Addition of Chloride to a Prepartal Diet High in Cations Increases 1,25-Dihydroxyvitamin D Response to Hypocalcemia Preventing Milk Fever

Özlem

Acta Veterinaria Hungarica

et al. 2003

In this study, fractional excretions (Fe) of sodium (Na), potassium (K), chloride (Cl), calcium (Ca), magnesium (Mg) and phosphorus (PO 4 ) were examined with the aim to demonstrate interactions between fractional excretions of these electrolytes within each period and relate them to electrolyte metabolism in clinically normal cows at different stages of lactation and dry period. The material of this study consisted of 20 clinically healthy Holstein-Friesian cows of the same age and milk yield. Blood and urine samples were collected on 190-200th, 240-250th and 270-280th days of pregnancy and on days 1-7th, 35-45th and 75-85th after calving, altogether 6 times. An increase was observed in Fe Ca and Fe Mg during the transition from the lactation to the dry period (p < 0.05), and a decrease in Fe Ca (p < 0.05), Fe Mg (p < 0.01) in the 2nd month of the dry period. Fe PO4 and Fe Mg , respectively, increased on levels of p < 0.01 and p < 0.05, while Fe Ca decreased on a level of p < 0.05 after gestation compared to the level before gestation. Fe Na and Fe K showed a decrease of p < 0.001 and p < 0.01, respectively, between the 1st and 2nd months of the dry period, while after gestation this value showed an increase in Fe Na (p < 0.05) and Fe K (p < 0.01). Fe Cl increased significantly (p < 0.05) only from postpartum to the 1st month of lactation. There was a strong positive correlation between Fe Na and Fe Cl in all of the periods. It was concluded that there were significant changes in the Fe of Na, K, Cl, Ca, PO 4 and Mg before parturition and during lactation; these changes could have an important role in assessing renal function and electrolyte balance.Key words: Cow, fractional excretion, electrolytes, lactation, dry period Metabolic diseases associated with electrolyte disturbances in cattle, such as parturient paresis (hypocalcaemia), grass tetany (hypomagnesaemia), and displaced abomasum (alkalosis, hypochloraemia and hypokalaemia), develop predominantly before calving or in early lactation and have significant economic impact (Fleming et al

Section: Discussioncontrasting

confidence: 48%

“…Feeding low Ca-low PO 4 or anionic diets during the dry period tends to reduce hypocalcaemia, while high Ca-high PO 4 or cationic diets tend to induce it (Kichura et al, 1982;Gaynor et al, 1989;Goff et al, 1991). However, the effects of Ca and PO 4 contents in the anionic diet on mineral metabolism are not fully understood.…”

Section: Discussionmentioning

confidence: 96%

Fractional excretion of electrolytes during pre- and postpartum periods in cows

Özlem

Acta Veterinaria Hungarica

et al. 2003

“…It has been proposed that metabolic alkalosis reduces renal responsiveness to PTH (51) and that this may be reversed by metabolic acidification. Furthermore, improved responsiveness to calcitriol at a lower DCAD has been suggested (92) . However, a positive DCAD is not unique to the periparturient period.…”

Section: Reduction Of the Dietary Cation -Anion Differencementioning

confidence: 99%

“…A high DCAD has been explained as a negative factor for Ca metabolism (89,92,93) rather than a negative DCAD as a positive factor against milk fever. It has been proposed that metabolic alkalosis reduces renal responsiveness to PTH (51) and that this may be reversed by metabolic acidification.…”

Section: Reduction Of the Dietary Cation -Anion Differencementioning

confidence: 99%

A novel model to explain dietary factors affecting hypocalcaemia in dairy cattle

Martín-Tereso

Verstegen

2011

Nutr. Res. Rev.

Most dairy cows exhibit different degrees of hypocalcaemia around calving because the gestational Ca requirements shift to the disproportionately high Ca requirements of lactation. Ca homeostasis is a robust system that effectively adapts to changes in Ca demand or supply. However, these adaptations often are not rapid enough to avoid hypocalcaemia. A delay in the reconfiguration of intestinal Ca absorption and bone resorption is probably the underlying cause of this transient hypocalcaemia. Several dietary factors that affect different aspects of Ca metabolism are known to reduce the incidence of milk fever. The present review describes the interactions between nutrition and Ca homeostasis using observations from cattle and extrapolations from other species and aims to quantitatively model the effects of the nutritional approaches that are used to induce dry cows into an early adaptation of Ca metabolism. The present model suggests that reducing dietary cation -anion difference (DCAD) increases Ca clearance from the blood by dietary induction of systemic acidosis, which results in hypercalciuria due to the loss of function of the renal Ca transient receptor potential vanilloid channel TRPV5. Alternatively, reducing the gastrointestinal availability of Ca by reducing dietary Ca or its nutritional availability will also induce the activation of Ca metabolism to compensate for basal blood Ca clearance. Our model of gastrointestinal Ca availability as well as blood Ca clearance in the transition dairy cow allowed us to conclude that the most common dietary strategies for milk fever prevention may have analogous modes of action that are based on the principle of metabolic adaptation before calving.

“…This can lead to a delay in both the release of Ca from skeletal storage and active absorption in the small intestine when a sudden Ca demand is initiated . Anionic diets have been shown to increase both Ca absorption and skeletal mobilisation before parturition and therefore have been effective at reducing the incidence of hypocalcaemia (Fredeen et al, 1988;Goff et al, 1991;DeGroot et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Anionic salts and dietary 25-hydroxyvitamin D stimulate calcium availability in steers

McGrath

Savage

Nolan

et al. 2013

Animal

The influence of feeds containing varying dietary cation-anion differences (DCADs) with and without supplements of 25-hydroxyvitamin D (25(OH)D) on urine pH and excretion of macro minerals was determined in fistulated crossbred steers (mean live weight 315 6 45 kg). A basal forage diet comprising lucerne hay and wheat chaff was used, to which varying quantities of MgCl 2 or K 2 CO 3 were added to achieve four levels of DCAD: 2300, 50, 150 or 250 mEq/kg dry matter (DM). Steers were allocated to one of six treatments, one treatment for each diet and a further treatment for both the 50 and 150 mEq/kg DCAD diets, which were supplemented with 25(OH)D at a rate of 3 mg/steer per day. Urine pH from steers offered the diets comprising DCADs of 50, 150 and 250 mEq/kg ranging from 8.3 to 8.8. In treatments not containing 25(OH)D with DCADs of 50 to 250 mEq/kg, there were no significant differences in urine pH or Ca excretion. However, steers offered the diet with a DCAD of 2300 mEq/kg DM produced urine with a significantly lower pH (6.5 to 7.5). Daily output of Ca in urine was also significantly higher from steers given this diet. Supplementation with 25(OH)D significantly increased urinary Ca excretion from steers offered diets of DCADs 50 and 150 mEq/kg DM. Estimates of daily urinary Ca excretion, calculated using the ratio of creatinine to Ca in 'spot' urine samples, were less variable than those based on total collection (residual mean square of 0.54 and 0.63, respectively).