Hypocalcemia in Dairy Cows: Meta-analysis and Dietary Cation Anion Difference Theory Revisited

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Hypocalcemia in Dairy Cows: Meta-analysis and Dietary Cation Anion Difference Theory Revisited

I. J. Lean^*^,1, P. J. DeGaris^*, D. M. McNeil and E. Block

^* Bovine Research Australasia, Camden 2570, NSW, Australia
MC Franklin Laboratory, Department of Veterinary Science, University of Sydney, Australia
Church & Dwight Co., Inc., Arm & Hammer Animal Nutrition Group, Princeton, NJ 08543

¹ Corresponding author: ianl{at}dairydocs.com.au

Data from 137 published trials involving 2,545 calvings wereanalyzed using random effects normal logistic regression modelsto identify risk factors for clinical hypocalcemia in dairycows. The aim of the study was to examine which form, if any,of the dietary cation anion difference (DCAD) equation providedthe best estimate of milk fever risk and to clarify roles ofcalcium, magnesium, and phosphorus concentrations of prepartumdiets in the pathogenesis of milk fever. Two statistically equivalentand biologically plausible models were developed that predictincidence of milk fever. These models were validated using datafrom 37 trials excluded from the original data used to generatethe models; missing variables were replaced with mean valuesfrom the analyzed data. The preferred models differed slightly;Model 1 included prepartum DCAD, and Model 2 included prepartumdietary concentrations of potassium and sulfur alone, but notsodium and chloride. Other factors, included in both modelswere prepartum dietary concentrations of calcium, magnesium,phosphorus; days exposed to the prepartum diet; and breed. Jerseycows were at 2.25 times higher risk of milk fever than Holsteincows in Model 1. The results support the DCAD theory of greaterrisk of milk fever with higher prepartum dietary DCAD (oddsratio = 1.015). The only DCAD equation supported in statisticalanalyses was (Na⁺ + K⁺) – (Cl^– + S^2–). Thisfinding highlights the difference between developing equationsto predict DCAD and those to predict milk fever. The resultssupport a hypothesis of a quadratic role for Ca in the pathogenesisof milk fever (model 1, odds ratio = 0.131; Model 2, odds ratio= 0.115). Milk fever risk was highest with a prepartum dietaryconcentration of 1.35% calcium. Increasing prepartum dietarymagnesium concentrations had the largest effect on decreasingincidence of milk fever in both Model 1 (odds ratio = 0.006)and Model 2 (odds ratio = 0.001). Increasing dietary phosphorusconcentrations prepartum increased the risk of milk fever (Model1, odds ratio = 6.376; Model 2, odds ratio = 9.872). The modelspresented provide the basis for the formulation of diets toreduce the risk of milk fever and strongly support the needto evaluate macro mineral nutrition apart from DCAD of the diet.

Key Words: milk fever • meta-analysis • dairy cow • dietary cation-anion difference

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