Effect of energy sources ruminal methane production using ex-situ ruminal fermentation technique in bovines

Worldwide issue raised in the last two decades, the generation of greenhouse gases (GGE) has, a contributor parcel in the methane emission by ruminants. Methane, a powerful GGE, is the final product of cattle fermentative process and, for representing productive potential loss, has been studied by nutritionist all over the world. In the search for strategies to reduce losses by methane, different diets, additives and nutritional management have been used. Vegetable lipid sources, such as soybean grain contain high content of unsaturated fatty acids and this type of lipid can contribute to methanogenesis reduction. On the other hand, the inclusion of a high pectin (citrus pulp) source in diets can contribute for methane production increase. In this sense, the objective of the present experiment was to evaluate different energy sources in diet on methane production and fermentation parameters in cattle. The design adopted was a replicated 3x3 Latin square with 16 day period and 3 treatments: Control: Low ether extract diet (3.50% of EE); Soybean: High ether extract diet (inclusion of 15% of soybean grain with 5.30% of EE); Citrus pulp: Low ether extract and high inclusion of pectin diet (inclusion of 15% of citrus pulp with 3.0% of EE). Dry matter intake (DMI) was obtained by the difference between the offered and the surplus of the diet at the last six experimental days. Rumen total liquid volume, total solid volume, solid turnover and ruminal passage rate were obtained by the emptying of this organ performed at days 11 and 12 of each experimental period, before and 3 hours after morning feeding. The solid content was manually removed and the liquid by vacuum pulp and both samples weighed separately. A sample of 10% was used to determine dry matter of rumen content and correct total solid volume. At day 16 of experimental period, ruminal pH was determined by a data logger of continuous measurement. At this day, ruminal content sampling was carried out before, 3, 6, 9 and 12 hours after morning feeding for short chain fatty acids (SCFA) production. Rumen fluid was also collected, through vacuum pulp, for ammonia nitrogen determination. The technique applied to measure methane and SCFA production was the ex situ rumen fermentation that consists on the incubation of penicillin flasks with solid and liquid rumen content in a thermostatic bath for 30 min. After, methane and SCFA determinations were carried out by gas chromatography and the relative energy loss (REL) was estimated. The REL evaluates the efficiency of feed fermentation. In other words, verifies methane loss when compared to other fermentation products. It was observed effect of treatment (P<0.05) for DMI, rumen solid turnover and passage rate. Soybean diet had lower values than control and citrus pulp diet in all these parameters. Treatments did not significantly differ (P>0.05) for total solid volume. The variables mean and maximum ruminal pH, time wich pH was under 5.8; 6.0 and 6.2, as well as, pH area under 5.8 and 6.2 did not differ (P>0.05) between treatments. However, minimum pH was higher (P<0.05) in soybean group when compared to control, without difference of two groups to citrus pulp. pH area under 6.0 was lesser (P<0.05) in soybean group compared with control group, without difference of two groups to citrus pulp. For ammonia nitrogen determination, it was not observed difference (P>0.05) between treatments. Total SCFA, acetate and butirate production (mMol/kg/day) were increased in citrus pulp diet and were decreased in soybean diet. No diet altered (P>0.05) methane production or REL. The inclusion of lipids in the diet of cattle can reduce methane production, but this effect is not specific methanogenic archaea on and therefore does not alter the efficiency of rumen fermentation. Already pectin can increase the production of methane, having high fermentability rumen, without however changing the inefficiency of this process. (AU)