Prediction of enteric methane production, yield, and intensity in dairy cattle using an intercontinental database

Mutian Niu; Ermias Kebreab; Alexander N. Hristov; Joonpyo Oh; Claudia Arndt; André Bannink; Ali R. Bayat; André F. Brito; Tommy Boland; David Casper; Les A. Crompton; Jan Dijkstra; Maguy A. Eugène; Phil C. Garnsworthy; Md Najmul Haque; Anne L.F. Hellwing; Pekka Huhtanen; Michael Kreuzer; Bjoern Kuhla; Peter Lund; Jørgen Madsen; Cécile Martin; Shelby C. McClelland; Mark McGee; Peter J. Moate; Stefan Muetzel; Camila Muñoz; Padraig O'Kiely; Nico Peiren; Christopher K. Reynolds; Angela Schwarm; Kevin J. Shingfield; Tonje M. Storlien; Martin R. Weisbjerg; David R. Yáñez-Ruiz; Zhongtang Yu

doi:10.1111/gcb.14094

Prediction of enteric methane production, yield, and intensity in dairy cattle using an intercontinental database

Mutian Niu, Ermias Kebreab, Alexander N. Hristov, Joonpyo Oh, Claudia Arndt, André Bannink, Ali R. Bayat, André F. Brito, Tommy Boland, David Casper, Les A. Crompton, Jan Dijkstra, Maguy A. Eugène, Phil C. Garnsworthy, Md Najmul Haque, Anne L.F. Hellwing, Pekka Huhtanen, Michael Kreuzer, Bjoern Kuhla, Peter LundJørgen Madsen, Cécile Martin, Shelby C. McClelland, Mark McGee, Peter J. Moate, Stefan Muetzel, Camila Muñoz, Padraig O'Kiely, Nico Peiren, Christopher K. Reynolds, Angela Schwarm, Kevin J. Shingfield, Tonje M. Storlien, Martin R. Weisbjerg, David R. Yáñez-Ruiz, Zhongtang Yu

Animal Science

Research output: Contribution to journal › Article › peer-review

133 Scopus citations

Abstract

Enteric methane (CH₄) production from cattle contributes to global greenhouse gas emissions. Measurement of enteric CH₄ is complex, expensive, and impractical at large scales; therefore, models are commonly used to predict CH₄ production. However, building robust prediction models requires extensive data from animals under different management systems worldwide. The objectives of this study were to (1) collate a global database of enteric CH₄ production from individual lactating dairy cattle; (2) determine the availability of key variables for predicting enteric CH₄ production (g/day per cow), yield [g/kg dry matter intake (DMI)], and intensity (g/kg energy corrected milk) and their respective relationships; (3) develop intercontinental and regional models and cross-validate their performance; and (4) assess the trade-off between availability of on-farm inputs and CH₄ prediction accuracy. The intercontinental database covered Europe (EU), the United States (US), and Australia (AU). A sequential approach was taken by incrementally adding key variables to develop models with increasing complexity. Methane emissions were predicted by fitting linear mixed models. Within model categories, an intercontinental model with the most available independent variables performed best with root mean square prediction error (RMSPE) as a percentage of mean observed value of 16.6%, 14.7%, and 19.8% for intercontinental, EU, and United States regions, respectively. Less complex models requiring only DMI had predictive ability comparable to complex models. Enteric CH₄ production, yield, and intensity prediction models developed on an intercontinental basis had similar performance across regions, however, intercepts and slopes were different with implications for prediction. Revised CH₄ emission conversion factors for specific regions are required to improve CH₄ production estimates in national inventories. In conclusion, information on DMI is required for good prediction, and other factors such as dietary neutral detergent fiber (NDF) concentration, improve the prediction. For enteric CH₄ yield and intensity prediction, information on milk yield and composition is required for better estimation.

