Abstract

INTRODUCTION

The breeding phase for calves, leading up to weaning, is a period of maximal profit for the producer, since this is when greatest feed conversion occurs (SilperSILPER DF, LANA AM, CARVALHO AU, FERREIRA CS, FRAZONI AP, LIMA JA, SATURNINO HM, REIS RB and COELHO SG. 2014. Effects of milk replacer feeding strategies on performance, ruminal development, and metabolism of dairy calves. J Dairy Sci 97: 1016-1025. et al. 2014). Farms that focus on dairy production sell male calves to meat producers, who fatten the animals for later slaughter. Normally, calves arrive at meat-producing farms on the first day of life, having consumed only colostrum. Investigators describe good potential for short-term weight gain in Holstein calves at this stage (BiondiBIONDI P, SCOTT WN and FREITAS EAN. 1984. Criação e produção de bovinos machos de raças leiteiras para o corte. Zootecnia 22: 281-296. et al. 1984).

The breeding phase begins with artificial feeding, where exclusive milk-based formula may lead to underdevelopment of the rumen (KolbKOLB E, GURTLER H, KETZ HA, SCHRODER L and SEIDELL H. 1984. Fisiologia Veterinária. 4a ed., Rio de Janeiro: Guanabara, 612 p. et al. 1984). To avoid this, many producers practice early weaning, allowing the animal to start its life as a ruminant earlier, since newborn calves have similar digestive systems to dwarf ruminants. In addition, as they require nutrients for development, they begin to ingest solids, accelerating the development of the rumen and consequently digesting more fiber (BragaBRAGA AP, RIBEIRO HU, CÂMARA FA and BRAGA ZCAC. 2006. Desempenho de bezerros mestiços leiteiros submetidos a diferentes tipos de aleitamento artificial. Rev Caatinga 19: 245-249. et al. 2006). However, it should be emphasized that the liquid diet is a pleasurable experience for the calf and the end of this phase causes physiological stress, in addition to reduction in dry matter consumption (12% milk dry matter x milk volume supplied). Energy and protein deficiency can cause a reduction in energy balance if concentrate consumption does not increase rapidly (TzouTZOU GG, EVERSON DO, BULL RC and OLSON DP. 1991. Classification of beef calves as protein-deficient or thermally by discriminant analysis of blood constituents. J Anim Sci 69: 864-873. et al. 1991, DavisDAVIS CL and DRACKLEY JK. 1998. The development, nutrition, and management of young calf: Iowa: State University, p. 339. and Drackley 1998). The metabolic stress related to weaning may be severe, causing the calves to consume their own energy and protein reserves, resulting in oxidative stress (SundrumSUNDRUM A. 2015. Metabolic disorders in the transition period indicate that the dairy cows ability to adapt is overstressed. Animals 5: 978-1020. 2015). Oxidative stress is defined as an imbalance between the production and elimination of free radicals that can lead to cellular and tissue damage. This process may contribute to weight loss and alterations in performance (FerreiraFERREIRA ALA and MATSUBARA LS. 1997. Radicais livres: conceitos, doenças relacionadas, sistema de defesa e estresse oxidativo. Rev Ass Med Bras 43: 61-68. and Matsubara 1997). Increases in oxidant generation are moderated by antioxidants such as catalase (CAT), superoxide dismutase (SOD) and glutathione peroxidase (GPx), which neutralize free radicals, preventing or reducing their deleterious effects on cells and tissues (HalliwellHALLIWELL B and WHITEMAN M. 2004. Measuring reactive species and oxidative damage in vivo and in cell culture: how should you do it and what do the results mean? Br J Pharmacol 142: 231-255. and Whiteman 2004).

