The objective of this experiment was to compare the effect of sources of sulfate trace mineral (STM) and hydroxy trace mineral (HTM) at different inclusions on digestibility of dry matter (DM) and neutral detergent fiber and solubility of Cu, Mn, and Zn in the rumen and abomasum of cattle. Five ruminally cannulated steers were used in a 5×5 Latin square design and individually fed a corn silage-based diet on an ad libitum basis. The 5 dietary treatments were as follows: control: no supplemental Cu, Mn, or Zn, analyzed to contain 7.4mg of Cu, 30.8mg of Mn, and 32.1mg of Zn per kilogram of diet DM (CON); low sulfate: 5mg of Cu/kg of DM supplemented from CuSO4, 15mg of Mn/kg of DM from MnSO4, and 30mg of Zn/kg of DM from ZnSO4; low HTM: 5mg of Cu/kg of DM supplemented from basic copper chloride (IntelliBond C; Micronutrients Inc., Indianapolis, IN), 15mg of Mn/kg of DM from manganese hydroxychloride (IntelliBond M; Micronutrients Inc.), and 30mg of Zn/kg of DM from zinc hydroxychloride (IntelliBond Z; Micronutrients Inc.); high sulfate: 25mg of Cu/kg of DM supplemented from CuSO4, 60mg of Mn/kg of DM from MnSO4, and 120mg of Zn/kg of DM from ZnSO4; and high HTM: 25mg of Cu/kg of DM supplemented from basic copper chloride, 60mg of Mn/kg of DM from manganese hydroxychloride, and 120mg of Zn/kg of DM from zinc hydroxychloride. Periods lasted for 12d, with 10d of diet adaptation. Dacron bags containing the CON total mixed ration were inserted on d 11 at 0h and were removed at 6, 12, 24, and 36h after insertion. Dry matter and neutral detergent fiber disappearances and rumen and simulated abomasal trace mineral solubilities were evaluated. Dietary treatment did not affect DM intake. Dry matter disappearance was lesser in supplemental TM treatments and greater in CON than the STM treatments, although the CON and HTM treatments did not differ. Neutral detergent fiber disappearance was not affected by treatment. Ruminally soluble Cu and Mn concentrations were least in CON and were lesser in HTM-containing treatments compared with STM treatments. However, in the abomasum, solubilities of Cu and Mn were similar across trace mineral sources. Ruminal and simulated abomasal soluble Zn was greater in the HTM treatments than in CON and STM, driven by the greater solubility of the high HTM treatment. Under the conditions of this study, supplementing trace minerals as STM decreased DM digestibility, whereas HTM did not affect DM digestibility. Additionally, Cu and Mn from HTM sources were relatively insoluble in the rumen but had similar solubility as STM at the pH found in the abomasum, suggesting that these minerals should be available for absorption in the intestine.
Trace minerals (TM) are vital to health and growth of livestock, but low dietary concentrations and dietary antagonists may reduce mineral status and feeder cattle TM status is usually unknown at arrival. The objective of this study was to examine the effect of TM status on response to mineral injection in beef cattle. Forty steers were equally assigned to diets for an 84-d depletion period: control (CON; supplemental Cu, Mn, Se, and Zn) or deficient (DEF; no supplemental Cu, Mn, Se, or Zn plus Fe and Mo as TM antagonists). Lesser liver Cu and Se concentrations (79.0 ± 11.60 and 1.66 ± 0.080 mg/kg DM, respectively) in DEF steers compared with CON steers (228.8 ± 11.60 and 2.41 ± 0.080 mg/kg DM, respectively) on d 71 of depletion indicated mild deficiencies of these TM (P < 0.001). On d 1 of the 85-d repletion period, 10 steers within each dietary treatment were injected with sterilized saline (SAL) or Multimin90 (MM), containing 15, 10, 5, and 60 mg/mL of Cu, Mn, Se, and Zn, respectively, at a dose of 1 mL/68 kg BW. All steers were fed the same repletion diet supplemented with Cu, Mn, Se, and Zn to meet or exceed NRC recommendations. Blood was collected on d 0 and 1, and blood and liver biopsies were collected on d 8, 15, 29, 57, and 85 postinjection. Red blood cell lysate manganese-superoxide dismutase activity was greater in MM (P = 0.02), suggesting incorporation of injectable TM into a biological process. The increase in liver Se in response to MM was greater in CON vs. DEF (P = 0.02), suggesting TM from injection were used rather than stored in DEF steers. Liver Se and Cu (P < 0.05) were elevated through at least d 30 by MM. Dietary TM deficiency decreased neutrophil bacteria killing ability and increased myeloperoxidase (MPO) degranulation (P < 0.04) as measured on d 0, 1, 13, and 14 during the repletion period while injection had no impact. Within CON animals, total MPO was greater in animals that received TM injection, but injection did not affect MPO within DEF steers (P = 0.007). Overall, TM from an injectable mineral were used differently between TM adequate and mildly deficient steers.