Original language	English (US)
Pages (from-to)	3368-3389
Number of pages	22
Journal	Global Change Biology
Volume	24
Issue number	8
DOIs	https://doi.org/10.1111/gcb.14094
State	Published - Aug 2018

All Science Journal Classification (ASJC) codes

Global and Planetary Change
Environmental Chemistry
Ecology
Environmental Science(all)

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10.1111/gcb.14094

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Niu, M., Kebreab, E., Hristov, A. N., Oh, J., Arndt, C., Bannink, A., Bayat, A. R., Brito, A. F., Boland, T., Casper, D., Crompton, L. A., Dijkstra, J., Eugène, M. A., Garnsworthy, P. C., Haque, M. N., Hellwing, A. L. F., Huhtanen, P., Kreuzer, M., Kuhla, B., ... Yu, Z. (2018). Prediction of enteric methane production, yield, and intensity in dairy cattle using an intercontinental database. Global Change Biology, 24(8), 3368-3389. https://doi.org/10.1111/gcb.14094

@article{e1033b623bf1424ab59f1814c1ca5aba,

title = "Prediction of enteric methane production, yield, and intensity in dairy cattle using an intercontinental database",

abstract = "Enteric methane (CH4) production from cattle contributes to global greenhouse gas emissions. Measurement of enteric CH4 is complex, expensive, and impractical at large scales; therefore, models are commonly used to predict CH4 production. However, building robust prediction models requires extensive data from animals under different management systems worldwide. The objectives of this study were to (1) collate a global database of enteric CH4 production from individual lactating dairy cattle; (2) determine the availability of key variables for predicting enteric CH4 production (g/day per cow), yield [g/kg dry matter intake (DMI)], and intensity (g/kg energy corrected milk) and their respective relationships; (3) develop intercontinental and regional models and cross-validate their performance; and (4) assess the trade-off between availability of on-farm inputs and CH4 prediction accuracy. The intercontinental database covered Europe (EU), the United States (US), and Australia (AU). A sequential approach was taken by incrementally adding key variables to develop models with increasing complexity. Methane emissions were predicted by fitting linear mixed models. Within model categories, an intercontinental model with the most available independent variables performed best with root mean square prediction error (RMSPE) as a percentage of mean observed value of 16.6%, 14.7%, and 19.8% for intercontinental, EU, and United States regions, respectively. Less complex models requiring only DMI had predictive ability comparable to complex models. Enteric CH4 production, yield, and intensity prediction models developed on an intercontinental basis had similar performance across regions, however, intercepts and slopes were different with implications for prediction. Revised CH4 emission conversion factors for specific regions are required to improve CH4 production estimates in national inventories. In conclusion, information on DMI is required for good prediction, and other factors such as dietary neutral detergent fiber (NDF) concentration, improve the prediction. For enteric CH4 yield and intensity prediction, information on milk yield and composition is required for better estimation.",

author = "Mutian Niu and Ermias Kebreab and Hristov, {Alexander N.} and Joonpyo Oh and Claudia Arndt and Andr{\'e} Bannink and Bayat, {Ali R.} and Brito, {Andr{\'e} F.} and Tommy Boland and David Casper and Crompton, {Les A.} and Jan Dijkstra and Eug{\`e}ne, {Maguy A.} and Garnsworthy, {Phil C.} and Haque, {Md Najmul} and Hellwing, {Anne L.F.} and Pekka Huhtanen and Michael Kreuzer and Bjoern Kuhla and Peter Lund and J{\o}rgen Madsen and C{\'e}cile Martin and McClelland, {Shelby C.} and Mark McGee and Moate, {Peter J.} and Stefan Muetzel and Camila Mu{\~n}oz and Padraig O'Kiely and Nico Peiren and Reynolds, {Christopher K.} and Angela Schwarm and Shingfield, {Kevin J.} and Storlien, {Tonje M.} and Weisbjerg, {Martin R.} and Y{\'a}{\~n}ez-Ruiz, {David R.} and Zhongtang Yu",

