Development and evaluation of prediction equations for methane emission from Nellore cattle

Pires Sobrinho, Tatiana Lucila; Branco, Renata Helena; Magnani, Elaine; Berndt, Alexandre; Canesin, Roberta Carrilho; Mercadante, Maria Eugênia Zerlotti

doi:10.4025/actascianimsci.v41i1.42559

ABSTRACT.

Dry matter intake (DMI), nutrient intake and enteric CH₄ emission were evaluated in 48 Nellore cattle (392 ± 27 days of age). Equations were generated from intake data and evaluated using root mean square prediction error (RMSPE), and validated by cross-validation. Equations that included DMI and hemicellulose intake (HEMI) [ $C H_{4} (M J d^{- 1}) = 4.08 (\pm 1.65) + 11.6 (\pm 2.34) D M I (k g d^{- 1}) - 33.4 (\pm 7.21) H E M I (k g d^{- 1})]$ ; DMI and total carbohydrate intake (TCHI) $[C H_{4} (M J d^{- 1}) = 5.26 (\pm 1.69) - 6.3 (\pm 1.47) D M I (k g d^{- 1}) + 8.8 (\pm 1.81) T C I (k g d^{- 1})]$ ; metabolizable energy intake (MEI) and cellulose intake (CELI) $[C H_{4} (M J d^{- 1}) = 5.16 (\pm 1.72) - 0.13 (\pm 0.048) M E I (M J d^{- 1}) + 7.37 (\pm 1.53) C E L I (k g d^{- 1})]$ , and non-fiber carbohydrate intake (NFCI) $[C H_{4} (M J d^{- 1}) = 3.14 (\pm 1.48) + 3.65 (\pm 1.05) N F C I (k g d^{- 1})]$ resulted in the lowest RMSPE (14.3, 14.1, 14.3 and 14.7%, respectively). When literature equations were evaluated using our database, the most accurate predictions were obtained with equations that included DMI and lignin intake (RMSPE = 15.27%) and MEI, acid detergent fiber intake and lignin intake (RMSPE = 15.7%). The mean error of predicting enteric CH₄ emission with the equations developed in this study based on DMI and nutrient intake is 17% and the most accurate predictions are obtained with equations including DMI, carbohydrate intake and MEI.

Keywords:
beef cattle; dry matter intake; greenhouse gas; prediction; sulfur hexafluoride

Introduction

Livestock farming is an important source of greenhouse gases worldwide, generating carbon dioxide (CO₂), methane (CH₄) and nitrous oxide (N₂O) throughout the production process, which contribute significantly to global warming (Monteiro et al., 2018Monteiro, A. L. G., Faro, A. M. C. d. F., Peres, M. T. P., Batista, R., Poli, C. H. E. C., & Villalba, J. J. (2018). The role of small ruminants on global climate change. Acta Scientiarum. Animal Sciences, 40(e43124), 1-11. doi: http://dx.doi.org/10.4025/actascianimsci.v40i1.43124.
https://doi.org/http://dx.doi.org/10.402... ). Global greenhouse gas emissions from livestock have increased by 51% from 1960 to 2001, mainly because of the increasing emissions from herds in developing countries (+ 117%). In this respect, cattle are responsible for 74% of global emissions in this sector (Caro, Davis, Bastianoni, & Caldeira, 2014Caro, D., Davis, S. J., Bastianoni, S., & Caldeira, K. (2014). Global and regional trends in greenhouse gas emissions from livestock. Climatic Change, 126(1-2), 203-216. doi: 10.1007/s10584-014-1197-x.
https://doi.org/10.1007/s10584-014-1197-... ). Methane emissions from enteric fermentation account for 25.9% of all CH₄ emissions resulting from anthropogenic activities (United States Environmental Protection Agency [USEPA], 2015United States Environmental Protection Agency [USEPA]. (2015). Inventory of U.S. Greenhouse Gas Emissions and Sinks: 1990 - 2013. Washington, DC.). Eructed methane is responsible for 2 to 12% of ingested gross energy loss depending on the level of feeding, diet composition and other factors (Johnson & Johnson, 1995Johnson, K. A., & Johnson, D. E. (1995). Methane emissions from cattle. Journal of Animal Science , 73(8), 2483-2492. doi: 10.2527/1995.7382483x.
https://doi.org/10.2527/1995.7382483x.... ), as different breeds (Grobler, Scholtz, van Rooyan, Mpayipheli, & Neser, 2014Grobler, S. M., Scholtz, M. M., van Rooyan, H., Mpayipheli, M., & Neser, F. W. C. (2014). Methane production in different breeds, grazing different pastures or fed a total mixed ration, as measured by a Laser Methane Detector. South AfricanJournal of Animal Science , 44(5), 12-16. doi: 10.4314/sajas.v44i5.3.
https://doi.org/10.4314/sajas.v44i5.3.... ).

