Dose- and substrate-dependent reduction of enteric methane and ammonia by natural additives in vitro

Marco Battelli; Mette Olaf Nielsen; Natalja P Nørskov

doi:10.3389/fvets.2023.1302346

Dose- and substrate-dependent reduction of enteric methane and ammonia by natural additives in vitro

Front Vet Sci. 2023 Nov 6:10:1302346. doi: 10.3389/fvets.2023.1302346. eCollection 2023.

Authors

Marco Battelli¹, Mette Olaf Nielsen², Natalja P Nørskov²

Affiliations

¹ Department of Agricultural and Environmental Sciences - Production, Landscape, Agroenergy, University of Milan, Milan, Italy.
² Department of Animal and Veterinary Sciences, AU Viborg - Research Center Foulum, Aarhus University, Tjele, Denmark.

Abstract

Ruminants contribute to global warming by emitting greenhouse gasses, particularly methane (CH₄) which is a product of rumen fermentation. The use of feed additives able to modulate rumen fermentation is a promising strategy to reduce enteric CH₄ and ammonia (NH₃) emissions. Among the various strategies investigated, plant secondary metabolites (PSMs) have attracted attention due to their apparent potential to reduce enteric CH₄ and NH₃ emissions, and it would be possible to use such compounds as feed additives in organic production systems. In an in vitro system simulating rumen fermentation, we have tested the impact of different classes of naturally occurring PSMs; catechin and quercetin (flavonoids), salicylic acid (phenolic acid) and tannic acid (hydrolysable tannin). The PSMs were added to two different basal feeds (maize and grass silages) at three inclusion doses 1.5, 3 and 6% of the feed dry matter (DM). CH₄ production was significantly lowered upon addition of quercetin to two basal feeds at doses of 3 and 6%, and this without changes in concentrations of total volatile fatty acid (VFA) produced during fermentation. Quercetin, as the only tested additive, reduced CH₄ production, and when added to maize silage and grass silage, the reduction increased linearly with increasing dose, ie., by 51 and 43%, respectively, at a dose of 3% of feed DM and by 86 and 58%, respectively, at a dose of 6% of feed DM. Moreover, quercetin significantly reduced NH₃ concentration by >12% at doses of 3 and 6% in feed DM irrespective of the basal feed used as compared to when the basal feeds were incubated alone. Although none of the other additives affected CH₄ formation, several additives had significant impacts on concentrations of NH₃ and VFAs in the incubated fluid after fermentation. This study demonstrated a dose-dependent ability of quercetin to reduce CH₄ emission from rumen fermentation, however, the magnitude of the suppression of CH₄ depended on the basal feed. Furthermore, quercetin reduced NH₃ concentration irrespective of the basal feed type. These findings encourage to in vivo studies to verify whether quercetin can reduce CH₄ emission also in cows.

Keywords: catechin; plant secondary metabolites; quercetin; rumen fermentation; salicylic acid; tannic acid.

Grants and funding

The author(s) declare financial support was received for the research, authorship, and/or publication of this article. The research conducted in this study is part of the ECOCO2W project (Tannins of willow and hemp as organic feed additives for methane reduction in dairy cows). The project ECOCO2W is part of the Organic RDD 7 program, which is coordinated by the International Center for Research in Organic Food Systems (ICROFS). It has received grant from the Green Growth and Development program (GUDP) under the Danish Ministry of Food, Agriculture, and Fisheries.