note = "Funding Information: FONDECYT, Grant/Award Number: 11110410, 1151355; Fontagro, Grant/ Award Number: FTG/RF-1028-RG; The Netherlands Ministry of Economic Affairs, Grant/Award Number: BO-20-007-006; Austin Eugene Lyons Fellowship; Academy of Finland, Grant/Award Number: 281337; USDA National Institute of Food and Agriculture, Grant/Award Number: 2014-67003-21979, NH00616-R; Department of Animal Science and College of Agricultural Sciences, Pennsylvania State University; the Dutch Dairy Board (Zoetermeer, The Netherlands); University of California, Davis Sesnon Endowed Chair Program; Pennsylvania Soybean Board; Agricultural GHG Research Initiative for Ireland; Northeast Sustainable Agriculture Research and Education; Swedish Infrastructure for Ecosystem Science (SITES) at Ro€backsdalen Research Station; Department for Environment, Food and Rural Affairs (Defra; UK); Defra, the Scottish Government, Department of Agriculture and Rural Development (Northern Ireland), and the Welsh Government as part of the UK{\textquoteright}s Agricultural GHG Research Platform projects; Swiss Federal Office of Agriculture, Berne, Switzerland; French National Research Agency, Grant/Award Number: ANR-13-JFAC-0003-01; New Hampshire Agricultural Experiment Station; the Product Board Animal Feed (Zoetermeer, The Netherlands); PMI Nutritional Additives; DSM Nutritional Products; German Federal Ministry of Food and Agriculture (BMBL) through the Federal Office for Agriculture and Food (BLE); European Commission through SMEthane, Grant/Award Number: FP7-SME-262270; INIA, Spain, Grant/Award Number: MIT01-GLOBALNET-EEZ Funding Information: This study is part of the Joint Programming Initiative on Agriculture, Food Security and Climate Change (FACCE-JPI)'s ?GLOBAL NETWORK? project and the ?Feeding and Nutrition Network? (http://animalscience.psu.edu/fnn) of the Livestock Research Group within the Global Research Alliance for Agricultural Greenhouse Gases (www.globalresearchalliance.org). Authors gratefully acknowledge funding for this project from: USDA National Institute of Food and Agriculture Grant no. 2014-67003-21979) University of California, Davis Sesnon Endowed Chair Program, USDA, and Austin Eugene Lyons Fellowship (University of California, Davis); Funding from USDA National Institute of Food and Agriculture Federal Appropriations under Project PEN 04539 and Accession number 1000803, DSM Nutritional Products (Basel, Switzerland), Pennsylvania Soybean Board (Harrisburg, PA, USA), Northeast Sustainable Agriculture Research and Education (Burlington, VT, USA), and PMI Nutritional Additives (Shoreview, MN, USA); the Ministry of Economic Affairs (the Netherlands; project BO-20-007-006; Global Research Alliance on Agricultural Greenhouse Gases), the Product Board Animal Feed (Zoetermeer, the Netherlands) and the Dutch Dairy Board (Zoetermeer, the Netherlands); USDA National Institute of Food and Agriculture (Hatch Multistate NC-1042 Project Number NH00616-R; Project Accession Number 1001855) and the New Hampshire Agricultural Experiment Station (Durham, NH); French National Research Agency through the FACCE-JPI program (ANR-13-JFAC-0003-01), Agricultural GHG Research Initiative for Ireland (AGRI-I), Academy of Finland (No. 281337), Helsinki, Finland; Swiss Federal Office of Agriculture, Berne, Switzerland; the Department for Environment, Food and Rural Affairs (Defra; UK); Defra, the Scottish Government, DARD, and the Welsh Government as part of the UK's Agricultural GHG Research Platform projects (www.ghgplatform.org.uk); INIA (Spain, project MIT01-GLOBALNET-EEZ); German Federal Ministry of Food and Agriculture (BMBL) through the Federal Office for Agriculture and Food (BLE); Swedish Infrastructure for Ecosystem Science (SITES) at R?b?cksdalen Research Station; Comisi?n Nacional de Investigaci?n Cient?fica y Tecnol?gica, Fondo Nacional de Desarrollo Cient?fico y Tecnol?gico (Grant Nos. 11110410 and 1151355) and Fondo Regional de Tecnolog?a Agropecuaria (FTG/RF-1028-RG); European Commission through SMEthane (FP7-SME-262270). The authors are thankful to all colleagues who contributed data to the GLOBAL NETWORK project and especially thank Luis Moraes, Ranga Appuhamy, Henk van Lingen, James Fadel, and Roberto Sainz for their support on data analysis. All authors read and approved the final manuscript. The authors declare that they have no competing interests. Funding Information: NETWORK” project and the “Feeding and Nutrition Network” (http:// animalscience.psu.edu/fnn) of the Livestock Research Group within the Global Research Alliance for Agricultural Greenhouse Gases (www.globalresearchalliance.org). Authors gratefully acknowledge funding for this project from: USDA National Institute of Food and Agriculture Grant no. 2014-67003-21979) University of California, Davis Sesnon Endowed Chair Program, USDA, and Austin Eugene Lyons Fellowship (University of California, Davis); Funding from USDA National Institute of Food and Agriculture Federal Appropriations under Project PEN 04539 and Accession number 1000803, DSM Nutritional Products (Basel, Switzerland), Pennsylvania Soybean Board (Harrisburg, PA, USA), Northeast Sustainable Agriculture Research and Education (Burlington, VT, USA), and PMI Nutritional Additives (Shoreview, MN, USA); the Ministry of Economic Affairs (the Netherlands; project BO-20-007-006; Global Research Alliance on Agricultural Greenhouse Gases), the Product Board Animal Feed (Zoetermeer, the Netherlands) and the Dutch Dairy Board (Zoeter-meer, the Netherlands); USDA National Institute of Food and Agriculture (Hatch Multistate NC-1042 Project Number NH00616-R; Project Accession Number 1001855) and the New Hampshire Agricultural Experiment Station (Durham, NH); French National Research Agency through the FACCE-JPI program (ANR-13-JFAC-0003-01), Agricultural GHG Research Initiative for Ireland (AGRI-I), Academy of Finland (No. 281337), Helsinki, Finland; Swiss Federal Office of Agriculture, Berne, Switzerland; the Department for Environment, Food and Rural Affairs (Defra; UK); Defra, the Scottish Government, DARD, and the Welsh Government as part of the UK{\textquoteright}s Agricultural GHG Research Platform projects (www.ghgplatform.org.uk); INIA (Spain, project MIT01-GLOBALNET-EEZ); German Federal Ministry of Food and Agriculture (BMBL) through the Federal Office for Agriculture and Food (BLE); Swedish Infrastructure for Ecosystem Science (SITES) at Ro€b€acksdalen Research Station; Comision Nacional de Investigacion Cientıfica y Tecnologica, Fondo Nacional de Desarrollo Cientıfico y Tecnologico (Grant Nos. 11110410 and 1151355) and Fondo Regional de Tecnolog{\'i}a Agropecuaria (FTG/RF-1028-RG); European Commission through SMEthane (FP7-SME-262270). The authors are thankful to all colleagues who contributed data to the GLOBAL NETWORK project and especially thank Luis Moraes, Ranga Appuhamy, Henk van Lingen, James Fadel, and Roberto Sainz for their support on data analysis. All authors read and approved the final manuscript. The authors declare that they have no competing interests. Publisher Copyright: {\textcopyright} 2018 John Wiley & Sons Ltd",