Minerals are present in all cells and body tissues, where they serve a wide variety of functions. The concentrations of these minerals vary according to their requirements, and they are generally maintained within narrow limits for functional activity and tissue integrity in order to maintain satisfactory levels of growth, health, and animal productivity (OlsonOLSON KC. 2007. Management of mineral supplementation programs for cow-calf operations. Vet Clin North Am Food Anim Pract 23: 69-90. 2007). Among these micronutrients, zinc (Zn) and diphenyl diselenide (PhSe)₂ deserve particular mention. During weaning, reserves of Zn and selenium in calves are practically nonexistent. The animal depends on feed and roughage to meet the high requirements for these minerals. However, stress at weaning alters basal metabolism, protein synthesis, and immune system function, reducing animal performance. Reversing or minimizing this situation, as well as making the animal seek food is important to ensure calf development (Sundrum 2015). Selenium protects cell membranes from oxidative degeneration (SmithSMITH KL, WEISS WP and HOGAN JS. 1986. Influence of vitamin e and selenium on mastitis and milk quality in dairy cows. J Dairy Sci 80: 1728-1737. et al. 1986). Since the 1980s, investigators have shown that dairy cow diets supplemented with selenium help maintain the body’s defense mechanisms, including antibody production, cell proliferation, cytokine production, prostaglandin metabolism, and function of cells in the innate immune defense system (Smith et al. 1986).

A recent study demonstrated the antioxidant potential of (PhSe)₂ in improving antioxidant/oxidant status in production animals, as observed by MenezesMENEZES C, LEITEMPERGER J, MURUSSI C, VIERA MS, ADAIME MB, ZANELLA R and LORO VL. 2016. Effect of diphenyl diselenide diet supplementation on oxidative stress biomarkers in two species of freshwater fish exposed to the insecticide fipronil. Fish Physiol Biochem 42: 1357-1368. et al. (2016) in fish supplemented for 60 days with 3 mg/kg (PhSe)₂. In addition, experimental models of parasitic infections and liver damage have demonstrated the immunomodulatory and anti-inflammatory potential of (PhSe)₂ (StefanelloSTEFANELLO ST, DA ROSA EJF, DOBRACHINSKI F, AMARAL GP, CARVALHO NR, DA LUZ SCA, BENDER CR, SCHWAB RS, DORNELLES L and SOARES FAA. 2015. Effect of diselenide administration in thioacetamide-induced acute neurological and hepatic failure in mice. Toxicol Res 3: 1-11. et al. 2015, DoleskiDOLESKI PH, TEN CATEN MV, PASSOS DF, CASTILHOS LG, LEAL DBR, MACHADO VS, BOTTARI NB, VOGEL FF, MENDES RE and DA SILVA AS. 2017. Toxoplasmosis treatment with diphenyl diselenide in infected mice modulates the activity of purinergic enzymes and reduces inflammation in spleen. Exp Parasitol 181: 7-13. et al. 2017). Therefore, we believe that selenium might improve the immune and antioxidant systems of calves during the pre- and post-weaning period.

Zinc plays an important role in animal health, as it is a cofactor for several enzymes in the antioxidant system. In addition, Zn is involved in the metabolism of nucleic acids, proteins and carbohydrates, as well as actively participating in the development and normal functioning of the immune system (CarvalhoCARVALHO FAN, BARBOSA FA and MCDOWELL LR. 2003. Nutrição de bovinos a pasto. Belo Horizonte, PapelForm, Editora Gráfica, p. 438. et al. 2003, NamazuNAMAZU LB, PAPESSO K, ALBUQUERQUE R, SCHAMMASS EA, TAKEARA P and TRINDADE NETO MA. 2008. Lisina digestível e Zn quelado para frangos de corte machos: desempenho e retenção de nitrogênio na fase pré-inicial. R Bras Zootec 37: 1634-1640. et al. 2008). Recent studies have demonstrated the antioxidant and anti-inflammatory properties of Zn in prevention of increased free radical production, improved antioxidant enzyme activity (CAT, SOD and GPx) and decreased production of inflammatory cytokines (YinYIN LL, ZHANG Y, GUO DM, AN K, YIN MS and CUI X. 2013. Effects of zinc on interleukins and antioxidant enzyme values in psoriasis-induced mice. Biol Trace Elem Res 155: 411-415. et al. 2013, YangYANG JS, PERVEEN S, HA TJ, KIM SY and YOON SH. 2015. Cyanidin-3-glucoside inhibits glutamate-induced Zn2+ signaling and neuronal cell death in cultured rat hippocampal neurons by inhibiting Ca2+-induced mitochondrial depolarization and formation of reactive oxygen species. Brain Res 1606: 9-20. et al. 2015), corroborating our hypothesis that treatment with Zn improves antioxidant and immune responses during the nursing period. Therefore, we believe that these treatments, alone or in combination, can improve the antioxidant and immune systems of pre- and post-weaning calves.

