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Influence of Grain Processing and Dietary Protein Degradability on Nitrogen Metabolism, Energy Balance and Methane Production in Young Calves
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 Title & Authors
Influence of Grain Processing and Dietary Protein Degradability on Nitrogen Metabolism, Energy Balance and Methane Production in Young Calves
Pattanaik, A.K.; Sastry, V.R.B.; Katiyar, R.C.; Lal, Murari;
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Crossbred (Bos taurusBos indicus) calves were used from birth till 14 weeks of age to evaluate three sources of protein that differed in ruminal degradability viz. groundnut cake alone (HD) or in combination with cottonseed meal (MD) and meat and bone meal (LD), when fed along with two sources of non-structural carbohydrates viz. raw (R) and thermally processed (P) maize. Twenty four new born calves were arranged in six groups in a factorial design and fed on whole milk up to 56 d of age. All the different calves received calf startes along with green oats (Avena sativa) from 14 d of age onwards free-choice. A metabolism trial of 6d starters duration, conducted after 90 d of experimental feeding, revealed greater (p<0.05) digestibility of DM, OM, total carbohydrates, NDF and ADF in calves fed on the P diets than on the R diets promoting greater (p<0.05) metabolizable energy intake. The digestibility of NDF was higher (p<0.01) on LD diets where as calves on MD diets exhibited significantly lower digestibility of ADF (p<0.01). The retention of nitrogen per unit metabolic body size was significantly (p<0.05) higher on the LD-P diet than on the diet HD-P which, in turn, was higher (p<0.05) than that of HD-R. Nitrogen retention as percentage of intake was significantly greater (p<0.05) on LD-P than on LD-R diets (52.2 vs. 36.4%). Also, P fed calves utilized nitrogen more efficiently than the R fed as shown by retention of significantly greater proportions of intake (47.4 vs. 40.9%) and absorbed (65.8 vs. 59.5%) nitrogen. Calorimetric evaluation of the diets through open-circuit respiration chamber revealed that the dietary treatments had no impact on methane production by calves. The intake of DE and ME was improved (p<0.01) because of maize processing resulting in greater (p<0.01) retention of energy. The protein degradability exerted no influence on the partitioning or retention of energy. A significant interaction between cereal and protein types was evident with respect to retention of both nitrogen (p<0.01) and energy (p<0.05). In conclusion, no discernible trend in the influence of cereal processing was apparent on the dietary protein degradability, but the positive effect of cereal processing on energy retention diminished with the increase in dietary undegradability.
Cereal Processing;Protein;Nitrogen Retention;Energy Balance;Calves;
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Abdelgadir, I. E. O., J. L. Morril and J. J. Higgins. 1996. Effect of roasted soybean and corn on performance and ruminal and blood metabolites of dairy calves. J. Dairy Sci. 79:465-474.

AOAC. 1990. Official Methods of Analysis, 15th Ed. Association of Official Analytical Chemists, Washington, DC.

Brouwer, E. 1965. Report of sub-committee on constants and factors. Proc. III EAAP Symp. In Energy Metabolism, EAAP Publ. No. 11, Academic Press, London. pp. 441-443.

Campling, R. C. 1991. Processing of cereal grains for cattle - a review. Livestock Prod. Sci. 28:223-234.

Coomer, J. C. and H. E. Amos. 1991. Influence of source of rumen escape protein on growth, feed efficiency and nutrient digestibility in weaned dairy calves. J. Anim. Sci. 66 (Suppl. 1):527 (Abstr.).

Cummins, K. A., J. E. Nocek and C. E. Polan. 1982. Growth and nitrogen balance of calves fed rations of varying nitrogen degradability and physical form. J. Dairy Sci. 65:773-783.

Donelly, P. E. 1983. Effects of dietary carbohydrate : fat ratio on growth and body composition of milk-fed calves. N.Z. J. Agric. Res. 26:71.