Greenhouse gas emission inventories generally use mathematical models to predict enteric methane emission from cattle. These models can be applied directly, relating nutrient intake to methane emission, or by estimating emissions from mathematical descriptions of the biochemistry of rumen fermentation (Kebreab, Clark, Wagner-Riddle, & France, 2006Kebreab, E., Clark, K., Wagner-Riddle, C., & France, J. (2006). Methane and nitrous oxide emissions from Canadian animal agriculture: A review. Canadian Journal of Animal Science , 86(2), 135-157. doi: 10.4141/A05-010.
https://doi.org/10.4141/A05-010.... ). Methane prediction equations are available in the literature and have been developed, among others, for simultaneous analysis in cattle and sheep (Blaxter & Clapperton, 1965Blaxter, K. L., & Clapperton, J. L. (1965). Prediction of the amount of methane produced by ruminants. British Journal of Nutrition, 19(1), 511-522. doi: 10.1079/BJN19650046.
https://doi.org/10.1079/BJN19650046.... ), dairy cows (Mills et al., 2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x.
https://doi.org/10.2527/2003.81123141x.... ), beef cattle (Ellis et al., 2009Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725.
https://doi.org/10.2527/jas.2007-0725.... ), and beef and dairy cattle in separate and combined analysis (Ellis et al., 2007; Patra, 2017Patra, A. K. (2017). Prediction of enteric methane emission from cattle using linear and non-linear statistical models in tropical production systems. Mitigation and adaptation strategies for global change, 22(4), 629-650. doi: 10.1007/s11027-015-9691-7.
https://doi.org/10.1007/s11027-015-9691-... ). These studies were developed by meta-analysis, including published results of enteric methane emission of animals from different breeds, categories, and fed different diets.

The use of different diet-related variables in prediction equations affects the accuracy of CH₄ prediction (Ellis et al., 2009Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725.
https://doi.org/10.2527/jas.2007-0725.... ; Ellis et al., 2007). It would therefore be useful to screen for dietary variables that are easily obtained in the field and are closely correlated with enteric CH₄ emission to model and predict CH₄ production in ruminants.

The objective of the present study was to develop prediction equations for enteric methane emission from Nellore cattle raised in a tropical climate, and to evaluate the accuracy of equations described in the literature under the conditions studied.

Material and methods

The experiment was approved by Animal Ethics Committee, in accordance with Guidelines of Animal Welfare and Humane Slaughter (São Paulo State law number 11.977). The experiment was conducted in Sertãozinho, Brazil (21º10’ South latitude and 48º5’ West longitude); a region characterized by humid tropical climate with an average annual temperature of 24ºC and average annual rainfall of 1,312 mm.