year = "2018",

month = aug,

doi = "10.1111/gcb.14094",

language = "English (US)",

volume = "24",

pages = "3368--3389",

journal = "Global Change Biology",

issn = "1354-1013",

publisher = "Wiley-Blackwell",

number = "8",

}

Niu, M, Kebreab, E, Hristov, AN, Oh, J, Arndt, C, Bannink, A, Bayat, AR, Brito, AF, Boland, T, Casper, D, Crompton, LA, Dijkstra, J, Eugène, MA, Garnsworthy, PC, Haque, MN, Hellwing, ALF, Huhtanen, P, Kreuzer, M, Kuhla, B, Lund, P, Madsen, J, Martin, C, McClelland, SC, McGee, M, Moate, PJ, Muetzel, S, Muñoz, C, O'Kiely, P, Peiren, N, Reynolds, CK, Schwarm, A, Shingfield, KJ, Storlien, TM, Weisbjerg, MR, Yáñez-Ruiz, DR & Yu, Z 2018, 'Prediction of enteric methane production, yield, and intensity in dairy cattle using an intercontinental database', Global Change Biology, vol. 24, no. 8, pp. 3368-3389. https://doi.org/10.1111/gcb.14094

TY - JOUR

T1 - Prediction of enteric methane production, yield, and intensity in dairy cattle using an intercontinental database

AU - Niu, Mutian

AU - Kebreab, Ermias

AU - Hristov, Alexander N.

