硒与维生素E互作对动物的影响

硒和维生素E是动物必需的营养成分,它们之间存在有协同关系,但是不可互相代替。两者的互作对动物生长性能、繁殖性能、胴体品质、免疫和应激等都有显著影响,具有极其重要的作用。     

Blood and milk status of vitamin E,vitamin A,and selenium in nursing Awassi ewes injected with vitamin E and selenium

Abstract

This study investigated the effects of vitamin E and selenium (Se) injections on concentrations of vitamin E, vitamin A, and Se in blood and milk to predict when injections may improve ewes’ performance. Awassi ewes received 0 (control, 13 ewes) or 15 plus 0.05?mg/kg BW of vitamin E and Se (injected, 15 ewes) at 1 and 4 weeks postpartum. Blood and milk samples were collected weekly for 6 weeks. Injections increased vitamin E, decreased Se, and had no effects on vitamin A levels in blood. Blood vitamin E was correlated positively with vitamin A. Injections increased vitamin E, but had no effects on vitamin A or Se levels in milk. Milk vitamin A was positively correlated with vitamin E and Se levels in the control group. Milk vitamins E and A were positively correlated with their corresponding levels in blood. Milk somatic cell count was negatively correlated with blood vitamin A levels.     

Effects of selenium and vitamin E supplementation on selenium distribution and meat quality of pigs

Abstract

The study was conducted on 60 pigs kept in individual pens. The animals were allocated to four groups. The growing-finishing pigs from the control group were fed with basic feed containing 0.3 mg selenium (Se) derived from Na₂SeO₃ kg^?1 and 60 mg of dl-α-tocopheryl acetate kg^?1. The remaining three groups were differentiated by adding 0.2 mg kg^?1 Se-enriched yeast (Saccharomyces cerevisiae) and/or 60 mg vitamin E to feed (grower and finisher). Our results show that the addition of organic Se to inorganic Se commonly used in pig feed caused a significant increase in hepatic Se and muscle. This indicates the possibility of using these products as functional foods to improve Se status in humans residing within regions which are deficient in this trace element. We found no beneficial effect of supplementation with vitamin E and Se on the quality of the meat.     

The effect of dietary vitamin E level on selenium status in rats

The effect of varying levels of dietary vitamin E on selenium status was determined using 40 Wistar rats with similar initial body weight. The rats were equally divided into four groups and fed the following dietary treatments (mg vitamin E/kg DM): 18 (control; C‐diet), 0 (0E‐diet), 9 (0.5E‐diet) and 36 (2E‐diet) for either 4‐week (Phase 1) or 8‐week (Phase 2) period. At the end of experiment, animals were slaughtered to measure vitamin E and selenium levels in the brain, liver, spleen, kidney, muscles and blood tissues. Dietary vitamin E levels did not affect feed and water intake and body weight. But whole‐blood selenium concentration in rats fed 0E‐diet was higher than in rats fed 2E‐diet after 4 weeks. Selenium level in muscle, spleen and brain was also higher (p < 0.05) in rats fed the 0E‐diet than in rats fed C‐diet after 4 weeks of feeding. On the other hand, selenium level in the muscle was lower (p < 0.05) in rats fed 0.5E‐diet than in those fed 0E‐diet after 4 weeks of feeding, but not after 8 weeks of feeding. Increasing dietary vitamin E level directly influenced selenium content of the spleen and brain after 8 weeks of feeding 2E‐diet. Moreover, the twofold increase in vitamin E intake resulted in a tendency to reduce whole‐blood selenium level and total selenium in the liver and kidney after 4 and 8 weeks. The results showed that the increasing dietary vitamin E level resulted in a tendency to reduce Se contents in some vital organs of the body such as the liver and kidney, suggesting their close compensatory interrelationship. Therefore, dietary vitamin E level directly influenced selenium metabolism in the animal body.     

The selenium and vitamin E status of horses in Prince Edward Island

Serum selenium (Se), vitamin E, and resting thyroid hormone concentrations were measured in 201 horses in Prince Edward Island (PEI). Selenium concentrations were either marginal (0.0053 to 0.1200 ppm) or deficient (< 0.0053 ppm) in 79% of horses based on current reference ranges for Se in serum. Aged and young adult pleasure horses had a higher prevalence of inadequate Se concentrations compared to racehorses and broodmares (82% and 97% versus 45% and 72%, respectively). Overall, 13% of horses had inadequate (< 200 μg/dL) serum vitamin E concentrations; most of these were young pleasure horses. No horses were hypothyroid and, contrary to findings in other species, there was a positive relationship between serum thyroxine and Se concentrations (P < 0.05). We conclude that Se deficiency is widespread in PEI horse populations, especially in pleasure horses, and vitamin E deficiency is more common in young pleasure horses. Micronutrient supplementation practices employed by PEI horse owners appear inadequate to ensure sufficiency.     