Dry matter intake (DMI) and enteric methane emission were evaluated for 5 consecutive days in 24 male and 24 female Nellore animals (332 ± 35 kg initial body weight and 392 ± 27 days of age) housed in individual pens (12 m²). Daily intake was calculated as the difference between the feed provided and leftovers. Although intake was only calculated during the measurement of methane emission (5 days), the simple correlation between the latter and DMI obtained in an 84-day feed efficiency test (Mercadante et al., 2015Mercadante, M. E. Z., Caliman, A. P. d. M., Canesin, R. C., Bonilha, S. F. M., Berndt, A., Frighetto, R. T. S., ... Branco, R. H. (2015). Relationship between residual feed intake and enteric methane emission in Nellore cattle. Revista Brasileira de Zootecnia , 44(7), 255-262. doi: 10.1590/S1806-92902015000700004.
https://doi.org/10.1590/S1806-9290201500... ) was high (0.842; p < 0.01).

The diet fed to the animals consisted of Brachiaria brizantha cv. Marandu hay (445 g kg^-1 of dry matter, DM), ground corn (322 g kg^-1 of DM), cottonseed meal (214 g kg^-1 of DM), urea (4.5 g kg^-1 of DM), ammonium sulfate (0.5 g kg^-1 of DM) and mineral supplement (19.5 g kg^-1 of DM), with a roughage:concentrate ratio of 45:55. The diet was provided twice a day (8 am and 4 pm) and was adjusted individually to permit leftovers of 5 to 10%, ensuring ad libitum intake. Individual leftover samples were collected over the 5 days of methane emission measurement and the ingredients of the diet were sampled on the first day and stored for subsequent chemical analysis (Table 1).

The diet and leftover samples were dried for 72h at 55°C and ground in a knife mill with a 1-mm sieve. Association Official Analytical Chemists (AOAC, 1990Association Official Analytical Chemists [AOAC]. (1990). Official Methods of Analysis (15th ed.). Arlington, VA: AOAC International.) methods were used for the determination of DM (Method 934.01), ash (Method 942.05), and ether extract (Method 920.39) content. Crude protein content was determined from the nitrogen value obtained by the Dumas combustion method in a Leco^® FP-528 nitrogen analyzer (St. Joseph, MI, USA) and multiplied by 6.25 (Etheridge, Pesti, & Foster, 1998Etheridge, R. D., Pesti, G. M., & Foster, E. H. (1998). A comparison of nitrogen values obtained utilizing the Kjeldahl nitrogen and Dumas combustion methodologies (Leco CNS 2000) on samples typical of an animal nutrition analytical laboratory. Animal Feed Science and Technology, 73(1-2), 21-28. doi: 10.1016/S0377-8401(98)00136-9.
https://doi.org/10.1016/S0377-8401(98)00... ). Gross energy was obtained by combustion of the samples in an adiabatic calorimeter (model 6300, Parr Instrument Company, Moline, IL, USA). Neutral detergent fiber was obtained using α-amylase without the addition of sodium sulfite, according to Van Soest, Robertson, and Lewis (1991Van Soest, P. J., Robertson, J. B., & Lewis, B. A. (1991). Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science , 74(10), 3583-3597. doi: 10.3168/jds.S0022-0302(91)78551-2.
https://doi.org/10.3168/jds.S0022-0302(9... ) and adapted for the Ankom 200 Fiber Analyzer (Ankom Technology, Fairport, NY, USA), and was subsequently corrected for ash and protein. Acid detergent fiber was determined using the method of Goering and Van Soest (1970Goering, H. K., & Van Soest, P. J. (1970). Forage Fiber Analysis. USDA Agricultural Research Service. Handbook number 379 (16th ed). Washington, DC: US Government Printing Office.), adapted for the Ankom 200 Fiber Analyzer (Ankom Technology). Lignin was determined by solubilization of cellulose in sulfuric acid according to Van Soest et al. (1991). Total digestible nutrients (TDN=DCP+2.25DFA+DND F P +DNFC−7), digestible energy [DE=(DCP/100)5.6+(DFA/100)9.4+(DNFC/100)4.2+(DNDF/100)4.2−0.3] and metabolizable energy (ME=DE0.82) were calculated according to the National Research Council (NRC, 2001National Research Council [NRC]. (2001). Nutrient Requirements of Dairy Cattle (7th rev. ed.). Washington, DC: National Academy Press.), in which: DCP = digestible crude protein, DFA = digestible fatty acids, DNDF = digestible neutral detergent fiber, DNDF_P = digestible neutral detergent fiber free of digestible proteins, and DNFC = digestible nonfiber carbohydrates. Non-fiber carbohydrates were determined as percentage using the following equation: 100 - (% crude protein + % ether extract + % mineral matter +% neutral detergent fiber corrected for ash and protein) according to Sniffen, O'Connor, Van Soest, Fox, and Russell (1992Sniffen, C. J., O'Connor, J. D., Van Soest, P. J., Fox, D. G., & Russell, J. B. (1992). A net carbohydrate and protein system for evaluating cattle diets: II. Carbohydrate and protein availability. Journal of Animal Science , 70(11), 3562-3577. doi: 10.2527/1992.70113562x.
https://doi.org/10.2527/1992.70113562x.... ). Total carbohydrates were calculated as percentage: 100 - (% crude protein + % ether extract + % mineral matter).

