反刍家畜瘤胃甲烷预测模型的研究进展
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摘要
甲烷作为全球第二大温室气体,不仅严重污染空气,而且还是造成反刍家畜日粮碳水化合物消化代谢过程中重要的能量损失。文中综述了国内外经典的反刍家畜甲烷模型,分析了影响模型精度的原因,为预测甲烷排放提供参考依据。
Methane as the second largest greenhouse gas in the world seriously causes s the air pollution,but also is an important energy loss in the process of digestion and metabolism of carbohydrate in ruminant diets. T Classical models for ruminant methane production,factors affecting the accuracy of the model were summarized in order to provides references for forecasting methane emission.
Methane as the second largest greenhouse gas in the world seriously causes s the air pollution,but also is an important energy loss in the process of digestion and metabolism of carbohydrate in ruminant diets. T Classical models for ruminant methane production,factors affecting the accuracy of the model were summarized in order to provides references for forecasting methane emission.
引文
[1] Intergovernmental Panel on Climate change. Climate change2007:The physical science basis[M]. Cambridge:Cambridge University Press,UK,2007.
[2] Knapp J R,Laur G L,Vadas P A,et al.Invited review:Enteric methane in dairy cattle production:quantifying the opportunities and impact of reducing emissions[J].Journal of Dairy Science,2014,97(6):3231-3261.
[3]王荣,邓近平,王敏,等.基于IPCC Tier 1层级的中国反刍家畜胃肠道甲烷排放格局变化分析[J].生态学报,2015,35(21):7244-7254.
[4] Johnson K A,Johnson D E.Methane emissions from cattle[J].Journal of Animal Science,1995,73(8):2483-2492.
[5] Alemu A W,Ominski K H,Kebreab E. Estimation of enteric methane emissions trends(1990-2008)from Manitoba beef cattle using empirical and mechanistic models[J].Canada Journal of Animal Science,2011,91(2):305-321.
[6] Kriss M.Quantitative relations of the dry matter of the food consumed,the heat production,the gaseous outgo,and the insensible loss in body weight of cattle[J]. Journal of Agricultural Research,1930,40(3):283-295.
[7] Axelsson J.The amount of produced methane energy in the European metabolic experiments with adult cattle[J]. Kungliga Lantbrukshogskolans Annaler,1949,16:404-419.
[8] Wheelock J B,Rhoads R P,Vanbaale M J,et al.Effects of heat stress on energetic metabolism in lactating Holstein cows[J].Journal of Dairy Science,2010,93(2):644-655.
[9] Demarchi J J A A,Manella M Q,Loureno A J,et al. Daily methane emission at different seasons of the year by Nelore cattle in Brazil grazing Brachiaria brizantha cv[C].Preceedings of the 3rd International Methane and Nitrous Oxide Mitigation Confenrence Marandu(II).Beijing:[s.n.],2003:80-84.
[10]颜志成,谢天宇,王荣,等.冬春两季奶牛胃肠道甲烷排放量变化的研究[J].湖南农业科学,2015(2):50-54.
[11] Moe P W,Tyrrell H F.Methane Production in Dairy Cows[J].Journal of Dairy Science,1979,62(10):1583-1586.
[12]韩继福,冯仰廉.阉牛不同日粮的纤维消化,瘤胃内VFA对甲烷产生量的影响[J].中国兽医学报,1997,17(3):278-280.
[13]冯仰廉.反刍动物营养学[M].北京:科学出版社,2000.
[14] Yan T,Porter M G,Mayne C S.Prediction of methane emission from beef cattle using data measured in indirect open-circuit respiration calorimeters[J]. Animal:An International Journal of Animal Bioscience,2009,3(10):1455-1462.
[15] Blaxter K L,Clapperton J L.Prediction of the amount of methane produced by ruminants[J]. British Journal of Nutrition,1965,19(4):511.
[16] OECD.Emission of greehouse gas emissions and sinks[R].Final report from the OECD experts meeting,1991:51-56.
[17] Intergovernmental Panel on Climate Change. Climate change1997:The physical science basis[M]. Cambridge:Cambridge University Press,UK,1997.
[18] Intergovernmental Panel on Climate Change. Climate change2006:The physical science basis[M]. Cambridge:Cambridge University Press,UK,2006.