Selenium and vitamin E deficiency in pigs. II. Influence on plasma selenium, vitamin E, ASAT and ALAT and on tissue selenium.

The effect of dietary selenium (Se) and vitamin E (Vit. E) in pigs on Se and Vit. E in plasma and on Se in tissue from liver, heart, m. long, dorsi and m. psoas major was studied; and furthermore was the influence on the enzymes ASAT and ALAT studied.Two levels of Se were used, 0.03 and 0.06 mg Se per kg feed. Within each Se level 2 levels of Vit. E were used, 15 and 45 i. u. per kg feed. This resulted in 4 groups: 1. low Se and low Vit. E; 2. low Se and high Vit. E; 3. high Se and low Vit. E; 4. high Se and high Vit. E.Ten% of all pigs fed low Se, and 4% of the pigs fed low Se and high Vit. E diet died with severe symptoms of Se deficiency. None of the pigs fed the high Se diet died with such symptoms. Plasma Se determinations have been shown to indicate the Se status in pigs almost as accurately as liver Se determination. ASAT and ALAT enzyme determinations were not of any diagnostic value.There was a good agreement between dietary Vit. E level and the corresponding levels in plasma. Oxidized herring oil seems to enhance the Vit. E need.     

有机硒和维生素E对母猪生产性能的影响

试验采用随机区组设计,2×2因子设计,在相同的日粮基础上,妊娠期和哺乳期分别添加0.3 mg/kg亚硒酸钠(以硒计)+22 IU/kg VE0、.3 mg/kg酵母硒(以硒计)+22 IU/kgVE0、.3 mg/kg亚硒酸钠(以硒计)+44 IU/kg VE、0.3 mg/kg酵母硒(以硒计)+44 IU/kg VE的日粮。结果表明:妊娠1 d、妊娠60 d、哺乳3 d、哺乳14 d,0.3 mg/kg酵母硒(以硒计)+44 IU/kg VE的日粮获得母猪血清中硒的最高含量。妊娠1 d、妊娠60 d、哺乳3 d、哺乳14 d,各处理母猪血清中抗氧化指标GSH-PX差异不显著。哺乳3 d、哺乳14 d各阶段均反映出0.3 mg/kg酵母硒(以硒计)+44 IU/kg VE的日粮获得乳猪血清中硒的最高含量。不同处理对不同阶段乳猪血清中GSH-PX的含量,哺乳第3 d各处理差异不显著;哺乳14 d添加0.3 mg/kg亚硒酸钠(以硒计)+22 IU/kg VE的处理和0.3 mg/kg酵母硒(以硒计)+44 IU/kg VE处理差异显著(P0.05)。     

Effect of dietary selenium and vitamin E on spermatogenic development in boars

An experiment involving a total of 61 crossbred boars evaluated the effects of dietary Se and vitamin E on spermatogenic development at various stages of sexual development and the prostaglandin F2alpha (PGF2alpha) content in the seminal vesicle and prostate glands at 18 mo of age. The experiment from 5.4 to 9 mo of age was conducted as a 2 x 2 factorial in a randomized complete block design. Dietary Se at 0 or .5 ppm was the first factor and vitamin E at 0 or 220 IU/kg diet was the second. From 9 to 18 mo of age, a group of sexually active and inactive boars was a third factor. Treatment diets were fed from weaning (28 d of age) to the end of the experiment. Three boars per treatment group at 5.4 (105 kg BW), 6.2 (130 kg BW), and 9.0 (150 kg BW) mo of age were killed and the testes collected. From 9 to 18 mo of age, three boars from each dietary treatment group were used for semen collection, and another set of three to four boars from each treatment group remained sexually inactive. At 18 mo, both sets of boars were killed and their testes, prostates, and seminal vesicles were collected. The testis at each age was evaluated for sperm reserve numbers and germ and Sertoli cell populations. At 5.4 or 6.2 mo of age, testicular sperm reserves were not affected by dietary Se (P > .15), at 9.0 mo of age there was a trend for a higher (P < .10) number of sperm reserves, and by 18 mo of age the Se-fed boars had higher (P < .01) numbers of sperm reserves. Vitamin E had no effect (P > .15) on testicular sperm reserves at any age period. Boars fed dietary Se had a greater number of Sertoli cells (P < .01) and round spermatids (P < .01) at 6.2 mo of age, but by 18 mo of age the boars fed Se had more Sertoli cells (P < .05), more secondary spermatocytes (P < .01), and more round spermatids (P < .05). Vitamin E did not affect Sertoli or germ cell populations at the various ages. Boars at 18 mo of age had lower PGF2alpha concentrations in the prostate (P < .05) and seminal vesicles (P < .01) when vitamin E was fed, whereas Se had no effect. Sexually active boars had lower PGF2alpha concentrations in the seminal vesicles (P < .01) than sexually inactive boars, but there was no effect (P > .15) of sexual activity on the number of Sertoli cells, primary or secondary spermatocytes, or round spermatids. Our results indicate that Se has a role in establishing the number of boar spermatozoal reserves and Sertoli cells, whereas supplemental vitamin E did not affect these criteria.     