Measurement of enteric methane

The sulfur hexafluoride (SF₆) tracer gas technique described by Johnson and Johnson (1995Johnson, K. A., & Johnson, D. E. (1995). Methane emissions from cattle. Journal of Animal Science , 73(8), 2483-2492. doi: 10.2527/1995.7382483x.
https://doi.org/10.2527/1995.7382483x.... ) was used for the quantification of daily enteric methane emission. For this purpose, an SF₆ source (permeation tube) with a known constant release rate was inserted through the mouth into the animal’s rumen. For determination of the SF₆ release rate, the tubes were kept in a beaker immersed in a water bath at 39ºC for 6 weeks prior to the experiment and were weighed weekly. After this period, the tubes were administered orally to each animal (n = 48) in a random manner, one week before the beginning of the experiment. The expired and eructed gases were sampled in 60-mm polyvinyl chloride collection canisters (class 20) through a stainless-steel capillary tube (inner diameter of 0.127 mm) attached to the halter of the animals. The collection canisters were evacuated at 0.1 atm in order to be filled with the gases captured at 0.5 atm over a period of 24h. The animals were allowed to adapt to the sampling devices (canisters and halters) for 15 days. Methane was collected during 5 consecutive days at intervals of 24h. For correction of atmospheric methane concentrations inside the facility, gas samples were collected daily from ambient air with two collection canisters (blank), hanging at the entrance and exit of the barn.

Methane was determined in an HP6890 gas chromatograph (Hewlett Packard, Model HP 6890, Ramsey, MN, USA) equipped with a flame ionization detector (FID) and Plot HP-Al/M megabore column (0.53 μm, 30 m) for CH₄, and with an electron capture detector (μ-ECD) and HP-MolSiv megabore column for SF6, using two 0.5-cm3 loops coupled to two 6-way valves, as the method described by Johnson, Huyler, Westberg, Lamb, and Zimmerman (1994Johnson, K., Huyler, M., Westberg, H., Lamb, B., & Zimmerman, P. (1994). Measurement of methane emissions from ruminant livestock using a sulfur hexafluoride tracer technique. Environmental science & technology, 28(2), 359-362. doi: 10.1021/es00051a025.
https://doi.org/10.1021/es00051a025.... ). The canisters were pressurized with nitrogen 5.0 (White Martins, Praxair Inc) until reaching a pressure of approximately 1.2 atm. Pressure readings were obtained with a digital pressure meter. The calibration curves were constructed, using gas standards certified by White Martins (Praxair Inc), as described by Westberg, Johnson, Cossalman, and Michal (1998Westberg, H. H., Johnson, K. A., Cossalman, M. W., & Michal, J. J. (1998). A SF6 tracer technique: methane measurement from ruminants. Pullman, WA: Washington State University.). The methane emitted by the animal was calculated from the release rate of SF₆, correlating the results with the known release rate of the tracer in the rumen and subtracting basal methane concentrations (Westberg et al., 1998):