The objective of this study was to evaluate whether injectable administration with zinc edetate and diphenyl diselenide in weaning calves improves performance, immune responses, protein and lipid metabolism, and oxidative/antioxidant status.

MATERIALS AND METHODS

PRODUCTS

Diphenyl diselenide (PhSe)₂ (99.9%) was purchased from Sigma-Aldrich (St. Louis, MO, USA). (PhSe)₂ was diluted dimethylsulfoxide (DMSO). Zinc edetate was purchased from Biogenesis.

ANIMALS

The experiment was conducted on a farm located in the city of Tunápolis, Santa Catarina, Brazil. Twenty-four male Holstein breed calves were salvaged from local dairy farms who typically remove males after birth. The animals used in this study arrived on the farm on their first day of life, after having ingested only colostrum during the first hours of life on the farm of origin. The animals weighed an average of 40 ± 5.2 kg at birth.

All the calves were housed in a closed shed, two calves per stalls, with concrete floors and wooden beds. They remained there until 60 days of life (from weaning). Then, the animals were taken to an open area, with collective bays and beaten dirt floors. The calves’ concentrate-based diet (Table I) contained milk replacer until 60 days of life. Hay and water ad libitum together with concentrate was also available starting on the first day of life. From 60 days until slaughter the diet was based on 16% protein concentrate and corn silage.

EXPERIMENTAL DESIGN

The animals were divided into four groups: (PhSe)₂, Zn, (PhSe)₂+Zn, and control. Each group had six calves at 50 days of life. The animals in the (PhSe)₂ group received a subcutaneous injection of 3 µmol/kg (PhSe)₂. Calves in the Zn group received a subcutaneous dose of 1 mg/Kg zinc edetate. Animals in the (PhSe)₂+Zn group received a combination of both mineral preparations at the same dose and the same route of administration. The control group was not supplemented with minerals. Minerals were administered on days of life 50 (10 days prior to weaning) and 70 (10 days after weaning). That is, there were two applications at 20-day intervals.

Experimental protocol was approved by the Animal Welfare Committee of the State University of Santa Catarina (UDESC), under number: 7646040416.

WEIGHING

Animals were weighed on days of life 50, 70, 90, 150, 210, 270 and 360 (day of slaughter) using a digital scale.

SAMPLE COLLECTION

Blood samples were collected on days of life 50, 70, and 90 by jugular venipuncture. Blood was collected in tubes without anticoagulant, containing sodium citrate and EDTA. Collection tubes without anticoagulant were used to obtain serum by centrifugation at 8000 rpm for 10 minutes, then placed in microtubes at -20ºC. Whole blood from tubes containing sodium citrate was also homogenized and transferred to microtubes (-20ºC). The collection tubes containing EDTA were used to perform the leukogram and measurement of glutathione peroxidase (GPx) activity in red blood cell (RBC) membranes. This was done by washing RBCs with PBS and centrifuging at 2500 rpm three times, until only RBCs were left. These were transferred to microtubes. All materials were labelled and stored at -20°C pending analysis.

At 360 days of age, the animals were sent to the slaughterhouse. The warm carcasses were weighed and muscle fragments were obtained and stored in plastic bags at -20ºC until analysis. On the day of analysis, muscle fragments were weighed and allocated into test tubes. Muscle tissue was homogenized in buffer containing Tris–HCl 10 mmol, pH 7.2 to measure oxidant levels and antioxidant activities.

HEMATOLOGIC ANALYSIS

Leukocyte count was obtained using a semi-automatic cell counter (CELM model CC530). To obtain the white cell differential, blood smears were prepared and stained using a kit (Panotico Rápido). Subsequently, cells were identified by light microscopy.

