imposed from birth to eight months of age on subsequent growth and development patterns of full-fed beef calves. , 1968, Journal of animal science.

[8]  J. Thornley,et al.  A model of nutrient utilization and body composition in beef cattle , 1987 .

[9]  N. P. McMeniman,et al.  Feeding Standards for Australian Livestock Ruminants. , 1990 .

[10]  R. L. Baldwin,et al.  Modeling ruminant digestion and metabolism. , 1999, Advances in experimental medicine and biology.

[11]  F. Owens,et al.  Dry Matter Intake by Feedlot Beef Steers: Influence of Initial Weight, Time on Feed, and Season of Year Received in Yard , 1990 .

[12]  Harry M. Kaiser,et al.  Predicting nutritional requirements and lactation performance of dual-purpose cows using a dynamic model , 2004 .

[13]  D. Fox,et al.  Predicting carcass composition and individual feed requirement in live cattle widely varying in body size. , 1997, Journal of animal science.

[14]  F. Owens,et al.  Daily Dry Matter Intake By Feedlot Cattle: Influence of Breed and Gender , 1990 .

[15]  G. W. Davis,et al.  RELATIONSHIP OF USDA QUALITY GRADES TO PALATABILITY OF COOKED BEEF , 1987 .

[16]  James W. Oltjen,et al.  Development of a Dynamic Model of Beef Cattle Growth and Composition , 1986 .

[17]  D. Notter SIMULATED EFFICIENCY OF BEEF PRODUCTION FOR A COW-CALF-FEEDLOT MANAGEMENT SYSTEM. , 1977 .

[18]  J. R. Stouffer,et al.  Changes in Carcass Weight and Characteristics with Increasing Weight of Large and Small Cattle , 1983 .

[19]  R. R. Johnson,et al.  Relationship of Empty Body Weight to Carcass Weight in Beef Cattle , 1976 .

[20]  L. O. Tedeschi,et al.  Estudo da curva de crescimento de animais da raça Guzerá e seus cruzamentos alimentados a pasto, com e sem suplementação: 2. Avaliação dos parâmetros da curva de crescimento , 2000 .

[21]  W. Haresign,et al.  Recent Developments in Ruminant Nutrition , 1981 .

[22]  A. Mustafa,et al.  Evaluation of the 1996 NRC beef model under western Canadian environmental conditions. , 2001, Journal of animal science.

[23]  J. Keele,et al.  A computer model to predict empty body weight in cattle from diet and animal characteristics. , 1992, Journal of animal science.

[24]  T Mitsuhashi,et al.  Computer image analysis for prediction of carcass composition from cross-sections of Japanese Black steers. , 2001, Journal of animal science.

[25]  H. B. Hedrick,et al.  Effects of Ration Energy and Slaughter Weight on Composition of Empty Body and Carcass Gain of Beef Cattle , 1976 .

[26]  F. Owens,et al.  Review of some aspects of growth and development of feedlot cattle. , 1995, Journal of animal science.

[27]  E. W. Klosterman,et al.  Protein and Energy Utilization during Compensatory Growth in Beef Cattle , 1972 .

[28]  J. Joyce,et al.  Utilisation of metabolisable energy for fat and protein deposition in sheep , 1976 .

[29]  Oddy Vh,et al.  Understanding body composition and efficiency in ruminants : a non-linear approach. , 1997 .

[30]  A. Fortin,et al.  Effect of level of energy intake and influence of breed and sex on the chemical composition of cattle. , 1980, Journal of animal science.

[31]  P. Garnsworthy,et al.  13 – MODELLING NUTRIENT SUPPLY AND UTILIZATION BY RUMINANTS , 1991 .

[32]  D. M. Murray,et al.  The effect of three different growth rates on the chemical composition of the dressed carcass of cattle and the relationships between chemical and dissected components , 1975, The Journal of Agricultural Science.

[33]  D. E. Beever,et al.  Modelling Nutrient Utilization in Farm Animals , 2000 .

[34]  P. Osuji The physiology of eating and the energy expenditure of the r uminant at pasture. , 1974 .

