Micro- and Macro-Algae Combination As a Novel Alternative Ruminant Feed with Methane-Mitigation Potential

Overview

Journal Animals (Basel)

Date 2023 Mar 11

PMID 36899652

Authors

Eslam Ahmed

Kengo Suzuki

Takehiro Nishida

Affiliations

Soon will be listed here.

Abstract

This study was conducted to provide alternative high-quality feed and to reduce methane production using a mixture of the minimum effective levels of , EG, and , AT. This study was performed as a 24 h in vitro batch culture. Chemical analysis demonstrated that EG is a highly nutritive material with 26.1% protein and 17.7% fat. The results showed that the supplementation of AT as a feed additive at 1 and 2.5% of the diet reduced methane production by 21 and 80%, respectively, while the inclusion of EG in the diet at 10 and 25% through partially replacing the concentrate mixture reduced methane production by 4 and 11%, respectively, with no adverse effects on fermentation parameters. The mixtures of AT 1% with both EG 10% and EG 25% had a greater reductive potential than the individual supplementation of these algae in decreasing methane yield by 29.9% and 40.0%, respectively, without adverse impacts on ruminal fermentation characteristics. These results revealed that the new feed formulation had a synergistic effect in reducing methane emissions. Thus, this approach could provide a new strategy for a sustainable animal production industry.

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