BIOCHEMICAL ANALYSIS

Serum levels of total protein (TP) and albumin were measured using commercially-available kits, on semi-automatic equipment (Bio-2000 BioPlus®). Globulin levels were obtained by mathematical calculation (total protein – albumin).

OXIDANT LEVELS

Lipid peroxidation was measured as serum malondialdehyde (MDA) levels, by measuring thiobarbituric acid reactive substances (TBARS) (JentzschJENTZSCH AM, BACHMANN H and BIESALKSKI HK. 1996. Improved analysis of malondialdehyde in human body fluids. Free Radic Biol Med 20: 251-256. et al. 1996). Results were expressed as nanomoles malondialdehyde per milliliter of serum (nmol MDA/mL). Muscle lipid peroxidation was determined by TBARS levels, measured by the absorbance of red product at 532 nm according to the method described by OhkawaOHKAWA H, OHISHI N and YAGI K. 1979. Assay for lipid peroxides in animal tissues by thiobarbituric acid reaction. Anal Biochem 95: 351-358. et al. (1979). Values were expressed as nmol MDA/mg of protein.

Oxidation levels of 2’-7’-dichlorofluorescein (DCFH) were determined in serum and muscle homogenate as a peroxide index produced by cellular components according to the modified method of ColpoCOLPO E et al. 2008. A single high dose of ascorbic acid and iron is not correlated with oxidative stress in healthy volunteers. Ann Nutr Metab 53: 79-85. et al. (2008), in order to determine levels of reactive oxygen species (ROS) (HalliwellHALLIWELL B and GUTTERIDGE JMC. 2007. Cellular responses to oxidative stress: adaptation, damage, repair, senescence and death. In: Halliwell B and Gutteridge JMC (Eds), Free Radicals in Biology and Medicine. 4th Edition, Oxford University Press, New York, p. 187-267. and Gutteridge 2007). For the assay, 10 µl samples were incubated with DCFH (10 µl) 1mM at 37ºC for 1 hour in the dark. Fluorescence was measured using 488 nm for excitation and 520 nm for emission. Fluorescence measurements were normalized for time, values and fluorescence ratios (reflecting ROS levels). Results were expressed as U DCFH/mL of serum and tissue.

ANTIOXIDANT ENZYMES

Serum and tissue assays were used to evaluate activity of antioxidant enzymes superoxide dismutase (SOD) and catalase (CAT). SOD activity was determined using spectrophotometry by measuring inhibition of autocatalytic adenochrome formation (McCordMCCORD JM and FRIDOVICH I. 1969. Superoxide dismutase. An enzymatic function for erythrocuprein (hemocuprein). J Biol Chem 244: 6049-6055. and Fridovich 1969). Results were expressed as U SOD/mg protein. CAT activity was measured using the methodology described by AebiAEBI H. 1984. Catalase in vitro. Methods Enzymol 105: 121-126. (1984), which determines the rate of H₂O₂ decomposition. CAT activity was expressed as nmol CAT/mg protein.

Glutathione peroxidase activity was determined in erythrocyte membranes according to the method described by Gunzler et al. (1974)GÜNZLER WA, KREMERS H and FLOHÉ L. 1974. An improved coupled test procedure for glutathione peroxidase (EC 1.11.1.9) in blood. Z Klin Chem Klin Biochem 12: 444-448.. Results were expressed as Ug/Hg. Muscle GPx was determined according to the method described by PagliaPAGLIA DE and VALENTINE WN. 1967. Studies on the quantitative and qualitative characterization of erythrocyte glutathione peroxidase. J Lab Clin Med 70: 158-169. and Valentine (1967), in which oxidation of nicotinamide adenine dinucleotide phosphate (NADPH) was determined, and enzymatic activity was expressed in nmol oxidized NADPH/h/mg protein.

NITRATE/NITRITE LEVELS

Nitric oxide levels were determined by indirectly as levels of NOx (nitrate/nitrite) using a colorimetric reaction, considered the standard technique for measuring NO₂ levels (DusseDUSSE LM, SILVA RM, VIEIRA LM and CARVALHO MG. 2005. Does plasma nitric determination by the Griess reaction reflect nitric oxide synthesis? Clin Chim Acta 362: 195-197. et al. 2005).