To examine the effect of trace mineral (TM) status and TM injection on growth performance and carcass characteristics in beef cattle, 40 steers were used in a growing and finishing study. Steers were stratified by weight (323 ± 14.8 kg) and assigned to 1 of 2 treatments for an 84-d depletion period: 1) a corn silage-based diet supplemented with Cu, Mn, Se, and Zn to meet or exceed NRC recommendations (CON), or 2) CON diet without supplemental Cu, Mn, Se, or Zn but supplemented with 300 mg Fe and 5 mg Mo/kg diet DM as dietary TM antagonists (DEF) to induce mild deficiencies. To mimic shipping stress, steers were shipped for 20 h on d 88 and were received back on d 89. On d 91 an equal number of steers from both dietary treatments were injected with sterilized saline (SAL) or Multimin 90 (MM; containing 15, 60, 10, and 5 mg/mL of Cu, Zn, Mn, and Se, respectively) at a dose of 1 mL/68 kg BW. Steers were fed a common finishing diet supplemented with 10 mg Cu, 20 mg Mn, 0.1 mg Se, and 30 mg Zn/kg diet DM for the 90-d repletion period. Steers were harvested 91 d postinjection and carcass data were collected. During the depletion period, diet did not affect BW, ADG, DMI, or G:F (P > 0.20). During the shipping period (defined as the time between 2-d consecutive weights on d 83 and 84 and d 90 and 91), DEF steers tended to lose more weight per day than CON steers (P = 0.06) and had lesser DMI (P = 0.03), suggesting that response to shipping stress may be modulated by TM status. During the repletion period, ADG of DEF + MM steers was greater (P = 0.03) compared with DEF + SAL and was not different (P = 0.92) among CON + MM and CON + SAL steers. There was no effect of diet or injection on HCW or dressing percentage (P > 0.20). Within the CON group, TM injection decreased yield grade (P = 0.03) but did not affect yield grade of DEF steers (P > 0.20). Steers given TM injection had a larger rib eye area (P = 0.04) regardless of previous diet. Interestingly, both diet and injection affected marbling scores (MS), where CON steers had greater MS than DEF steers (P = 0.01) and MM steers had greater MS than SAL steers (P = 0.04). These results indicate that adequate TM nutrition is essential for marbling development, during both the growing and finishing phases. Overall, an injectable mineral improved rib eye area and MS regardless of initial TM status and improved growth of mildly TM deficient steers.
Drinking water can contain high concentrations of Fe, mainly of the ferrous (Fe(2+)) valence. The current recommended upper tolerable concentration of Fe in drinking water for cattle (0.3mg/L) comes from guidelines for human palatability, but cattle may be able to tolerate higher concentrations. Our objective was to determine the effects of varying concentrations of ferrous (Fe(2+)) or ferric (Fe(3+)) iron and Fe salt source on lactating dairy cows' preferences for and drinking behavior of water offered as choices ad libitum. In 4 separate experiments, cows were offered pairs of water treatments for 22-h periods and water intake and drinking behavior were recorded. In experiment 1, treatments were 0, 4, or 8 mg of total recoverable Fe/L from ferrous lactate. Cows exhibited no preference between water with 0 or 4 mg of Fe/L, but water intake was less with 8 compared with 0 or 4 mg of Fe/L. Also, cows spent less time drinking water containing 8 mg of Fe/L. Total time spent drinking correlated positively with water intake when pooled across treatments. In experiment 2, treatments were 0 or 8 mg of Fe/L from either ferrous sulfate (FeSO(4)) or ferric sulfate [Fe(2)(SO(4))(3)]. Water intake did not differ among treatments. In experiment 3, treatments were 0 (control), 12.5, or 8 mg of Fe/L from ferrous chloride (FeCl(2)) or ferric chloride (FeCl(3)), respectively. Again, cows exhibited no preference among treatments. In experiment 4, treatments were 0 or 8 mg of Fe/L from ferrous lactate [Fe(C(3)H(5)O(3))(2)], ferrous sulfate (FeSO(4)), or ferrous chloride (FeCl(2)). Cows preferred to drink water without added Fe, but did not exhibit any preference among waters containing the Fe sources with different anionic moieties. Cows spent less time drinking and drank less frequently when offered water containing 12.5mg of total recoverable Fe/L from ferrous chloride compared with 8.0mg of Fe/L from ferrous lactate or ferrous sulfate. Water intake correlated positively with both drinking duration and frequency when pooled across treatments in experiment 4. Overall, our results indicate that upon first exposure to drinking water, lactating dairy cows tolerate concentrations of Fe up to 4 mg/L from ferrous lactate without reducing water intake; however, water intake was reduced with 8 mg of total recoverable Fe. Preference did not appear to be influenced by Fe valence or added Fe source.
and Implications Adequate trace mineral status of feedlot cattle decreases losses during shipping and improves marbling score (MS). Utilizing an injectable trace mineral, at the start of the finishing period, improved average daily gain (ADG), body weight (BW) and hot carcass weight (HCW). Trace mineral supplementation is important to beef cattle performance, and improves response to stress. Injectable minerals improve recovery after a stressful event, and enhance performance.
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