AU - Oh, Joonpyo

AU - Arndt, Claudia

AU - Bannink, André

AU - Bayat, Ali R.

AU - Brito, André F.

AU - Boland, Tommy

AU - Casper, David

AU - Crompton, Les A.

AU - Dijkstra, Jan

AU - Eugène, Maguy A.

AU - Garnsworthy, Phil C.

AU - Haque, Md Najmul

AU - Hellwing, Anne L.F.

AU - Huhtanen, Pekka

AU - Kreuzer, Michael

AU - Kuhla, Bjoern

AU - Lund, Peter

AU - Madsen, Jørgen

AU - Martin, Cécile

AU - McClelland, Shelby C.

AU - McGee, Mark

AU - Moate, Peter J.

AU - Muetzel, Stefan

AU - Muñoz, Camila

AU - O'Kiely, Padraig

AU - Peiren, Nico

AU - Reynolds, Christopher K.

AU - Schwarm, Angela

AU - Shingfield, Kevin J.

AU - Storlien, Tonje M.

AU - Weisbjerg, Martin R.

AU - Yáñez-Ruiz, David R.

AU - Yu, Zhongtang

N1 - Funding Information: FONDECYT, Grant/Award Number: 11110410, 1151355; Fontagro, Grant/ Award Number: FTG/RF-1028-RG; The Netherlands Ministry of Economic Affairs, Grant/Award Number: BO-20-007-006; Austin Eugene Lyons Fellowship; Academy of Finland, Grant/Award Number: 281337; USDA National Institute of Food and Agriculture, Grant/Award Number: 2014-67003-21979, NH00616-R; Department of Animal Science and College of Agricultural Sciences, Pennsylvania State University; the Dutch Dairy Board (Zoetermeer, The Netherlands); University of California, Davis Sesnon Endowed Chair Program; Pennsylvania Soybean Board; Agricultural GHG Research Initiative for Ireland; Northeast Sustainable Agriculture Research and Education; Swedish Infrastructure for Ecosystem Science (SITES) at Ro€backsdalen Research Station; Department for Environment, Food and Rural Affairs (Defra; UK); Defra, the Scottish Government, Department of Agriculture and Rural Development (Northern Ireland), and the Welsh Government as part of the UK’s Agricultural GHG Research Platform projects; Swiss Federal Office of Agriculture, Berne, Switzerland; French National Research Agency, Grant/Award Number: ANR-13-JFAC-0003-01; New Hampshire Agricultural Experiment Station; the Product Board Animal Feed (Zoetermeer, The Netherlands); PMI Nutritional Additives; DSM Nutritional Products; German Federal Ministry of Food and Agriculture (BMBL) through the Federal Office for Agriculture and Food (BLE); European Commission through SMEthane, Grant/Award Number: FP7-SME-262270; INIA, Spain, Grant/Award Number: MIT01-GLOBALNET-EEZ Funding Information: This study is part of the Joint Programming Initiative on Agriculture, Food Security and Climate Change (FACCE-JPI)'s ?GLOBAL NETWORK? project and the ?Feeding and Nutrition Network? (http://animalscience.psu.edu/fnn) of the Livestock Research Group within the Global Research Alliance for Agricultural Greenhouse Gases (www.globalresearchalliance.org). Authors gratefully acknowledge funding for this project from: USDA National Institute of Food and Agriculture Grant no. 2014-67003-21979) University of California, Davis Sesnon Endowed Chair Program, USDA, and Austin Eugene Lyons Fellowship (University of California, Davis); Funding from USDA National Institute of Food and Agriculture Federal Appropriations under Project PEN 04539 and Accession number 1000803, DSM Nutritional Products (Basel, Switzerland), Pennsylvania Soybean Board (Harrisburg, PA, USA), Northeast Sustainable Agriculture Research and Education (Burlington, VT, USA), and PMI Nutritional Additives (Shoreview, MN, USA); the Ministry of Economic Affairs (the Netherlands; project BO-20-007-006; Global Research Alliance on Agricultural Greenhouse Gases), the Product Board Animal Feed (Zoetermeer, the Netherlands) and the Dutch Dairy Board (Zoetermeer, the Netherlands); USDA National Institute of Food and Agriculture (Hatch Multistate NC-1042 Project Number NH00616-R; Project Accession Number 1001855) and the New Hampshire Agricultural Experiment Station (Durham, NH); French National Research Agency through the FACCE-JPI program (ANR-13-JFAC-0003-01), Agricultural GHG Research Initiative