STATISTICAL ANALYSIS

For each group and day of observation, all parameters were tested for normality using the Shapiro-Wilk test. Skewness, kurtosis and homogeneity were evaluated by the Levene test. Log transformation was applied when needed. One-way ANOVA was used to analyze all parameters that showed difference, comparing groups at each time period (day 1, day 20, and day 40), for weight related measurements (day 1, day 20, day 40, day 100, day 160, day 220, and day 300). For post hoc testing, Tukey’s test was used accordingly. Significant difference was assumed if P < 0.05. The statistical analysis was performed using R-language, v.3.1, R Development Core Team 2012.

RESULTS

WEIGHT

The group treated with (PhSe)₂ gained more weight compared with other groups on day 220 of the experiment (day of life 270). However, there were no differences among groups at the other time points or at the end of the experiment (Figure 1).

Figure 1
Distribution by group of weigh in newborn calves. Each day of sampling the mean and standard deviation of each variable are been represented. ***P < 0.001 and represents significant differences between groups. Note: day 1 of experiment correspond at day 50 of life.

LEUKOGRAM

On day 20 of the experiment, animals treated with Zn and those treated with the combination of (PhSe)₂ and Zn had greater numbers of total leukocytes and lymphocytes than did the control group. On day 40, the groups treated with (PhSe)₂ and (PhSe)₂ + Zn had lower numbers of total leukocytes and lymphocytes than did the control group. On day 40, monocyte levels were lower in all the treatment groups compared with control. There were no differences in neutrophil or eosinophil counts among groups at any evaluated time point (Table II).

SERUM BIOCHEMISTRY

On day 20, serum total protein levels were greater in the group treated with the combination of (PhSe)₂ and Zn, compared with control. On day 40, total protein levels were lower in the (PhSe)₂ group compared with control. On day 40, albumin and globulin levels were lower in the group treated with (PhSe)₂ compared with control. In addition, on day 20, the combination of (PhSe)₂ and Zn gave greater values of globulin compared with control (Table III).

OXIDANT STATUS AND SERUM ANTIOXIDANTS

The mineral combination group ((PhSe)₂+Zn) have lower values of TBARS on day of life 70 (day 20 of the experiment) compared to the other groups (P < 0.05). Similar, ROS levels were lower in the (PhSe)₂ and (PhSe)₂+Zn groups compared with control (P < 0.05, Table IV).

On days 20 and 40 of the experiment, the mineral combination group ((PhSe)₂+Zn) caused an increase in whole blood SOD activity, compared with the other groups. On day 20 of the experiment, GPx activity was greater in the (PhSe)₂ and (PhSe)₂+Zn groups, as well as in all supplemented groups at day 40, when compared to control (Table IV).

NITRATE/NITRITE

On experiment day 40 (that is, day of life 90), supplemented animals had higher levels of NOx (P < 0.05) compared with the control group (Table II).

MUSCLE OXIDANTS/ANTIOXIDANTS

Muscle levels of TBARS in animals treated with the mineral combination (PhSe)₂+Zn were lower compared with control, while GPx activity was higher. Carcass yield, ROS levels, and SOD and CAT activities did not differ among groups (Table V).