Q_{{C H}_{4}} = \frac{{{Q_{{S F}_{6}} ([{C H}_{4}]}_{Y} - [C H_{4}]}_{B})}{[S F_{6}]},

in which: Q_CH4 = rate of methane emission by the animal; Q_SF6 = known release rate of SF_6; [CH₄]_Y= methane concentration in the canister; [CH₄]_B= methane concentration in the blank, and [SF₆] = SF₆ concentration in the canister. Methane expressed as gram was converted to unit of energy using the conversion factor proposed by Holter and Young (1992Holter, J. B., & Young, A. J. (1992). Nutrition, feeding and calves: methane prediction in dry and lactating Holstein cows. Journal of Dairy Science , 75(2165-2175). doi: 10.3168/jds.S0022-0302(92)77976-4.
https://doi.org/10.3168/jds.S0022-0302(9... ).

Evaluation of the equations developed

A completely randomized design was used. Simple correlations between the intake variables and CH₄ emission (MJ d^-1) were calculated as an indicator of the relationship between CH₄ emission and the intake variables used to develop the prediction equations. Regression equations were developed with the PROC MIXED procedure (Statistical Analisys System, [SAS], 2013Statistical Analisys System [SAS]. (2013). SAS/STAT User guide, Version 9.4. Cary, NC: SAS Institute Inc.), starting with the inclusion of one variable each and progressing to a combination of two or more variables according to literature data, which showed that, for example, DMI and metabolizable energy intake are good predictors of methane emission (Axelsson, 1949Axelsson, J. (1949). The amount of produced methane energy in the European metabolic experiments with adult cattle. Annals of the Royal Agricultural College of Sweden, 16, 404-419.; Johnson & Johnson, 1995Johnson, K. A., & Johnson, D. E. (1995). Methane emissions from cattle. Journal of Animal Science , 73(8), 2483-2492. doi: 10.2527/1995.7382483x.
https://doi.org/10.2527/1995.7382483x.... ; Mills et al., 2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x.
https://doi.org/10.2527/2003.81123141x.... ). The sex of the animals was included in the model as a random effect.

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Table 1
Chemical composition of the diet.

Leave-one-out cross-validation was used to validate the equations developed, in which one observation is left out of the training data and is then used for the test. The method is repeated until all observations are removed and consequently used as test for each of the equations evaluated. Thus, the sum of the mean square prediction error was calculated for each equation as:

M S P E = \sum_{i = 1}^{n} \frac{{(O_{i} - P_{i})}^{2}}{n}

in which: O_i = value of CH₄ emission of the observation left out of the training data, in MJ d^-1, P_i = value of methane emission predicted with the equation tested (without observation O_i), in MJ d^-1. The prediction error obtained by the square root of MSE (RMSPE) is expressed as a proportion of the observed mean. The best equations were chosen based on the lowest RMSPE values. The equations were also evaluated by residual regression (observed CH₄ emission minus expected CH₄ emission) on the prediction centered around its respective means (St-Pierre, 2003St-Pierre, N. R. (2003). Reassessment of biases in predicted nitrogen flows to the duodenum by NRC 2001. Journal of Dairy Science , 86(1), 344-350. doi: 10.3168/jds.S0022-0302(03)73612-1.
https://doi.org/10.3168/jds.S0022-0302(0... ). The intercept of the equation was used to estimate mean bias, while linear bias was evaluated by the slope of the regression line.

Evaluation of equations described in the literature

Using the methane emission data obtained with the SF₆ tracer gas technique and the nutrient intake data, equations described in the literature were selected according to the availability of the predictor variables (Table 2). Correlations were estimated between observed methane emission and methane emission predicted with each of the equations tested (PROC CORR) (SAS, 2013). Equations exhibiting the lowest RMSPE, absence of bias (mean and linear) and highest correlation between observed and expected methane emission were considered to best fit the data evaluated.