[19] Yan T,Agnew R E,Gordon F J,et al.Prediction of methane energy output in dairy and beef cattle offered grass silagebased diets[J]. Livestock Production Science,2000,64(2/3):253-263.
[20] Auffret M D,Stewart R,Dewhurst R J,et al. Identification,Comparison,and Validation of Robust Rumen Microbial Biomarkers for Methane Emissions Using Diverse Bos Taurus Breeds and Basal Diets[J].Frontiers in Microbiology,2017,8(8):2462.
[21]孙家义,李凤双,韩红岩.三至七月龄小尾寒羊营养代谢中甲烷气产量和能值的初步研究[J].动物营养学报,1998,10(2):27-34.
[22] Ellis J L,Kebreab E,Odongo N E,et al.Prediction of methane production from dairy and beef cattle[J].Journal of Dairy Science,2007,90(7):3456-3466.
[23] Ellis J L,Kebreab E,Odongo N E,et al. Modeling methane production from beef cattle using linear and nonlinear approaches[J].Journal of Animal Science,2009,87(4):1334-1345.
[24] Patra A K.Prediction of enteric methane emission from cattle using linear and non-linear statistical models in tropical production systems[J]. Mitigation&Adaptation Strategies for Global Change,2017,22(4):629-650.
[25]毛宏祥,高凤仙,王敏,等.肉牛胃肠道甲烷排放模型估算精度的评估分析[J].畜牧兽医学报,2017,48(4):690-698.
[26] Kirchgessner M,Windisch W,Müller H L,et al. Nutritional factors for the quantification of methane production[C].Ruminant Physiology:Digestion,Metabolism,Growth and Reproduction.Proceedings,International Symposium on Ruminant Physiology,1995.
[27] Palliser C C,Woodward S L. Using models to predict methane reduction in pasture-fed dairy cows[J]. Citeseer,2002,482(1):162-167.
[28]谢天宇,王敏,王荣,等.奶牛胃肠道甲烷排放模型估算精度的评估分析[J].畜牧兽医学报,2015,46(9):1574-1583.
[29] Baldwin R L,France J,Gill M. Metabolism of the lactating cow.I.Animal elements of a mechanistic model[J]. Journal of Dairy Research,1987,54(1):77-105.
[30]王荣,杨玲媛,王敏,等.基于挥发性脂肪酸化学计量模型体外预测山羊瘤胃甲烷产量的精度[J].应用生态学报,2014,25(5):1518-1524.
[31] Czerkawski J W,Cheng K J.Compartmentation in the rumen[J].Rumen Microbial Ecosystem,1988,59(9):3046-3052.
[2] Knapp J R,Laur G L,Vadas P A,et al.Invited review:Enteric methane in dairy cattle production:quantifying the opportunities and impact of reducing emissions[J].Journal of Dairy Science,2014,97(6):3231-3261.
[3]王荣,邓近平,王敏,等.基于IPCC Tier 1层级的中国反刍家畜胃肠道甲烷排放格局变化分析[J].生态学报,2015,35(21):7244-7254.
[4] Johnson K A,Johnson D E.Methane emissions from cattle[J].Journal of Animal Science,1995,73(8):2483-2492.
[5] Alemu A W,Ominski K H,Kebreab E. Estimation of enteric methane emissions trends(1990-2008)from Manitoba beef cattle using empirical and mechanistic models[J].Canada Journal of Animal Science,2011,91(2):305-321.
[6] Kriss M.Quantitative relations of the dry matter of the food consumed,the heat production,the gaseous outgo,and the insensible loss in body weight of cattle[J]. Journal of Agricultural Research,1930,40(3):283-295.
[7] Axelsson J.The amount of produced methane energy in the European metabolic experiments with adult cattle[J]. Kungliga Lantbrukshogskolans Annaler,1949,16:404-419.
[8] Wheelock J B,Rhoads R P,Vanbaale M J,et al.Effects of heat stress on energetic metabolism in lactating Holstein cows[J].Journal of Dairy Science,2010,93(2):644-655.
