Martinez-Fernandez Gonzalo, Kinley Robert D, Smith Wendy J M, Simington Jessica, Joseph Stephen, Tahery Sara, Durmic Zoey, Vercoe Phil
Agriculture and Food, CSIRO, St Lucia, QLD, Australia.
Agriculture and Food, CSIRO, Townsville, QLD, Australia.
Front Microbiol. 2024 Nov 19;15:1463817. doi: 10.3389/fmicb.2024.1463817. eCollection 2024.
Biochar has gained significant attention as a possible anti-methanogenic supplement for ruminants due to its potential to reduce methane (CH₄) emissions from enteric fermentation. However, its effects on rumen methanogenesis have been inconsistent and, in some cases, contradictory. These variations are likely influenced by factors such as the type of biochar used, its source material, and how it is administered, including the form in which it is provided and the dosage needed to achieve desired outcomes. This study aimed to examine the effects of two fit-for-purpose biochars on rumen fermentation, CH emissions, and the rumen microbiome of cattle-fed roughage-based diets. Two experiments were conducted to assess the potential of biochar in mitigating CH emissions.
EXPERIMENT 1: This was a controlled pen trial conducted over 56 days, involving 12 steers that were fed Rhodes grass hay . The animals were assigned to one of four treatment groups: control (no biochar, only molasses), low dose (50 g biochar/animal/day), mid dose (100 g biochar/animal/day), or high dose (200 g biochar/animal/day). Two types of biochar, Biochar 1 and Biochar 2, were administered with molasses (200 mL per animal/day). Methane emissions were measured using open-circuit respiration chambers, and rumen fluid samples were collected for analysis of the rumen microbial community and fermentation metabolite.
EXPERIMENT 2: In this trial, 45 heifers were selected and grazed together in a single paddock for 60 days to assess the effects of biochar on productivity and CH emissions under grazing conditions. The animals were allocated to one of three treatment groups (15 animals per group): control (no biochar, only molasses), Biochar 1, or Biochar 2. Each group was administered biochar at an estimated single dose of 100 g per animal/day mixed with molasses. Methane emissions were measured using GreenFeed systems in the field to monitor CH₄ production from individual animals.
In the controlled pen trial (Experiment 1), biochar supplementation resulted in a reduction of CH₄ emissions by 8.8-12.9% without any negative effects on rumen fermentation or dry matter intake (DMI). Minor changes were observed in the rumen bacterial community, particularly in the and families. However, in the grazing trial (Experiment 2), no significant differences in CH₄ emissions or productivity were detected with biochar supplementation.
While the results from controlled feeding conditions suggest that biochar has the potential to reduce enteric CH₄ emissions, the lack of significant findings under grazing conditions highlights the need for further research. Future studies should focus on identifying biochar types, doses, and delivery methods that are effective in reducing CH₄ emissions in grazing systems without compromising cattle productivity.
生物炭作为反刍动物潜在的抗甲烷生成补充剂受到了广泛关注,因为它有潜力减少瘤胃发酵产生的甲烷(CH₄)排放。然而,其对瘤胃甲烷生成的影响并不一致,在某些情况下甚至相互矛盾。这些差异可能受到多种因素影响,如所用生物炭的类型、原料来源以及施用方式,包括提供的形式和达到预期效果所需的剂量。本研究旨在探讨两种适用的生物炭对以粗饲料为基础日粮的肉牛瘤胃发酵、CH排放和瘤胃微生物群的影响。进行了两项实验来评估生物炭在减少CH排放方面的潜力。
实验1:这是一项为期56天的对照栏舍试验,涉及12头以罗德草干草为食的阉牛。动物被分配到四个处理组之一:对照组(不添加生物炭,仅添加糖蜜)、低剂量组(每头动物每天50克生物炭)、中剂量组(每头动物每天100克生物炭)或高剂量组(每头动物每天200克生物炭)。两种生物炭,生物炭1和生物炭2,与糖蜜(每头动物每天200毫升)一起施用。使用开路呼吸室测量甲烷排放,并收集瘤胃液样本用于分析瘤胃微生物群落和发酵代谢产物。
实验2:在该试验中,挑选了45头小母牛,在一个围栏中一起放牧60天,以评估生物炭在放牧条件下对生产力和CH排放的影响。动物被分配到三个处理组之一(每组15头动物):对照组(不添加生物炭,仅添加糖蜜)、生物炭1组或生物炭2组。每组以每头动物每天估计100克的单剂量将生物炭与糖蜜混合施用。在田间使用GreenFeed系统测量甲烷排放,以监测个体动物的CH₄产生情况。
在对照栏舍试验(实验1)中,添加生物炭使CH₄排放减少了8.8 - 12.9%,且对瘤胃发酵或干物质摄入量(DMI)没有任何负面影响。在瘤胃细菌群落中观察到了微小变化,特别是在 科和 科。然而,在放牧试验(实验2)中,添加生物炭后未检测到CH₄排放或生产力的显著差异。
虽然对照饲养条件下的结果表明生物炭有潜力减少瘤胃CH₄排放,但放牧条件下缺乏显著结果凸显了进一步研究的必要性。未来的研究应专注于确定在不影响肉牛生产力的情况下,能有效减少放牧系统中CH₄排放的生物炭类型、剂量和施用方法。
