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In situ and in vitro estimation of mineral release from common feedstuffs fed to cattle

Published online by Cambridge University Press:  13 June 2017

D. ZANETTI*
Affiliation:
Department of Animal Science, Universidade Federal de Viçosa, PH Rolfs St, 36570-900, Minas Gerais, Brazil
A. C. B. MENEZES
Affiliation:
Department of Animal Science, Universidade Federal de Viçosa, PH Rolfs St, 36570-900, Minas Gerais, Brazil
F. A. S. SILVA
Affiliation:
Department of Animal Science, Universidade Federal de Viçosa, PH Rolfs St, 36570-900, Minas Gerais, Brazil
L. F. COSTA E SILVA
Affiliation:
Department of Animal Science, Universidade Federal de Viçosa, PH Rolfs St, 36570-900, Minas Gerais, Brazil
P. P. ROTTA
Affiliation:
Department of Animal Science, Universidade Federal de Viçosa, PH Rolfs St, 36570-900, Minas Gerais, Brazil
E. DETMANN
Affiliation:
Department of Animal Science, Universidade Federal de Viçosa, PH Rolfs St, 36570-900, Minas Gerais, Brazil
T. E. ENGLE
Affiliation:
Department of Animal Science, Colorado State University, 350 W Pitkin St, 80523, Colorado, USA
S. C. VALADARES FILHO
Affiliation:
Department of Animal Science, Universidade Federal de Viçosa, PH Rolfs St, 36570-900, Minas Gerais, Brazil
*
*To whom all correspondence should be addressed. Email: [email protected], [email protected]

Summary

The objective of the current study was to quantify the dry matter (DM) digestibility, and total ash (TA) and mineral release from 12 concentrate and 12 forage feedstuffs commonly fed to cattle using in situ and in vitro methods. Concentrate and forage feedstuffs were incubated in the rumen of ruminally cannulated beef bulls at eight different time points. Two different trials were conducted for concentrates and forages, with maximum incubation time of 72 and 120 h, respectively. The residue from samples incubated for 24 h were treated with pepsin and hydrochloric acid to simulate abomasum digestion in vitro. The initial and residual samples after in situ and in vitro incubations were measured. An asymptotic model was adopted for estimating solubility of minerals, disappearance rate of DM, and TA. Correlations between feedstuff contents and mineral release were evaluated. Residual samples from rumen fermentation after 24 h were incubated in simulated abomasal conditions and mineral release was measured. Cluster analysis was performed to group feedstuffs in relation to TA release. Large variability was observed between concentrate and forage feedstuffs for all constituents analysed. Large variability was observed for the effective ruminal degradation of TA and individual mineral release. When feedstuffs were clustered according to the immediately soluble fraction (‘a’), the insoluble by potentially releasable fraction (‘b’) and the release rate of ‘b’ (‘kd’,/h) estimates of TA ruminal release, four groups were identified. From group ‘1’ to group ‘4’, an increase in the soluble fraction and a reduction in both moderate releasable fraction and release rate was observed. Neutral detergent fibre content had a negative correlation with mineral release in the rumen, while mineral content had a positive correlation. These results demonstrate that mineral solubilization in the digestive tract is not the limiting factor for mineral absorption from the feedstuffs tested.

Type
Animal Research Papers
Copyright
Copyright © Cambridge University Press 2017 