Influence of vitamin E and selenium supplement on antibody production in horses

Fifteen horses used for serum production were maintained on low vitamin E and selenium diets. They were divided into four groups receiving: Group 1 no supplements, Group 2 vitamin E, Group 3 selenium and Group 4 both vitamin E and selenium. The humoral immune response to novel antigens, such as tetanus toxoid and equine influenza virus, was increased in groups receiving either vitamin E or selenium/vitamin E. No effects were recorded on the titres against Escherichia coli or the levels of immunoglobulin G.     

Parenteral selenium and vitamin E supplementation of weaned beef calves

BACKGROUND: The weaning process in beef calves elicits physiological stress responses that can negatively affect performance and health. Supplementation of vitamins and minerals, particularly selenium (Se) and vitamin E, might be warranted. HYPOTHESIS: That parenteral administration of Se or vitamin E would correct or prevent deficiencies of these nutrients in postweaned beef calves during a backgrounding period (42 days after weaning). ANIMALS: One hundred and forty-four weaned steers (200-250 kg) in 3 trials. METHODS: One trial was conducted with cattle on a dry lot fed a total mixed ration and 2 trials were conducted on cattle on pasture. Selenium was administered at 0.05 mg/kg BW (SC) and vitamin E was administered at 1500 IU on days 0 and 28 (SC). RESULTS: A treatment effect attributable to Se or vitamin E supplementation on average daily gain was not detected in any trials. Parenteral supplementation with Se on days 0 and 28 resulted in higher serum Se concentrations as compared with controls on day 42. Parenteral supplementation with Se on days 0 and 28 improved Se status from marginal to adequate in 1 trial. Parenteral supplementation with vitamin E did not improve serum vitamin E concentrations in any experiment. CONCLUSIONS AND CLINICAL IMPORTANCE: Supplementation with vitamin E or Se or a combination of both did not have a significant effect on calf performance during the 42-day backgrounding period.     

补饲硒 维生素E对奶牛激素水平的影响

为进一步研究硒、维生素E对奶牛繁殖性能的影响,在某奶牛场选择临床健康、年龄、体重相近的荷斯坦奶牛50头。随机分为对照组、试验A组和试验B组,对试验A组补饲维生素E,试验B组补饲亚硒酸钠维生素E,每5 d采血1次,用高效液相色谱法测定血清中的雌三醇、4-壬基酚、17α-乙烃基雌二醇、17α-雌二醇、17β-雌二醇、双酚A的含量。结果显示,补饲维生素E、亚硒酸钠维生素E后血液中雌三醇、4-壬基酚、17α-雌二醇、17β-雌二醇、双酚A的含量均有所增加,补亚硒酸钠维生素E后各激素含量的变化明显优于补饲维生素E的变化。     

Effect of vitamin E and selenium on iron utilization in neonatal pigs.