DISCUSSION

Stress of weaning is considered critical for animal production, as it may compromise the calf immune system and delay development. An analysis of the productive performance in beef cattle showed that calf mortality from birth to weaning represented 53.7% of the general mortality occurring in the herd (AlvasenALVASEN K, MORK MJ, SANDGREN CH, THOMSEN PT and EMANUELSON U. 2012. Herd-level risk factors associated with cow mortality in Swedish dairy herds. J Dairy Sci 95: 4352-4362. et al. 2012). It is important to emphasize that many minerals are antioxidant enzyme cofactors that augment immune defense and promote animal health (McDonaldMCDONALD LR. 2002. Mineral deficiencies and toxicities and their effect on beef production in developing countries. Edinburg: Pearson 6, p. 639. 2002). Selenium participates in several processes, especially antioxidant and anti-inflammatory systems (KimKIM Y, KIM DC, CHO ES, KO O, KWON WY, SUH GS and SHIN HK. 2014. Antioxidant and anti-inflammatory effects of selenium in oral buccal mucosa and small intestinal mucosa during intestinal ischemia-reperfusion injury. J Inflamm 11: 36. et al. 2014). In a study by MandalMANDAL GP, DASS RS, ISORE DP, GARG AK and RAM GC. 2007. Effect of zinc supplementation from two sources on growth, nutrient utilization and immune response in male crossbred cattle (Bosindicus× Bostaurus) bulls. Anim Feed Sci Technol 138: 1-12. et al. (2007), zinc supplementation improved cellular and humoral immune responses. Our experiment verified that mineral supplementation activated the antioxidant system, that is, it increased the activity of SOD and GPx. GPx is responsible for detoxifying harmful compounds (JohnJOHN DH, JACK UF and IAN RJ. 2005. Glutathione transferases. Annu Rev Pharmacol Toxicol 45: 51-88. et al. 2005), and SOD controls the formation of free radicals and non-radical species that are linked to oxidative damage (Ferreira and Matsubara 1997).

In the present study, SOD activity was significantly higher in the combined group ((PhSe)₂ + Zn) compared with the other groups. This is probably because SOD uses zinc and selenium as cofactors (VincentVINCENT HK, INNES KE and VINCENT KR. 2007. Oxidative stress and potential interventions to reduce oxidative stress in overweight and obesity. Diabetes Obesmetab 9: 813-839. et al. 2007, BianchiBIANCHI ML and ANTUNES LMG. 1999. Radicais livres e os principais antioxidantes da dieta. Rev Nutr 65: 123-130. and Antunes 1999). In a study of Jersey calves and crossbreeds (Jersey x Holstein), serum selenium increased along with an increase in GPx activity when selenium was administered directly into the abomasum (SallesSALLES MSV, ZANETTI MA, JUNIOR LCR, SALLES FA, AZZOLINI AECS, SOARES EM, FACCIOLI LH and VALIM YML. 2014. Performance and immune response of suckling calves fed organic selenium. Anim Feed Sci Technol 188: 28-35. et al. 2014). We observed an increase in glutathione peroxidase (GPx) activity with administration of selenium or combination of minerals ((PhSe)₂ + Zn). This result may be explained by the fact that selenium is involved in selenoproteins such as GPx (HoekstraHOEKSTRA WG. 1975. Biochemical function of selenium and its relation to vitamin E. Federation Proc J 34: 2083-2090. 1975). It is well known that selenium potentiates the activity of selenoproteins (GhisleniGHISLENI G, PORCIUNCULA LO, CIMAROSTI H, ROCHA JBT, SALBEGO CG and SOUZA DO. 2003. Diphenyl diselenide protect rat hippocampal slices submitted to oxygen-glucose deprivation and diminishes inducible nitric oxide synthase immunocontent. Brain Res 986: 196-199. et al. 2003,NogueiraNOGUEIRA CW, MEOTTI FC, PILISSÃO C, ZENI G and ROCHA JBT. 2003. Investigations into the potential neurotoxicity induced by diselenides in mice and rats. Toxicology 183: 29-37. et al. 2003, SavegnagoSAVEGNAGO L, PINTO LG, JESSE CR, ALVES D, ROCHA JBT, NOGUEIRA CW and ZENI G. 2007. Antinociceptive properties of diphenyl diselenide: evidences for the mechanism of action. Eur J Pharmacol 555: 129-138. et al. 2007).

