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Effect of castration and an anabolic implant on growth and serum hormones in cattle

Published online by Cambridge University Press:  02 September 2010

D. M. Henricksi ,
T. Gimenez ,
T. W. Gettys  and
B. D. Schanbacher
D. M. Henricksi
Affiliation:
Clemson University, Clemson, SC 29634, USA
T. Gimenez
Affiliation:
Clemson University, Clemson, SC 29634, USA
T. W. Gettys
Affiliation:
Clemson University, Clemson, SC 29634, USA
B. D. Schanbacher
Affiliation:
US Department of Agriculture, Clay Center, NE 68933, USA
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Abstract

In the present study, a commercially available anabolic implant containing trenbolone acetate and oestradiol-17p was investigated in intact and castrated bulls. Measurements of growth rate, serum hormones and metabolites in both phenotypes, and testicular development and function in bulls, were obtained. The experimental objectives were realized in a 2 × 2 factorially designed experiment utilizing eight Angus-sired crossbred bulls and eight similar steers castrated at 7 months of age. Half of each group were implanted with 140 mg trenbolone acetate plus 28 mg oestradiol-17β. Body weights were monitored every 7 days and plasma samples were obtained at 28-day intervals from 9 to 15 months of age. In the implanted groups, mean concentrations of plasma trenbolone and oestradiol-17p were 380 ng/1 and 31 ng/1, respectively. Trenbolone concentrations were undetectable in both non-implanted groups, and plasma oestradiol-17β was less than half that in implanted animals. While plasma GH concentrations were stratified according to implant treatment, they did not differ among the groups. Cortisol levels showed phenotype × implant interaction; implanted steers and non-implanted bulls had lower concentrations than non-implanted steers and implanted bulls. The implant resulted in no significant changes in gross testicular measures in the bulls but did affect the testosterone response to a GnRH challenge and basal plasma concentrations of testosterone were reduced. Plasma urea concentrations were reduced by the implant, but sex phenotype had no effect. Over the 175-day trial, implantation did not significantly improve the growth rate of bulls, except during the first third of the experiment. In contrast, implantation improved the growth rate of steers over the entire experiment, although implanted steers still grew more slowly than either implanted or non-implanted bulls. It can be concluded that the endocrine status of the young bull is set for a fast growth rate, making improvements via an anabolic implant marginal, except in the immature animal.

Type
Research Article
Information
Animal Production , Volume 46 , Issue 1 , February 1988 , pp. 35 - 41
Copyright
Copyright © British Society of Animal Science 1988