for Ireland (AGRI-I), Academy of Finland (No. 281337), Helsinki, Finland; Swiss Federal Office of Agriculture, Berne, Switzerland; the Department for Environment, Food and Rural Affairs (Defra; UK); Defra, the Scottish Government, DARD, and the Welsh Government as part of the UK's Agricultural GHG Research Platform projects (www.ghgplatform.org.uk); INIA (Spain, project MIT01-GLOBALNET-EEZ); German Federal Ministry of Food and Agriculture (BMBL) through the Federal Office for Agriculture and Food (BLE); Swedish Infrastructure for Ecosystem Science (SITES) at R?b?cksdalen Research Station; Comisi?n Nacional de Investigaci?n Cient?fica y Tecnol?gica, Fondo Nacional de Desarrollo Cient?fico y Tecnol?gico (Grant Nos. 11110410 and 1151355) and Fondo Regional de Tecnolog?a Agropecuaria (FTG/RF-1028-RG); European Commission through SMEthane (FP7-SME-262270). The authors are thankful to all colleagues who contributed data to the GLOBAL NETWORK project and especially thank Luis Moraes, Ranga Appuhamy, Henk van Lingen, James Fadel, and Roberto Sainz for their support on data analysis. All authors read and approved the final manuscript. The authors declare that they have no competing interests. Funding Information: NETWORK” project and the “Feeding and Nutrition Network” (http:// animalscience.psu.edu/fnn) of the Livestock Research Group within the Global Research Alliance for Agricultural Greenhouse Gases (www.globalresearchalliance.org). Authors gratefully acknowledge funding for this project from: USDA National Institute of Food and Agriculture Grant no. 2014-67003-21979) University of California, Davis Sesnon Endowed Chair Program, USDA, and Austin Eugene Lyons Fellowship (University of California, Davis); Funding from USDA National Institute of Food and Agriculture Federal Appropriations under Project PEN 04539 and Accession number 1000803, DSM Nutritional Products (Basel, Switzerland), Pennsylvania Soybean Board (Harrisburg, PA, USA), Northeast Sustainable Agriculture Research and Education (Burlington, VT, USA), and PMI Nutritional Additives (Shoreview, MN, USA); the Ministry of Economic Affairs (the Netherlands; project BO-20-007-006; Global Research Alliance on Agricultural Greenhouse Gases), the Product Board Animal Feed (Zoetermeer, the Netherlands) and the Dutch Dairy Board (Zoeter-meer, the Netherlands); USDA National Institute of Food and Agriculture (Hatch Multistate NC-1042 Project Number NH00616-R; Project Accession Number 1001855) and the New Hampshire Agricultural Experiment Station (Durham, NH); French National Research Agency through the FACCE-JPI program (ANR-13-JFAC-0003-01), Agricultural GHG Research Initiative for Ireland (AGRI-I), Academy of Finland (No. 281337), Helsinki, Finland; Swiss Federal Office of Agriculture, Berne, Switzerland; the Department for Environment, Food and Rural Affairs (Defra; UK); Defra, the Scottish Government, DARD, and the Welsh Government as part of the UK’s Agricultural GHG Research Platform projects (www.ghgplatform.org.uk); INIA (Spain, project MIT01-GLOBALNET-EEZ); German Federal Ministry of Food and Agriculture (BMBL) through the Federal Office for Agriculture and Food (BLE); Swedish Infrastructure for Ecosystem Science (SITES) at Ro€b€acksdalen Research Station; Comision Nacional de Investigacion Cientıfica y Tecnologica, Fondo Nacional de Desarrollo Cientıfico y Tecnologico (Grant Nos. 11110410 and 1151355) and Fondo Regional de Tecnología Agropecuaria (FTG/RF-1028-RG); European Commission through SMEthane (FP7-SME-262270). The authors are thankful to all colleagues who contributed data to the GLOBAL NETWORK project and especially thank Luis Moraes, Ranga Appuhamy, Henk van Lingen, James Fadel, and Roberto Sainz for their support on data analysis. All authors read and approved the final manuscript. The authors declare that they have no competing interests. Publisher Copyright: © 2018 John Wiley & Sons Ltd

