Impact of three forage based diets on the production of methane and volatile fatty acids in Bos taurus (bovidae)

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Issue: Vol. 17 No. 1 (2013): Enero - Junio

Publication Date: 2013-01-01

How to Cite
Albarracín Z, J. S., Henao U., F. J., & Estrada Á, J. (2013). Impact of three forage based diets on the production of methane and volatile fatty acids in Bos taurus (bovidae). Boletín Científico. Centro De Museos, 17(1), 73–80. Retrieved from https://ucaldas.metarevistas.org/index.php/boletincientifico/article/view/4522
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Authors

Juan Sebastián Albarracín Z,
Universidad de Caldas. Manizales
fhenao@ucaldas.edu.co
Francisco Javier Henao U.
Universidad de Caldas. Manizales
fhenao@ucaldas.edu.co
Julián Estrada Á
Universidad de Caldas. Manizales
fhenao@ucaldas.edu.co

Abstract

This research was carried out in the Agricultural Biotechnology Institute laboratories and in the Tesorito farm from Universidad de Caldas. Nine raise cattle about 200 Kg were used in this experiment, divided into three groups which were fed with Kikuyu grass (Pennisetum clandestinum) in addition to 0, 15 and 30% commercial concentrate food using an experimental design of randomized complete blocks. The independent variable was the level of supplementation, the blocking variable was the date of initiation of each replication, and the experimental unit was a group of three animals. Methane (CH4) and volatile fatty acids (VFA) were taken through direct ruminal puncture in 7 ml vacutainer® tubes in duplicate. These samples were analyzed through gas chromatography techniques with flame ionization detection GC/FID and gaseous chromatography coupled with mass spectrometry GC/MS. With the chromatographic conditions determined in the laboratory, different retention times of volatile compounds were observed: CH4 (1.865 min) propionic acid (3.141 min) acetic acid (2.281 min) and butyric acid (4.387). In this experiment differences (NS) between the three treatments were not observed. Differences (NS) for weight gain between treatments were not found.

Keywords:

metano

ácidos grasos volátiles

cromatografía

bovinos suplementados

methane

volatile fatty acids

chromatography

supplemented cattle

References

BLANCO, M.R. & RIVERA, O.E., 1999. - Adhesión microbiana en el rumen. Sitio Argentino de Producción Animal.

CALSAMIGLIA, S.; CARDOZO, P.W.; FERRET, A.; BACH, A., 2009. Changes in rumen microbial fermentation are due to a combined effect of type of diet and pH. J. Ani. Sci 86: 702-711.

CARMONA, J.C.; BOLÍVAR, D.M.; GIRALDO, L.A., 2005. El gas metano en la producción ganadera y alternativas para medir sus emisiones y aminorar su impacto ambiental y productivo. Revista Colombiana de Ciencias Pecuarias 18(1): 49- 63.

CHURCH, D.C., 1983. El rumiante. Fisiología digestiva y nutrición. 1ed. Acribia. Prentice Halla.

DERAMUS, H.A.; CLEMENT, T.C.; GIAMPOLA, D.D.; DICKISON, P.C., 2003. Methane emissions of beef cattle on forages: efficiency of grazing management systems. J. Environ. Qual., 32: 269-277.

GRAINGER, C.; CLARKE, T.; MCGINN, S.M.; AULDIST, M.J.; BEAUCHEMIN, K.A.; HANNAH, M.C.; WAGHORN, G.C.; CLARK, H. ECKARD, R.J., 2007. Methane Emissions from Dairy Cows Measured Using the Sulfur Hexafluoride (SF6) Tracer and Chamber Techniques. J. Dairy. Sci 90(6):2755-2766.

GUTIÉRREZ, M.C. & DROGUET, M., 2002. La cromatografía de gases y la espectrometría de masas: Identificación de compuestos de mal olor. Boletín Intexter. UPC, n.122, pp. 35–41.

HOLTER, J.B y YOUNG, A.J., 1992. Methane prediction in dry and lactating holstein cows. J. Dairy. Sci. 75: 2165-2175.

JOHNSON, K.A. & JOHNSON, D.E., 1995. Methane emissions from cattle. J. Animal Sci. 73: 2483-2492.

KINSMAN, R.; SAUER, F.D.; JACKSON, H.A.; WOLYNETZ, M.S., 1995. Methane and Carbon Dioxide emissions from dairy cows in full lactation monitored over a six month period. J. Dairy. Sci. 78: 2760-2766.

LILA, Z.A.; MOHAMMED, N.; KANDA, S.; KAMADA, T.; ITABASHI, H., 2003. Effect of sarsaponin on ruminal fermentation with particular reference to methane production in vitro. J. Dairy. Sci. 86: 3330-3336.

MCCAUGHEY, W.; WITTENBERG, K.; CORRIGAN, D., 1999. Impact of pasture type on methane production by lacting beef cows. J. Anim. Sci. 79(2): 221-226.

MENDOZA, G.D.; PLATA, F.X.; ESPINOSA, R.; LARA, A., 2008. Manejo nutricional para mejorar la eficiencia de utilización de la energía en bovinos. Universidad y Ciencia 24(1): 75-87.

MOE, P.W & TYRRELL, H.F., 1979. Methane production in dairy cows. J. Dairy. Sci. 62: 1583-1586.

MONTENEGRO, J. & ABARCA, S., 2000. Fijación de carbono, emisión de CH4 y de óxido nitroso en sistemas de producción bovina en Costa Rica. En: Intensificación de la ganadería en Centroamérica: beneficios económicos y ambientales. CATIE– FAO – SIDE. Ed. Nuestra Tierra.

PEÑALVER, A.M., 2002. Aplicación de la microextraccion en fase solida al análisis medioambiental. Tarragona, España. Universitat Rovira Virgili.

RODRÍGUEZ, A.A.; VALENCIA, E., 2008. Ruminantia. UPRM 3(1): 1-4.

VAN SOEST, P.J., 1994. Nutritional ecology of the ruminant. 2ed. Ithaca. Cornell University Press.

YOKOYAMA, M.T & JOHNSON, K.A., 1993. Microbiología del rumen e intestino. En: Church D.C: El rumiante: fisiología digestiva y nutrición. Editorial Acribia S.A., España.

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