Duncan, D. B. 1955. Multiple rage and multiple F tests. Biometrics. 11:1-12. crossref(new window)

Epifanov, G. V., A. F. Zakachurin, Z. A. Netecha and A. E. Zaikin. 1988. Digestibility of nutrients and productivity of young cattle on diets containing varying amounts of sugar and sulphur. Doklady Vsesoyuznoi Auademi Selskokho Zyaistvennykin Nauk, 2:27-29.

Fiems, L. O., C. V Boucque, B. G. Cottyn and F. X. Buysse. 1986. Cottonseed meal and maize gluten meal vs. soybean meal as protein supplements in calf starters. Arch. Anim. Nutr. 36:731-740.

Gaylean, M. L., D. G. Wagner and F. N. Owens. 1981. Dry matter and starch disappearance of corn and sorghum as influenced by particle size and processing. J. Dairy Sci. 64:1804.

Goering, H. K. and P. J. Van Soest. 1970. Forage fibre analysis (apparatus, reagents, procedures and some applications). ARS. US Dept. Agric. Hand book No. 379. Supdt. of Documents. US Govt. Printing office, Washington, D.C.

Grubic, G. 1988. Nutritional value of heat processed maize grain when feeding calves. Arhiv Za Polioprivredne Nauke, 49:11-36.

Guglya, V. G. and V. S. Safonov. 1985. Utilization of extruded barley for feeding of cow. Zhivotnovodstvo, 9:51-52.

Herrera-Saldana, R. and J. T. Huber. 1989. Influence of varying protein and starch degradabilities on performance of lactating cows. J. Dairy Sci. 72:1477-1483.

Hussein, H. S., M. D. Stern and R. M. Jordan. 1991. Influence of dietary protein and carbohydrate sources on nitrogen metabolism and carbohydrate fermentation by ruminal microbes in continuous culture. J. Anim. Sci. 3:2123-2133.

Johnson, D. E. and G. M. Ward. 1996. Estimates of animal methane emission. Environmental Monitoring and Assessement, 42:133-141.

Khan, M. Y. and D. C. Joshi. 1983. A new simplified open-circuit respiration equipment for sheep - a note. Indian J. Anim. Prod. 15:34-36.

Klopfenstein, T. 1988. Bypass protein-concepts and practical uses. p. 53 In: Proc. California Anim. Nutr. Conf., Fresno.

Kurihara, K., T. Magner, R. A. Hunter and G. J. McCrabb. 1999. Methane production and energy partition of cattle in the tropics. Br. J. Nutr. 81:227-234.

Lee, S. C., W. S. Kang and S. S. Lee. 1990. The effects of different processing methods on the digestibility and energy value of corns in Korean native cattle. Res. Rpts. of the Rural Dev. Admn. Livestock, 32:21-26.

Lindberg, J. E. 1981. The effect of basal diet on the ruminal degradation of dry matter, nitrogen compounds and cell walls in nylon bag - roughage and cereals in various proportions. Swedish J. Agric. Res. 11:159.

Maiga, H. A., D. J. Schinogoethe, F. C Ludens, W. L. Tucker and D. P. Casper. 1994. Response of calves to diets that varied in amounts of ruminally degradable carbohydrates and protein. J. Dairy Sci. 77:278-283.

Malcolm, K. J. and H. E. Kiesling. 1993. Dry matter disappearance and gelatinization of grains as influenced by processing and conditioning. Anim. Feed Sci. Tech. 40:321-330.

Matras, J., S. J. Bartle and R. L. Preston. 1991. Nitrogen utilization in growing lambs: effects of grain (starch) and protein sources with various rates of ruminal degradation. J. Anim. Sci. 69:339-347.

McAllan, A. B. and E. S. Griffith. 1987. The effects of different sources of nitrogen supplementation on the digestion of fibre components in the rumen of steers. Anim. Feed. Sci. Tech. 17: 65.