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References

Adams, R. S. (1975). Variability in mineral and trace element content of dairy cattle feeds. Journal of Dairy Science 58, 15381548.CrossRefGoogle ScholarPubMed
AFRC (1993). Energy and Protein Requirements of Ruminants. Wallingford, UK: CAB International.Google Scholar
Amtmann, A. & Rubio, F. (2012). Potassium in plants. In eLS: Citable Reviews in the Life Sciences (Ed. Hetherington, A. M.). Chichester, UK: John Wiley & Sons, Ltd. doi: 10.1002/9780470015902.a0023737. Available online from http://onlinelibrary.wiley.com/doi/10.1002/9780470015902.a0023737/abstract (accessed 8 May 2017).Google Scholar
AOAC (2012). Official Methods of Analysis, 19th edn. Arlington, VA, USA: Association of Official Analytical Chemists.Google Scholar
ARC (1980). The Nutrient Requirements of Ruminant Livestock. London, UK: CABI.Google Scholar
Berrett, C. J., Wagner, J. J., Neuhold, K. L., Caldera, E., Sellins, K. S. & Engle, T. E. (2015). Comparison of National Research Council standards and industry dietary trace mineral supplementation strategies for yearling feedlot steers. The Professional Animal Scientist 31, 237247.Google Scholar
Bonhomme, A. (1990). Rumen ciliates: their metabolism and relationships with bacteria and their hosts. Animal Feed Science and Technology 30, 203266.Google Scholar
Braselton, W. E., Stuart, K. J., Mullaney, T. P. & Herdt, T. H. (1997). Biopsy mineral analysis by inductively coupled plasma atomic emission spectroscopy with ultrasonic nebulization. Journal of Veterinary Diagnostic Investigation 9, 395400.Google Scholar
Bravo, D., Meschy, F., Bogaert, C. & Sauvant, D. (2000). Ruminal phosphorus availability from several feeds measured by the nylon bag technique. Reproduction Nutrition Development 40, 149162.Google Scholar
Broadley, M. R., White, P. J., Hammond, J. P., Zelko, I. & Lux, A. (2007). Zinc in plants. New Phytologist 173, 677702.Google Scholar
Čerešňáková, Z., Fľak, P., Poláčiková, M. & Chrenková, M. (2005). In sacco NDF degradability and mineral release from selected forages in the rumen. Czech Journal of Animal Science 50, 320328.Google Scholar
Čerešňáková, Z., Fľak, P., Poláčiková, M. & Chrenková, M. (2007). In sacco macromineral release from selected forages. Czech Journal of Animal Science 52, 175182.Google Scholar
Chládek, G. & Zapletal, D. (2007). A free-choice intake of mineral blocks in beef cows during the grazing season and in winter. Livestock Science 106, 4146.Google Scholar
Corah, L. (1996). Trace mineral requirements of grazing cattle. Animal Feed Science and Technology 59, 6170.Google Scholar
Costa, R. M., Ponsano, E. H. G., Souza, V. C. & Malafaia, P. (2016). Reduction of phosphorus concentration in mineral supplement on fertility rate, maternal ability and costs of beef cows reared in pastures of Urochloa decumbens . Tropical Animal Health and Production 48, 417422.Google Scholar
Costa e Silva, L. F., Engle, T. E., Valadares Filho, S. C., Rotta, P. P., Valadares, R. F. D., Silva, B. C. & Pacheco, M. V. C. (2015). Intake, apparent digestibility, and nutrient requirements for growing Nellore heifers and steers fed two levels of calcium and phosphorus. Livestock Science 181, 1724.Google Scholar
Demarty, M., Morvan, C. & Thellier, M. (1984). Calcium and the cell wall. Plant, Cell and Environment 7, 441448.Google Scholar
Emanuele, S. M. & Staples, C. R. (1990). Ruminal release of minerals from six forage species. Journal of Animal Science 68, 20522060.CrossRefGoogle ScholarPubMed
Emanuele, S. M., Staples, C. R. & Wilcox, C. J. (1991). Extent and site of mineral release from six forage species incubated in mobile Dacron bags. Journal of Animal Science 69, 801810.Google Scholar
Esser, N. M., Hoffman, P. C., Coblentz, W. K., Orth, M. W. & Weigel, K. A. (2009). The effect of dietary phosphorus on bone development in dairy heifers. Journal of Dairy Science 92, 17411749.Google Scholar
Field, A. C. (1981). Some thoughts on dietary requirements of macro-elements for ruminants. Proceedings of the Nutrition Society 40, 267272.Google Scholar