Supplying adequate iron (Fe) to neonatal pigs to support normal growth and hematological and antioxidant status, while preventing iron toxicity, is a challenge for producers. Three experiments were conducted to determine the effect of frequency and route of Fe administration with or without vitamin E (E) and selenium (Se) on growth, Fe, and antioxidant status of neonatal pigs. In Exp. 1, 12 pigs from dams with reduced E status were fed a semipurified diet without added Fe from d 3 to d 14 of age. At d 6 of age, pigs received the following i.m. injections: 1) FE, 1 mL containing 200 mg of Fe (iron dextran); 2) FEE, treatment FE plus 1 mL containing 300 IU of vitamin E (d-alpha tocopherol); or 3) FESEE, 1.03 mL containing 200 mg of Fe (iron dextran), .15 mg of Se (sodium selenite), and 15 IU of vitamin E (d-alpha tocopherol). Pigs were weighed daily and blood was collected at 3, 7, and 14 d of age. From d 8 to 14, growth was depressed (P < .05) in pigs injected with FESEE. At 14 d of age, pigs injected with FE or FEE had increased (P < .05) hemoglobin (Hb) concentration. Ceruloplasmin activity (CP) was greater (P < .05) at d 7 of age than at d 3 or 14 regardless of treatment. In Exp. 2, 3-d-old pigs (n = 94) received the following: 1) FE, 200 mg Fe (iron dextran) i.m.; (2) FEE, treatment FE plus 300 IU vitamin E i.m.; 3) EFE, 300 IU vitamin E i.m. followed by 200 mg Fe (iron dextran) i.m. 24 h later; or 4) OFE, 100 mg Fe and 10 mg Cu orally. On d 21 of age, one-half of the pigs in each treatment received a second dose of their respective treatment. Blood samples (n = 60) were obtained on d 3 and 21 of age. Pigs injected with FE, FEE, or EFE had greater (P < .05) Hb at d 21 than pigs given OFE. Copper/zinc superoxide dismutase (Cu/ZnSOD) activity was greater (P < .05) at d 21 with OFE than with the other treatments. At 65 d of age, ADG did not differ among treatments. In Exp. 3, pigs (n = 150, in three farrowing groups) were injected with 200 mg of Fe (iron dextran) on d 1 or d 1 and 14. Blood samples were obtained on d 7 and 21 of age. Hemoglobin concentration on d 21 was improved equally by both treatments. Catalase and Cu/ZnSOD activities were increased (P < .05) on d 21 of the experiment compared with d 7 regardless of treatment. Growth was not affected by injection frequency. Results from these experiments indicate that one Fe injection (200 mg) for pigs from sows fed adequate vitamin E will result in adequate growth and hemoglobin concentration with today's improved genetics.     

Investigations on manifestations of vitamin E and selenium deficiency in sheep and goats]

In a prospective study from 1991-1998 plasma concentrations of alpha-Tocopherole (VitE) and Selenium (Se) were analysed in 125 sheep and 32 goats with generalised motor disturbances or elevated plasma-activities of Creatine-Kinase (CK). VitE-values < 1.0 mg/l and Se-values < 0.08 mg/l were regarded as deficiency. Diagnosis of pathological manifestations was based on blood enzyme values. CK-values in plasma > 300 U/l or Aspatate-Amino-Transferase (ASAT) > 150 U/l were regarded as myopathy, Glutamat-Dehydrogenase-values > 25 U/l indicated a hepatopathy. 92 (74%) sheep and 10 (31%) goats showed VitE and/or Se deficiency. There were no principal differences in the frequencies of myopathies (67%) and hepatopathies (46%) between pure VitE deficiencies or pure Se deficiencies or combinations of both deficiencies. In VitE deficiency and in the combinations of VitE and Se deficiency the elevations of the enzyme activities were more pronounced than in Se deficiency. The lethality was significantly higher in combined VitE + Se deficiencies (73%) than in pure VitE or Se deficiencies (35%). Combined VitE + Se deficiencies occurred more frequent in lambs (53%) and was often accompanied by anaemia (29%) and hypoproteinaemia (32%). The diagnostic reliability of ASAT and GLDH for the detection of VitE and Se deficiency was better than CK. Diagnostic and therapeutic strategies in flock diseases are discussed.     

Status of selenium and vitamin E on Norwegian organic sheep and dairy cattle farms

Herbage selenium (Se) concentration is generally low in Norway. It is unknown whether feeding practices on Norwegian organic farms fulfil the dietary needs of Se and vitamin E for sheep and dairy cattle. Therefore we analysed Se in soil and herbage, and Se and vitamin E in animal blood in the indoor feeding season at 14 organic dairy and 14 organic sheep farms. The herbage Se concentration was low. Approximately 50 and 35% of all samples in the first and second cut, respectively, had Se concentrations below the detection limit of 0.01 mg/kg dry matter (DM). The median (10th, 90th percentile) Se concentrations were <0.01 (<0.01, 0.03) and 0.02 (<0.01, 0.06) mg/kg DM in the first and second cuts, respectively. Whole blood Se concentrations were 0.10 (0.04, 0.15) μg/g in dairy cattle and 0.14 (0.03, 0.26) μg/g in sheep. Vitamin E concentrations were 4.2 (2.7, 8.4) mg/l in dairy cattle and 1.3 (0.9, 2.4) mg/l in sheep. None of the soil or plant variables explained the variation in herbage Se concentration, although Se in soil and plant tended to be correlated. Herbage Se concentration was inadequate to meet the dietary Se requirements. Vitamin E requirement was only met in dairy herds. We recommend Se and vitamin E supplementation to ruminants on organic farms.