In the present study, a reduction in TBARS levels was observed when the two minerals were given together ((PhSe)₂+Zn), suggesting a reduction in lipid peroxidation. Zinc and selenium deficiencies predispose cells to oxidative stress, so that oxidants are not neutralized (YatooYATOO MI, SAXENA A, DEEPA PM, HABEAB BP, DEVI S, JATAV RS and DIMRI U. 2013. Role of trace elements in animals: a review. Vet World 6: 963-967. et al. 2013). The negative effects on animal health are mediated by damage to cells and tissues by free radicals or other oxidizing agents. Mineral supplementation can prevent oxidant stress, as has been observed in other studies (CastilloCASTILLO C, HERNANDEZ J, VALVERDE I, PEREIRA V, SOTILLO J, LÓPEZ AM and BENEDITO JL. 2006. Plasma malondialdehyde (MDA) and total antioxidant status (TAS) during lactation in dairy cows. Res Vet Sci 80: 133-139. et al. 2006). The use of selenium has been much studied, but unlike most other essential mineral supplements, selenium has a narrow range between deficiency and toxicity (MacDonald et al. 1981MCDONALD DW, CHRISTIAN RG, STRAUSZ KI and ROFF J. 1981. Acute selenium toxicity in neonatal calves. Can Vet J 22: 279-281., AbdelrahmanABDELRAHMAN MM and KINCAID RL. 1995. Effect of selenium supplementation of cows on maternal transfer of selenium to fetal and newborn calves. J Dairy Sci 78: 625-630. and Kincaid 1995). Studies in several animal’s species have shown toxic effects of selenium as (PhSe)₂ (RosaROSA RM, ROESLER R, BRAGA AL, SAFFI J and HENRIQUES JA. 2007. Pharmacology and toxicology of diphenyl diselenide in several biological models. Braz J Med Biol Res 40: 1287-1304. et al. 2007), but no observed in study current.

The stress of weaning rapidly accelerates the consumption of zinc by animals. The main consequence of this is metabolic alteration, which may reduce the need for protein synthesis, damaging animal performance (Sundrum 2015). Our total protein result was due to effects on globulins: when zinc was used, there was an increase in the total protein serum level. A study by Sundrum (2015) showed that single-dose supplementation with zinc in weaning calves increased protein synthesis, probably because more available zinc augmented the immune system, specifically acute phase proteins and immunoglobulins.

Lymphocytes and monocytes digest antigens recognized as foreign threats the immune system (MillerMILLER JK and SLEBODZINSKA EB. 1992. Oxidative stress, antioxidants, and animal function. J Dairy Sci 76: 2812-2823. and Slebodzinska 1992, BalakrishnanBALAKRISHNAN K and ADAMS LE. 1995. The role of the lymphocyte in an immune response. Immunol Invest 24: 233-244. and Adams 1995). BrunettoBRUNETTO MA, GOMES MOS, JEREMIAS JT, OLIVEIRA LD and CARCIOFI AC. 2007. Imunonutrição: o papel da dieta no restabelecimento das defesas naturais. Acta Sci Vet 35: 230-232. et al. (2007) reported that zinc deficiency resulted in extensive damage to T lymphocytes due to alteration in cell synthesis, resulting in immunosuppression. In our study, there was an increase in the number of leukocytes, lymphocytes, and monocytes when zinc and selenium were administered together. Various immune cells and their phagocytic activities may be directly affected by mineral deficiency, and supplementation may stimulate the immune system (Yatoo et al. 2013).

We observed positive responses to minerals in muscle tissue, in the form of decreasing lipid peroxidation (TBARS) and augmentation of GPx activity. This was likely related to zinc and selenium acting on the cellular antioxidant system by decreasing free radicals (BaraboiBARABOI VA and SHESTAKOVA EN. 2004. Selenium: the biological role and antioxidante activity. Ukr Biokhim Zh 76: 23-32. and Shestakova 2004). Selenium deficiency caused muscle degeneration, including myocardial necrosis, due to high levels of polyunsaturated fatty acids, mainly delivered via concentrate to the animals, causing tissue damage by free radicals (EnjalbertENJALBERT F. 2009. The relationship between trace elements status and health in calves. Revue Med Vet 160: 429-435. 2009).

CONCLUSIONS

Injectable supplementation with selenium and zinc in calves during the pre- and post-weaning period had substantial effects on the animals’ development. Zinc potently stimulated the immune-system while selenium had important anti-inflammatory action. When used in combination ((PhSe)₂ + Zn), the minerals activated the cellular antioxidant system, reducing the harmful action of free radicals and stimulating the activity of various immune cells.

REFERENCES

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