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Effect of Feeding Dried Apple Pomace on Ruminal Fermentation, Methane Emission, and Biohydrogenation of Unsaturated Fatty Acids in Dairy Cows
Industrial fruit by-products are now being utilized as animal feeds for several reasons. They may substitute the conventional cereal feeds, and also offer economic and environmental benefits. One of the most important industrial fruit by-products is apple pomace, which can be used as a source of energy in the ration of ruminant species, including dairy cattle. The aim of the present study was to evaluate the effect of feeding dried apple pomace to dairy cattle on ruminal fermentation, fatty acid concentration, microbial populations, and methane production. The experiment lasted 64 days and was conducted with 4 cannulated commercial dairy cows. The control animals received a standard diet, while the experimental animals was fed a standard diet supplemented with 150 g/kg DM dried apple pomace. Ruminal fluid samples were collected at three different time intervals. The samples were obtained at 0-, 3-, and 6-h post-feeding. The ruminal fluid was used to assess the ammonia concentration, pH, volatile fatty acids (VFA), long-chain fatty acids (FA), microbial population. A number of ruminal fermentation variables changed as a result of the addition of dried apple pomace to the standard diet. Ruminal pH slightly increased (p < 0.01) while the ammonia concentration decreased (p < 0.01) by 46%. There was a significant decrease in total protozoa count (p < 0.01) and an increase (p < 0.01) in total volatile fatty acids. In addition, there was a decline in methane emission (p = 0.05) by 8% due to dried apple pomace feeding. To sum up, this study demonstrated a positive effect of 150 g/kg DM dietary dried apple pomace on ruminal metabolism including a decrease in ammonia concentration and methane emissions, alongside with an increase in total ruminal VFAs, higher nutrient digestibility, and milk production. Also, beneficial changes to the ruminal fatty acid profile resulting from reduced biohydrogenation were observed although a decreased content of the C18:2 cis 9 trans 11 isomer was also noticed. The dietary inclusion of DAP can serve as a valuable, sustainable, and environmentally friendly dietary component for dairy cows.
Effect of multispecies swards on ruminal fermentation, methane emission and potential for climate care cattle farming − an in vitro study
Leverage of Essential Oils on Faeces-Based Methane and Biogas Production in Dairy Cows
Currently, there is an ongoing intensive search for solutions that would effectively reduce greenhouse gas emissions (mainly methane) into the environment. From a practical point of view, it is important to reduce methane emissions from cows in such a way as to simultaneously trim emissions from the digestive system and increase its potential production from feces, which is intended as a substrate used in biogas plants. Such a solution would not only lower animal-based methane emissions but would also enable the production of fuel (in chemical form) with a high yield of methane from biogas, which would boost the economic benefits and reduce the use of fossil fuels. We tested the effect of administering an essential oil blend consisting of 5.5% oils and fats on methane and biogas production from dairy cow feces during fermentation. Three subsequent series (control and experimental) were conducted in dairy cows fed a total mixed ration (TMR) rich in brewer’s cereals and beet pulp, with 20% dry matter (DM) of the total diet. Cows from the experimental group received 20 g/cow/day of essential oil blend, namely a commercial additive (CA). The study showed that CA can increase the production of methane and biogas from dairy cow feces. It can be concluded that in the experimental groups, approx. 15.2% and 14.4% on a fresh matter basis and 11.7% and 10.9% on a dry matter basis more methane and biogas were generated compared to the control group, respectively. Therefore, it can be assumed that the use of CA in cow nutrition improved dietary digestibility, which increased the efficiency of the use of feces organic matter for biogas production.
Potential of Paulownia Leaves Silage in Lamb Diet to Improve Ruminal Fermentation and Fatty Acid Profile − An in vitro Study
Abstract Environmental impact, quality, and quantity of food products of ruminant origin (especially beef and mutton) are considered major challenges in meeting the nutritional requirements of the growing human population worldwide. Therefore, we conducted this in vitro study to explore the potential of Paulownia leaves silage to reduce the environmental impact of feedlot lamb production and improve ruminal fatty acids (FAs) profile by influencing ruminal biohydrogenation. In the present study, Paulownia leaves silage (PLS) and alfalfa silage (AAS) were mixed in a proportion of 1:0 (Control, PLS 0%), 0.75:0.25 (PLS 25%), 0.5:0.5 (PLS 50%), 0.25:0.75 (PLS 75%) and 0:1 (PLS 100%) on dry matter basis in the lamb diet. The experimental findings demonstrated that 100% replacement of AAS with PLS in the lamb diet significantly improved the ruminal fermentation by increasing the in vitro DM degradability (P<0.01), total volatile fatty acid (P<0.01), and propionate production (P<0.01) while reducing the acetate: propionate (A/P) ratio (P<0.01) and CH4 concentration (mM; L and Q P<0.05) and CH4 production, mM/g DM (L and Q P<0.05). Meanwhile, 100% PLS inclusion in the diet increased the total monounsaturated fatty acids (P<0.05), total unsaturated fatty acids (P<0.01) and total n-3 fatty acids (P<0.05) particularly alpha-linolenic acid (ALA; C18:3 n-3; P<0.05) in the rumen fluid after incubation. Moreover, the total saturated fatty acids concentration was reduced (P<0.01). These findings suggested that PLS could be a climate-friendly and sustainable alternative to AAS in the lamb feedlot diet for quality meat production.