[9] Demarchi J J A A,Manella M Q,Loureno A J,et al. Daily methane emission at different seasons of the year by Nelore cattle in Brazil grazing Brachiaria brizantha cv[C].Preceedings of the 3rd International Methane and Nitrous Oxide Mitigation Confenrence Marandu(II).Beijing:[s.n.],2003:80-84.
[10]颜志成,谢天宇,王荣,等.冬春两季奶牛胃肠道甲烷排放量变化的研究[J].湖南农业科学,2015(2):50-54.
[11] Moe P W,Tyrrell H F.Methane Production in Dairy Cows[J].Journal of Dairy Science,1979,62(10):1583-1586.
[12]韩继福,冯仰廉.阉牛不同日粮的纤维消化,瘤胃内VFA对甲烷产生量的影响[J].中国兽医学报,1997,17(3):278-280.
[13]冯仰廉.反刍动物营养学[M].北京:科学出版社,2000.
[14] Yan T,Porter M G,Mayne C S.Prediction of methane emission from beef cattle using data measured in indirect open-circuit respiration calorimeters[J]. Animal:An International Journal of Animal Bioscience,2009,3(10):1455-1462.
[15] Blaxter K L,Clapperton J L.Prediction of the amount of methane produced by ruminants[J]. British Journal of Nutrition,1965,19(4):511.
[16] OECD.Emission of greehouse gas emissions and sinks[R].Final report from the OECD experts meeting,1991:51-56.
[17] Intergovernmental Panel on Climate Change. Climate change1997:The physical science basis[M]. Cambridge:Cambridge University Press,UK,1997.
[18] Intergovernmental Panel on Climate Change. Climate change2006:The physical science basis[M]. Cambridge:Cambridge University Press,UK,2006.
[19] Yan T,Agnew R E,Gordon F J,et al.Prediction of methane energy output in dairy and beef cattle offered grass silagebased diets[J]. Livestock Production Science,2000,64(2/3):253-263.
[20] Auffret M D,Stewart R,Dewhurst R J,et al. Identification,Comparison,and Validation of Robust Rumen Microbial Biomarkers for Methane Emissions Using Diverse Bos Taurus Breeds and Basal Diets[J].Frontiers in Microbiology,2017,8(8):2462.
[21]孙家义,李凤双,韩红岩.三至七月龄小尾寒羊营养代谢中甲烷气产量和能值的初步研究[J].动物营养学报,1998,10(2):27-34.
[22] Ellis J L,Kebreab E,Odongo N E,et al.Prediction of methane production from dairy and beef cattle[J].Journal of Dairy Science,2007,90(7):3456-3466.
[23] Ellis J L,Kebreab E,Odongo N E,et al. Modeling methane production from beef cattle using linear and nonlinear approaches[J].Journal of Animal Science,2009,87(4):1334-1345.
[24] Patra A K.Prediction of enteric methane emission from cattle using linear and non-linear statistical models in tropical production systems[J]. Mitigation&Adaptation Strategies for Global Change,2017,22(4):629-650.
[25]毛宏祥,高凤仙,王敏,等.肉牛胃肠道甲烷排放模型估算精度的评估分析[J].畜牧兽医学报,2017,48(4):690-698.
[26] Kirchgessner M,Windisch W,Müller H L,et al. Nutritional factors for the quantification of methane production[C].Ruminant Physiology:Digestion,Metabolism,Growth and Reproduction.Proceedings,International Symposium on Ruminant Physiology,1995.
[27] Palliser C C,Woodward S L. Using models to predict methane reduction in pasture-fed dairy cows[J]. Citeseer,2002,482(1):162-167.
[28]谢天宇,王敏,王荣,等.奶牛胃肠道甲烷排放模型估算精度的评估分析[J].畜牧兽医学报,2015,46(9):1574-1583.
[29] Baldwin R L,France J,Gill M. Metabolism of the lactating cow.I.Animal elements of a mechanistic model[J]. Journal of Dairy Research,1987,54(1):77-105.
[30]王荣,杨玲媛,王敏,等.基于挥发性脂肪酸化学计量模型体外预测山羊瘤胃甲烷产量的精度[J].应用生态学报,2014,25(5):1518-1524.
[31] Czerkawski J W,Cheng K J.Compartmentation in the rumen[J].Rumen Microbial Ecosystem,1988,59(9):3046-3052.
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