Flachowsky, G. & Grün, M. (1992). Influence of type of diet and incubation time on major elements release in sacco from Italian ryegrass, untreated and ammonia-treated wheat straw. Animal Feed Science and Technology 36, 239254.Google Scholar
Flachowsky, G., Grün, M., Polzin, S. & Kronemann, H. (1994). In sacco dry matter degradability and Ca, Mg and P disappearance from Italian ryegrass, alfalfa hay and wheat straw in sheep and goats. Journal of Animal Physiology and Animal Nutrition 71, 5764.Google Scholar
Genther, O. N. & Hansen, S. L. (2014). Effect of dietary trace mineral supplementation and a multi-element trace mineral injection on shipping response and growth performance of beef cattle. Journal of Animal Science 92, 25222530.Google Scholar
Han, H., So, H., Domby, E. & Engle, T. E. (2012). The relationship of pulmonary artery copper concentrations and genes involved in copper homeostasis in cattle, swine, and goats. Asian-Australasian Journal of Animal Sciences 25, 194199.CrossRefGoogle ScholarPubMed
He, H., Veneklaas, E. J., Kuo, J. & Lambers, H. (2014). Physiological and ecological significance of biomineralization in plants. Trends in Plant Science 19, 166174.Google Scholar
Humer, E. & Zebeli, Q. (2015). Phytate in feed ingredients and potentials for improving the utilization of phosphorus in ruminant nutrition. Animal Feed Science and Technology 209, 115.Google Scholar
Ibrahim, M. N. M., Zemmelink, G. & Tamminga, S. (1998). Release of mineral elements from tropical feeds during degradation in the rumen. Asian-Australasian Journal of Animal Sciences 11, 530537.CrossRefGoogle Scholar
Jasaitis, D. K., Wohlt, J. E. & Evans, J. L. (1987). Influence of feed ion content on buffering capacity of ruminant feeds in vitro . Journal of Dairy Science 70, 13911403.Google Scholar
Johnson, R. A. & Wichern, D. W. (1998). Applied Multivariate Statistical Analysis. New Jersey, NY, USA: Prentice-Hall International.Google Scholar
Jung, H. G. & Allen, M. S. (1995). Characteristics of plant cell walls affecting intake and digestibility of forages by ruminants. Journal of Animal Science 73, 27742790.Google Scholar
Khattree, R. & Naik, D. N. (2000). Multivariate Data Reduction and Discrimination. Cary, NC, USA: SAS Institute Inc.Google Scholar
Khorasani, G. R., Janzen, R. A., McGill, W. B. & Kennelly, J. J. (1997). Site and extent of mineral absorption in lactating cows fed whole-crop cereal grain silage of alfalfa silage. Journal of Animal Science 75, 239248.Google Scholar
Lestienne, I., Besançon, P. Caporiccio, B., Lullien-Péllerin, V. & Tréche, S. (2005). Iron and zinc in vitro availability in pearl millet flours (Pennisetum glaucum) with varying phytate, tannin, and fiber contents. Journal of Agricultural and Food Chemistry 53, 32403247.CrossRefGoogle ScholarPubMed
Ma, J. F. & Yamaji, N. (2006). Silicon uptake and accumulation in higher plants. Trends in Plant Science 11, 392397.Google Scholar
Maathuis, F. J. & Diatloff, E. (2012). Roles and functions of plant mineral nutrients. In Plant Mineral Nutrients: Methods and Protocols (Ed. Maathuis, F. J. M.), pp. 121. Methods in Molecular Biology 953. Dordrecht, The Netherlands: Springer.Google Scholar
McBurney, M. I., Allen, M. S. & Van Soest, P. J. (1986). Praseodymium and copper cation-exchange capacities of neutral-detergent fibres relative to composition and fermentation kinetics. Journal of the Science of Food and Agriculture 37, 666672.Google Scholar
Mertens, D. R. (2002). Gravimetric determination of amylase-treated neutral detergent fibre in feeds with refluxing beakers or crucibles: collaborative study. Journal of AOAC International 85, 12171240.Google Scholar
Minson, D. J. (1990). Forage in Ruminant Nutrition. San Diego, CA, USA: Academic Press.Google Scholar
Moreira, L. M., Leonel, F. P., Vieira, R. A. M. & Pereira, J. C. (2013). A new approach about the digestion of fibers by ruminants. Revista Brasileira de Saúde e Produção Animal 14, 382395.Google Scholar
NRC (2001). Nutrient Requirements of Dairy Cattle, Revised 7th edn. Washington, DC, USA: The National Academy Press.Google Scholar