[35]  J. Mcnamara,et al.  A mechanistic dynamic model of beef cattle growth. , 2000 .

[36]  D. Beermann,et al.  Effect of an implant of trenbolone acetate and estradiol on growth, feed efficiency, and carcass composition of Holstein and beef steers. , 1991, Journal of animal science.

[37]  D. Minson Predicting feed intake of food-producing animals , 1988 .

[38]  B. Cottrill,et al.  Energy and Protein Requirements of Ruminants , 1993 .

[39]  J. France,et al.  Biochemical Bases Needed for the Mathematical Representation of Whole Animal Metabolism , 1989, Nutrition Research Reviews.

[40]  P. L. Mitchell Misuse of regression for empirical validation of models , 1997 .

[41]  L. Turner,et al.  A body composition model for predicting beef animal growth , 1983 .

[42]  T G Jenkins,et al.  A computer model to predict composition of empty body weight changes in cattle at all stages of maturity. , 1998, Journal of animal science.

[43]  G. L. Bennett,et al.  A computer model to predict the effects of level of nutrition on composition of empty body gain in beef cattle: I. Theory and development. , 1992, Journal of animal science.

[44]  J. R. Black,et al.  A system for Predicting Body Composition and Performance of Growing Cattle , 1984 .

[45]  G. H. Wellington,et al.  Some Relationships Among the Major Chemical Components of the Bovine Body and their Application to Nutritional Investigations , 1955 .

[46]  K. Otagaki,et al.  Estimation of Empty Body Weight of Beef Cattle , 1962 .

[47]  G. L. Bennett,et al.  A computer model to predict the effects of level of nutrition on composition of empty body gain in beef cattle: II. Evaluation of the model. , 1992, Journal of animal science.

[48]  J. O. Sanders,et al.  A general cattle production systems model. Part 2—Procedures used for simulating animal performance , 1979 .

[49]  D. Fox,et al.  Compensatory Gain by Holstein Calves After Underfeeding Protein , 1988 .

[50]  Steven C. Chapra,et al.  Numerical methods for engineers: with software and programming applications / Steven C. Chapra, Raymond P. Canale , 2001 .

[51]  B. Young EFFECTS OF WINTER ACCLIMATIZATION ON RESTING METABOLISM OF BEEF COWS , 1975 .

[52]  L. Tedeschi,et al.  Predicting individual feed requirements of cattle fed in groups. , 2001, Journal of animal science.

[53]  Y. Geay Energy and protein utilization in growing cattle. , 1984, Journal of animal science.

[54]  T. Tylutki,et al.  Accounting for the effects of environment on the nutrient requirements of dairy cattle. , 1998, Journal of dairy science.

[55]  W. Garrett,et al.  Energy Cost of Protein and Fat Deposition in Sheep , 1974 .

[56]  W. Garrett,et al.  Re-Evaluation of the Relationship between Carcass Density and Body Composition of Beef Steers , 1969 .

[57]  L. Tedeschi,et al.  The effects of implant strategy on finished body weight of beef cattle. , 2002, Journal of animal science.

[58]  A. C. Bywater,et al.  Modelling animal growth , 1988 .

[59]  A.J.H. Van Es,et al.  The nutrient requirements of ruminant livestock , 1982 .

[60]  D. Johnson,et al.  Maintenance requirements of beef cattle as affected by season on different planes of nutrition. , 1991, Journal of animal science.

[61]  Gerhard Flachowsky,et al.  Recent Advances in Animal Nutrition in Australia , 2002 .

[62]  P. V. Soest,et al.  A net carbohydrate and protein system for evaluating cattle diets: III. Cattle requirements and diet adequacy. , 1992, Journal of animal science.

[63]  H. Fitzhugh,et al.  Analysis of growth curves and strategies for altering their shape. , 1976, Journal of animal science.

[64]  Luis Orlindo Tedeschi,et al.  Potential environmental benefits of ionophores in ruminant diets. , 2003, Journal of environmental quality.

[65]  L. Tedeschi,et al.  Energy requirement for maintenance and growth of Nellore bulls and steers fed high-forage diets. , 2002, Journal of animal science.