A mathematical model to describe the diurnal pattern of enteric methane emissions from non-lactating dairy cows post-feeding

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• 作者：Min Wang^a ; Rong Wang^a ; Xuezhao Sun^b ; Liang Chen^a ; Shaoxun Tang^a ; Chuangshe Zhou^a ; Xuefeng Han^a ; Jinghe Kang^a ; Zhiliang Tan^a ; ^{Wing_mail@hotmail.com" class="auth_mail" title="E-mail the corresponding author} ; Zhixiong He^a
• 关键词：Methane ; Logistic&ndash ; exponential model ; Methanogen ; Rumen
• 刊名：Animal Nutrition
• 出版年：2015
• 出版时间：December 2015
• 年：2015
• 卷：1
• 期：4
• 页码：329-338
• 全文大小：1321 K

文摘

Enteric methane emission is not only a source of energy loss in ruminants, but also a potent contributor to greenhouse gas production. To identify the nature and timing of interventions to reduce methane emissions requires knowledge of temporal kinetics of methane emissions during animal husbandry. Accordingly, a mathematical model was developed to investigate the pattern of enteric methane emissions after feeding in dairy cows. The model facilitated estimation of total enteric methane emissions (V, g) produced by the residual substrate (V₁, g) and newly ingested feed (V₂, g). The model was fitted to the 10 h methane emission patterns after morning feeding of 16 non-lactating dairy cows with various body weights (BW), and the obtained parameters were used to predict the kinetics of 24 h methane emission for each animal. The rate of methane emission (g/h) reached a maximum within 1 to 2 h after feeding, followed by a gradual post-prandial decline to a basal value before the next feeding. The model satisfactorily fitted curves for each cow according to the criterion of goodness-of-fit, and provided biological descriptions for fluctuations in methane emissions based on basal V₁ and feeding V₂ in response to the changes in BW and dry matter intake (DMI) of different dairy cows. The basal V₁ and feeding V₂ are probably maintained by slow- and readily-degradable substrates, respectively. The former contributed at least 0.6 of methane production. In summary, the model provides a means to separate basal V₁ and feeding V₂ within V, and can be used to predict 24 h emission from a single feeding period.