NRC (2016). Nutrient Requirements of Beef Cattle, 8th edn. Washington, DC, USA: The National Academy Press.Google Scholar
Olubobokun, J. A., Craig, W. M. & Pond, K. R. (1990). Effects of mastication and microbial contamination on ruminal in situ forage disappearance. Journal of Animal Science 68, 33713381.Google Scholar
Ørskov, E. R., & McDonald, I. (1979). The estimation of protein degradability in the rumen from incubation measurements weighted according to rate of passage. The Journal of Agricultural Science, Cambridge 92, 499503.Google Scholar
Perdomo, J. T., Shirley, R. L. & Chicco, C. F. (1977). Availability of nutrient minerals in four tropical forages fed freshly chopped to sheep. Journal of Animal Science 45, 11141119.Google Scholar
Playne, M. J., Echevarría, M. G. & Megarrity, R. G. (1978). Release of nitrogen, sulphur, phosphorus, calcium, magnesium, potassium and sodium from four tropical hays during their digestion in nylon bags in the rumen. Journal of the Science of Food and Agriculture 29, 520526.Google Scholar
Pogge, D. J., Drewnoski, M. E. & Hansen, S. L. (2014). High dietary sulfur decreases the retention of copper, manganese, and zinc in steers. Journal of Animal Science 92, 21822191.Google Scholar
Prados, L. F., Valadares Filho, S. C., Santos, S. A., Zanetti, D., Nunes, A. N., Costa, D. R., Mariz, L. D. S., Detmann, E., Amaral, P. M., Rodrigues, F. C. & Valadares, R. F. D. (2016). Reducing calcium and phosphorus in crossbred beef cattle diets: impacts on productive performance during the growing and finishing phase. Animal Production Science 56, 16431649.Google Scholar
Ray, P. P., Jarrett, J. & Knowlton, K. F. (2013). Effect of dietary phytate on phosphorus digestibility in dairy cows. Journal of Dairy Science 96, 11561163.Google Scholar
Sath, K., Pauly, T. & Holtenius, K. (2012). Mineral balance of Cambodian cattle based on their faecal and urinary excretion. Journal of Animal and Veterinary Advances 11, 42214225.Google Scholar
Smart, M. E., Gudmundson, J. & Christensen, D. A. (1981). Trace mineral deficiencies in cattle: a review. Canadian Veterinary Journal 22, 372376.Google Scholar
Smith, G. S., Nelson, A. B. & Boggino, E. J. (1971). Digestibility of forages in vitro as affected by content of ‘silica’. Journal of Animal Science 33, 466471.Google Scholar
Spanghero, M., Zanfi, C., Signor, M., Davanzo, D., Volpe, V. & Venerus, S. (2015). Effects of plant vegetative stage and field drying time on chemical composition and in vitro ruminal degradation of forage soybean silage. Animal Feed Science and Technology 200, 102106.Google Scholar
Spears, J. W. (1994). Minerals in forages. In Forage Quality, Evaluation, and Utilization (Ed. Fahey, G. C. Jr.), pp. 281317. Madison, WI, USA: ASA, CSSA, SSSA.Google Scholar
Spears, J. W. (1996). Organic trace minerals in ruminant nutrition. Animal Feed Science and Technology 58, 151163.Google Scholar
Spears, J. W. (2003). Trace mineral bioavailability in ruminants. The Journal of Nutrition 133, 1506S1509S.Google Scholar
Valadares Filho, S. C., Marcondes, M. I., Chizzotti, M. L. & Paulino, P. V. R. (2010). Nutrient Requirements of Zebu Beef Cattle – BR-Corte. 2nd edn. Visconde do Rio Branco, Brazil: Suprema Gráfica e Editora.Google Scholar
Van Eys, J. E. & Reid, R. L. (1987). Ruminal solubility of nitrogen and minerals from fescue and fescue-red clover herbage. Journal of Animal Science 65, 11011112.Google Scholar
Yoshihara, Y., Mizuno, H., Ogura, S., Sasaki, T. & Sato, S. (2013). Increasing the number of plant species in a pasture improves the mineral balance of grazing beef cattle. Animal Feed Science and Technology 179, 138143.Google Scholar
Zanetti, D., Godoi, L. A., Estrada, M. M., Engle, T. E., Silva, B. C., Alhadas, H. M., Chizzotti, M. L., Prados, L. F., Renno, L. N. & Valadares Filho, S. C. (2017). Estimating mineral requirements of Nellore beef bulls fed with or without inorganic mineral supplementation and the influence on mineral balance. Journal of Animal Science 95, 16961706. doi: 10.2527/jas2016.1190.Google Scholar