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References

REFERENCES

Galbraith, H. 1982. Growth, hormonal and metabolic response of post-pubertal entire male cattle to trenbolone acetate and hexoestrol. Animal Production 35: 269276.Google Scholar
Galbraith, H., Dempster, D. G. and Miller, T. B. 1978. A note on the effect of castration on the growth performance and concentrations of some blood metabolites and hormones in British Friesian male cattle. Animal Production 26: 339342.Google Scholar
Galbraith, H. and Watson, H. B. 1978. Performance, blood and carcase characteristics of finishing steers treated with trenbolone acetate and hexoestrol. Veterinary Record 103: 2830.CrossRefGoogle ScholarPubMed
Geay, Y. and Malterre, C. 1971. Effect of castration and type of carbohydrate in the ration on growth and quality of carcass of cattle killed at 24 months. Annales de Zootechnie 20: 251257.Google Scholar
Gettys, T. W., Burrows, P. M. and Henricks, D. M. 1986. Variance weighting functions in radioimmunoassay calibration. American Journal of Physiology 251: E357361.Google ScholarPubMed
Gettys, T. W., D'occhio, M. J., Henricks, D. M. and Schanbacher, B. D. 1984. Suppression of LH secretion by oestradiol, dihydrotestosterone and trenbolone acetate in the acutely castrated bull. Journal of Endocrinology 100: 107112.CrossRefGoogle ScholarPubMed
Grandadam, J. A., Scheid, J. P., Jobard, A., Dreux, H. and Boisson, J. M. 1975. Results obtained with trenbolone acetate® in conjunction with estradiol-17p in veal calves, feedlot bulls, lambs and pigs. Journal of Animal Science 41: 969977.CrossRefGoogle Scholar
Gregory, K. E. and Ford, J. J. 1983. Effects of late castration, zeranol and breed group on growth, feed efficiency and carcass characteristics of late maturing bovine males. Journal of Animal Science 56: 771780.Google Scholar
Heitzman, R. J., Chan, K. H. and Hart, I. C. 1977. Liveweight gains, blood levels of metabolites, proteins and hormones following implantation of anabolic agents in steers. British Veterinary Journal 133: 6270.CrossRefGoogle ScholarPubMed
Heitzman, R. J., Donaldson, I. A. and Hart, I. C. 1980. Effect of anabolic steroids on plasma thyroid hormones in steers and heifers. British Veterinary Journal 136: 168174.CrossRefGoogle ScholarPubMed
Heitzman, R. J., Gibbons, D. N., Little, W. and Harrison, L. P. 1981. A note on the comparative performance of beef steers implanted with the anabolic steroids trenbolone acetate and oestradiol-17β, alone or in combination. Animal Production 32: 219222.Google Scholar
Henricks, D. M., Cooper, J. W., Spitzer, J. C. and Grimes, L. W. 1984. Sex differences in plasma cortisol and growth in the bovine. Journal of Animal Science 59: 376383.CrossRefGoogle ScholarPubMed
Henricks, D. M., Edwards, R. L., Champe, K. A., Gettys, T. W., Skelley, G. C. and Gimenez, T. 1982. Trenbolone, estradiol-17β and esterone levels in plasma and tissues and live weight gains of heifers implanted with trenbolone acetate. Journal of Animal Science 55: 10481056.Google Scholar
Henricks, D. M. and Torrence, A. 1978. Endogenous estradiol-17β in bovine tissues. Journal of the Association of Official Analytical Chemists 16: 12801283.Google Scholar
Johnson, B. H., Welsh, T. J. and Juniewicz, P. E. 1982. Suppression of luteinizing hormone and testosterone secretion following adrenocorticotropin hormone treatment. Biology of Reproduction 26: 305310.CrossRefGoogle ScholarPubMed
Roche, J. F., Davis, W. D. and Sherington, J. 1978. Effect of trenbolone acetate and resorcylic acid lactone alone or combined on daily liveweight and carcass weight in steers. Irish Journal of Agricultural Research 17: 714.Google Scholar
Schanbacher, B. D. and D'occhio, M. J. 1982. Validation of a direct radioimmunoassay for testosterone in unextracted serum from five species: application to study of the hypothalmic pituitary-gonadal axis in males. Journal of Andrology 3: 4551.Google Scholar
Schanbacher, B. D., D'occhio, M. J. and Gettys, T. W. 1983a. Pulsatile luteinizing hormone secretion in the castrate male bovine: effects of testosterone or estradiol replacement therapy. Journal of Animal Science 56: 132138.CrossRefGoogle ScholarPubMed
Schanbacher, B. D., Prior, R. L. and Smith, S. B. 1983b. Effects of castration and subdermal silastic implants containing oestradiol- 17β-dipropionate on feedlot performance and carcass characteristics of male cattle. Animal Production 37: 7380.Google Scholar
Seideman, S. C., Cross, H. R., Oltien, R. R. and Schanbacher, B. D. 1982. Utilization of the intact male for red meat production: a review. Journal of Animal Science 55: 826840.CrossRefGoogle Scholar
Trenkle, A. 1970. Solid-phase immunoassay for sheep growth hormone. Proceedings of the Society for Experimental Biology and Medicine 133: 10181022.Google Scholar
Van Der Wal, P., Berende, P. L. M. and Sprietsma, J. E. 1975. Effect of anabolic agents on performance of calves. Journal of Animal Science 41: 978985.CrossRefGoogle Scholar