McAllister, T. A., K. A. Beauchemin, L. A. McClelland and K. J. Cheng. 1992. Effect of formaldehyde - treated barley or escape protein on nutrient digestibility, growth and carcass traits of feed lot lambs. Can. J. Anim. Sci. 72:309-316.

McCarthy, R. D. Jr., T. H. Klusmeyer, J. L Vicini, J. H. Clark and D. R Nelson. 1989. Effects of source of protein and carbohytrate on ruminal fermentation and passage of nutrients to the small intestine of lactating cows. J. Dairy. Sci. 72:2002-2016.

Morgan, E. K., M. L. Gibson, M. L. Nelson and J. R. Males. 1991. Utilization of whole or steam rolled barley fed with forages to wethers and cattle. Anim. Feed Sci. Tech. 33:59-78.

Olivares-Reyna, L., J. R. Herrera-Saldana, R. Barcena-Gama and S. Gonzalez-Munoz. 1992. The effect of different protein and starch sources in starters for young calves. J. Dairy Sci. 75 (Suppl. 1):269 (Abstr.).

Orskov, E. R. and J. McDonald. 1979. The estimation of protein degradability in rumen from incubation measurements weighted according to rate of passage. J. Agric. Sci. Camb. 92:499-503.

Pattanaik, A. K., V. R. B. Sastry and R. C. Katiyar. 2000. Effect of thermal processing of cereal grain on the performance of crossbred calves fed starters containing protein sources of varying ruminal degradability. Asian-Aust. J. Anim. Sci. 13: 1239-1244.

Pattanaik, A. K., V. R. B. Sastry, R. C. Katiyar and Murari Lal. 1998. Energy kinetics in crossbred calves on synchronized rumen degradable protein and starch based diets. Proc. VIII World Animal Production Conference, July 3-8, 1998, Seoul, Korea. 58-59.

Prasad, D. A., J. L. Morril, S. L. Meton and A. D. Dayton. 1975. Evaluation of processed sorghum grain and wheat by cattle and by in vitro techniques. J. Anim. Sci. 41:578-587.

Punj, M. L. 1995. Feeding strategies in the utilization of agroindustrial by products. Proc. VII Anim. Nutr. Res. Workers Conf., Dec. 7-9, 1995. Bombay, India, pp. 13-19.

Sahoo, B., M. L. Saraswat, N. Haque and M. Y. Khan. 2000. Energy balance and methane production in sheep fed chemically treated wheat straw. Small Rumin. Res. 35:13-19.

Sahoo, S. K. 1992. Effect of high and low degradable protein rations on nutrient utilization in buffalo. M. V. Sc. Thesis. Indian Veterinary Research Institute, Deemed University, Izatnagar, India.

Snedecor, G. W. and W. G. Cochran. 1967. Statistical methods. 6th Ed. Iowa State Univ. Press, Ames, Iowa.

Stokes, S. R., W. H. Hoover, T. K. Miller and R. Blauwekel. 1991. Ruminal digestional and microbial utilization of diets varying in type of carbohydrate and protein. J. Dairy Sci. 74:871-881.

Theurer, C. B. 1986. Grain processing effects on starch utilization by ruminants. J. Anim. Sci. 63:1649-1662.

Tiwari, C. M., S. B. Jadhao, Chandramoni, Murari Lal and M. Y. Khan. 2000. Comparative calorimetric evaluation of ammoniated straw-based rations supplemented with low levels of untreated, formaldehyde treated groundnut cake and fish meal with respect to growing buffalo calves. Asian-Aust. J. Anim. Sci. 13:761-773.

Van Soest, P. J. 1994. Nutritional Ecology of the Ruminants. 2nd Ed. Cornell University Press, Ithaca, NY.

Veen, W. A. G. 1986. The influence of slowly and rapidly degradable concentrate protein on a number of rumen parameters in dairy cattle. Neth. J. Agric. Sci. 34:199.

Zinn, R. A. 1993. Influence of processing on the comparative feeding value of barley for feedlot cattle. J. Anim. Sci. 71:3-10.