Results

Table 3 shows the descriptive statistics of the variables analyzed. Dry matter intake (DMI) was 2.3% of live weight (LW), similar to the 2.5% reported by Corvino et al. (2011Corvino, T. L. S., Branco, R. H., Bonilha, S. F. M., Castilhos, A. M., Figueiredo, L. A., Razook, A. G., & Mercadante, M. E. Z. (2011). Residual feed intake and relationships with performance of Nellore cattle selected for post weaning weight. Revista Brasileira de Zootecnia, 40, 929-937. doi: 10.1590/S1516-35982011000400030.
https://doi.org/10.1590/S1516-3598201100... ) and Hulshof et al. (2012Hulshof, R. B. A., Berndt, A., Gerrits, W. J. J., Dijkstra, J., Van Zijderveld, S. M., Newbold, J. R., & Perdok, H. B. (2012). Dietary nitrate supplementation reduces methane emission in beef cattle fed sugarcane-based diets. Journal of Animal Science , 90(7), 2317-2323. doi: 10.2527/jas.2011-4209.
https://doi.org/10.2527/jas.2011-4209.... ) for Nellore steers and Nellore x Guzerat crossbreeds, respectively. Average methane emission was 8.17 MJ d^-1, corresponding to approximately 20 g CH₄ kg DM^-1 consumed, and 6.1% GEI.

Development of prediction equations for methane emission

Except for lignin intake, all intake variables analyzed were positively correlated with methane emission (Table 4).

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Table 2
Published equations used for the prediction of enteric methane emission from cattle.

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Table 3
Descriptive statistics of body weight, nutrient intake and methane emission (n=48).

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Table 4
Pearson correlation between CH₄ emission (MJ d^-1) and intake variables.

The correlation between methane emission and DMI was similar to the estimate of 0.43 reported by Fitzsimons, Kenny, Deighton, Fahey, and McGee (2013Fitzsimons, C., Kenny, D. A., Deighton, M. H., Fahey, A. G., & McGee, M. (2013). Methane emissions, body composition, and rumen fermentation traits of beef heifers differing in residual feed intake. Journal of Animal Science , 91(12), 5789-5800. doi: /10.2527/jas.2013-6956.
https://doi.org//10.2527/jas.2013-6956.... ). The equations including DMI and hemicellulose intake (Table 5, Equation 4) or DMI and total carbohydrate intake (Table 5, Equation 5) resulted in the lowest RMSPE values, thus providing the best fit to the dataset analyzed. The same was observed when metabolizable energy intake and cellulose intake were included (Table 5, Equation 7). The equations that included metabolizable energy intake and other variables were not significant in predicting methane emission (data not shown).

When lignin intake was included in the prediction equations, only Equation 9 (Table 5) was significant, with lignin intake being the only variable in the model. The equation developed from acid detergent fiber intake resulted in a low RMSPE value (Table 5, Equation 10).

Crude protein intake was positively correlated with methane emission (Table 4), and the effect of this variable on the prediction equations (Table 5, Equation 13) was positive. However, a negative correlation was observed between ether extract intake and methane emission (Table 4), and the inclusion of ether extract intake in the prediction equations (Table 5, Equation 2) had a negative effect on methane emission.

Evaluation of equations described in the literature

The equations described by Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675.
https://doi.org/10.3168/jds.2006-675... ) that exhibited the highest accuracy in predicting methane emission, and thus the lowest RMSPE (Table 6), were Eq. 2b, 4b, 8b, 11b and 14b (Table 2). On the other hand, the equation described by Axelsson (1949Axelsson, J. (1949). The amount of produced methane energy in the European metabolic experiments with adult cattle. Annals of the Royal Agricultural College of Sweden, 16, 404-419.), Linear 1 and Linear 2 of Mills et al. (2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x.
https://doi.org/10.2527/2003.81123141x.... ) and Moe and Tyrrell (1979Moe, P. W., & Tyrrell, H. F. (1979). Methane production in dairy cows. Journal of Dairy Science , 62(10), 1583-1586. doi: 10.3168/jds.S0022-0302(79)83465-7.
https://doi.org/10.3168/jds.S0022-0302(7... ) resulted in high RMSPE values and overestimated methane emission from the animals of the present study.