PY - 2018/8

Y1 - 2018/8

N2 - Enteric methane (CH4) production from cattle contributes to global greenhouse gas emissions. Measurement of enteric CH4 is complex, expensive, and impractical at large scales; therefore, models are commonly used to predict CH4 production. However, building robust prediction models requires extensive data from animals under different management systems worldwide. The objectives of this study were to (1) collate a global database of enteric CH4 production from individual lactating dairy cattle; (2) determine the availability of key variables for predicting enteric CH4 production (g/day per cow), yield [g/kg dry matter intake (DMI)], and intensity (g/kg energy corrected milk) and their respective relationships; (3) develop intercontinental and regional models and cross-validate their performance; and (4) assess the trade-off between availability of on-farm inputs and CH4 prediction accuracy. The intercontinental database covered Europe (EU), the United States (US), and Australia (AU). A sequential approach was taken by incrementally adding key variables to develop models with increasing complexity. Methane emissions were predicted by fitting linear mixed models. Within model categories, an intercontinental model with the most available independent variables performed best with root mean square prediction error (RMSPE) as a percentage of mean observed value of 16.6%, 14.7%, and 19.8% for intercontinental, EU, and United States regions, respectively. Less complex models requiring only DMI had predictive ability comparable to complex models. Enteric CH4 production, yield, and intensity prediction models developed on an intercontinental basis had similar performance across regions, however, intercepts and slopes were different with implications for prediction. Revised CH4 emission conversion factors for specific regions are required to improve CH4 production estimates in national inventories. In conclusion, information on DMI is required for good prediction, and other factors such as dietary neutral detergent fiber (NDF) concentration, improve the prediction. For enteric CH4 yield and intensity prediction, information on milk yield and composition is required for better estimation.

AB - Enteric methane (CH4) production from cattle contributes to global greenhouse gas emissions. Measurement of enteric CH4 is complex, expensive, and impractical at large scales; therefore, models are commonly used to predict CH4 production. However, building robust prediction models requires extensive data from animals under different management systems worldwide. The objectives of this study were to (1) collate a global database of enteric CH4 production from individual lactating dairy cattle; (2) determine the availability of key variables for predicting enteric CH4 production (g/day per cow), yield [g/kg dry matter intake (DMI)], and intensity (g/kg energy corrected milk) and their respective relationships; (3) develop intercontinental and regional models and cross-validate their performance; and (4) assess the trade-off between availability of on-farm inputs and CH4 prediction accuracy. The intercontinental database covered Europe (EU), the United States (US), and Australia (AU). A sequential approach was taken by incrementally adding key variables to develop models with increasing complexity. Methane emissions were predicted by fitting linear mixed models. Within model categories, an intercontinental model with the most available independent variables performed best with root mean square prediction error (RMSPE) as a percentage of mean observed value of 16.6%, 14.7%, and 19.8% for intercontinental, EU, and United States regions, respectively. Less complex models requiring only DMI had predictive ability comparable to complex models. Enteric CH4 production, yield, and intensity prediction models developed on an intercontinental basis had similar performance across regions, however, intercepts and slopes were different with implications for prediction. Revised CH4 emission conversion factors for specific regions are required to improve CH4 production estimates in national inventories. In conclusion, information on DMI is required for good prediction, and other factors such as dietary neutral detergent fiber (NDF) concentration, improve the prediction. For enteric CH4 yield and intensity prediction, information on milk yield and composition is required for better estimation.

UR - http://www.scopus.com/inward/record.url?scp=85043383290&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85043383290&partnerID=8YFLogxK

U2 - 10.1111/gcb.14094

DO - 10.1111/gcb.14094

M3 - Article

C2 - 29450980

AN - SCOPUS:85043383290

SN - 1354-1013

VL - 24

SP - 3368

EP - 3389

JO - Global Change Biology

JF - Global Change Biology

IS - 8

ER -

Prediction of enteric methane production, yield, and intensity in dairy cattle using an intercontinental database

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