Discussion

The average loss of energy in the form of methane, defined by the percentage of enteric methane produced as a function of gross energy intake, was 6.1%, a value lower than the 6.5 to 7.5% predicted by the IPCC (2006Intergovernamental Panel on Climate Change [IPCC]. (2006). IPCC Guidelines for National Greenhouse Gasinventories Change. In H. S. Eggleston, L. Buendia, K. Miwa, T. Ngara, & K. Tanabe (Eds), Agriculture, Forestry and Other Land Use. Tokio, Japan: IPCC.) for cattle raised under tropical conditions. According to Benchaar, Pomar, and Chiquette (2001Benchaar, C., Pomar, C., & Chiquette, J. (2001). Evaluation of dietary strategies to reduce methane production in ruminants: A modelling approach. Canadian Journal of Animal Science, 81(4), 563-574. doi: doi.org/10.4141/A00-119.
https://doi.org/doi.org/10.4141/A00-119.... ), methane emission expressed as Mcal d^-1 increases when the percentage of concentrate in the diet increases from 0 to 20% and decreases when the animals are fed high-concentrate diets.

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Table 5
Linear equations developed for the prediction of enteric methane based on intake variables.

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Table 6
Evaluation of equations described in the literature.

Development of prediction equations for methane emission

Dry matter intake and metabolizable energy intake are the variables most commonly used to predict enteric methane emission (Axelsson, 1949Axelsson, J. (1949). The amount of produced methane energy in the European metabolic experiments with adult cattle. Annals of the Royal Agricultural College of Sweden, 16, 404-419.; Ellis et al., 2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675.
https://doi.org/10.3168/jds.2006-675... ; Johnson & Johnson, 1995Johnson, K. A., & Johnson, D. E. (1995). Methane emissions from cattle. Journal of Animal Science , 73(8), 2483-2492. doi: 10.2527/1995.7382483x.
https://doi.org/10.2527/1995.7382483x.... ; Mills et al., 2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x.
https://doi.org/10.2527/2003.81123141x.... ). Although the correlation between these variables and methane emission is of low magnitude (Table 4), the prediction equations including only these variables showed low RMSPE values (Table 5, Equations 1 and 6) and are therefore adequate to predict enteric methane emission. On the other hand, Ellis et al. (2007) observed that the use of DMI in prediction equations for methane emission from cattle resulted in lower RMSPE values than equations developed from metabolizable energy intake. According to the authors, many metabolizable energy intake values were extrapolated from other information provided in the publication and are likely to contain some error compared with DMI values.

The high correlation observed between non-fiber carbohydrate intake and methane emission (Table 4) indicates the potential of this variable to predict the emission of this gas in mathematical models. In fact, the equation based on non-fiber carbohydrate intake provided a low RMSPE (Table 5, Equation 15). According to Moe and Tyrrell (1979Moe, P. W., & Tyrrell, H. F. (1979). Methane production in dairy cows. Journal of Dairy Science , 62(10), 1583-1586. doi: 10.3168/jds.S0022-0302(79)83465-7.
https://doi.org/10.3168/jds.S0022-0302(7... ) and Mills et al. (2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x.
https://doi.org/10.2527/2003.81123141x.... ), the components of this fraction comprising sugars, starch and pectin are good predictors of methane emission since they show a high correlation with the latter. The low RMSPE was also observed when metabolizable energy intake and cellulose intake were included. According to Holter and Young (1992Holter, J. B., & Young, A. J. (1992). Nutrition, feeding and calves: methane prediction in dry and lactating Holstein cows. Journal of Dairy Science , 75(2165-2175). doi: 10.3168/jds.S0022-0302(92)77976-4.
https://doi.org/10.3168/jds.S0022-0302(9... ), cellulose and hemicellulose digestibility is highly correlated with methane emission since most ruminal hydrogen derived from carbohydrate fermentation and much of that generated during the conversion of hexoses into acetate or butyrate, via pyruvate, is converted to methane (Benchaar et al., 2001Benchaar, C., Pomar, C., & Chiquette, J. (2001). Evaluation of dietary strategies to reduce methane production in ruminants: A modelling approach. Canadian Journal of Animal Science, 81(4), 563-574. doi: doi.org/10.4141/A00-119.
https://doi.org/doi.org/10.4141/A00-119.... ). Thus, factors that contribute to high concentrations of acetate and butyrate, such as high amounts of fiber and fractions with a low passage rate (Hegarty & Gerdes, 1999Hegarty, R. S., & Gerdes, R. (1999). Hydrogen production and transfer in the rumen. Recent Advances in Animal Nutrition in Australia, 12, 37-44. ), result in increased methane emission.

When lignin intake was included in the prediction models, the effect on methane emission was negative. This finding might be explained by the fact that lignin exerts a limiting effect on the digestion of cellulose and hemicellulose, restricting the fermentation of foods by ruminal microorganisms (Ellis et al., 2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675.
https://doi.org/10.3168/jds.2006-675... ). However, Ellis et al. (2007) found no significant correlation between lignin and methane emission. The intake of acid detergent fiber, the portion that contains cellulose, lignin and sometimes silica, was also positively correlated with methane emission (Table 4), corroborating the results of Ellis et al. (2007). In general, diets rich in fibrous carbohydrates have a greater potential of enteric methane emission since the fermentation of these carbohydrates results in greater losses of energy in the form of methane when compared to the fermentation of sugars and starch (Boadi, Benchaar, Chiquette, & Massé, 2004Boadi, D., Benchaar, C., Chiquette, J., & Massé, D. (2004). Mitigation strategies to reduce enteric methane emissions from dairy cows: Update review. Canadian Journal of Animal Science , 84(3), 319-335. doi: 10.4141/A03-109.
https://doi.org/10.4141/A03-109.... ). The positive effect of crude protein intake on the prediction equations revealed that an increase in crude protein intake increases methane emission from the fermentation of amino acids into ammonia, volatile fatty acids, carbon dioxide, and methane (Mills et al., 2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x.
https://doi.org/10.2527/2003.81123141x.... ).

The inclusion of ether extract intake in the prediction equations had a negative effect on methane emission. High levels of dietary fat have been shown to depress methane emission due to the biohydrogenation of unsaturated fatty acids that act as a hydrogen sink, reducing the availability of hydrogen for methanogenic bacteria (Dong, Bae, McAllister, Mathison, & Cheng, 1997Dong, Y., Bae, H. D., McAllister, T. A., Mathison, G. W., & Cheng, K. J. (1997). Lipid-induced depression of methane production and digestibility in the artificial rumen system (RUSITEC). Canadian Journal of Animal Science , 77(2), 269-278. doi: 10.4141/A96-078.
https://doi.org/10.4141/A96-078.... ), as well as due to a reduction in fiber degradation through the formation of a layer that surrounds the fibers and impairs the adhesion of microorganisms (Mathison, 1997Mathison, G. (1997). Effect of canola oil on methane production in steers. Canadian Journal of Animal Science , 77, 545-546. ). Moreover, fats are not fermented in the rumen, and thus do not produce surplus of hydrogen, consequently methane production could be declined due to production of less hydrogen per unit of feed when higher levels of fats are included in the diets (Patra, 2013Patra, A. K. (2013). The effect of dietary fats on methane emissions, and its other effects on digestibility, rumen fermentation and lactation performance in cattle: A meta-analysis. Livestock science, 155(2-3), 244-254. doi: 10.1016/j.livsci.2013.05.023
https://doi.org/10.1016/j.livsci.2013.05... ).

According to St-Pierre (2003St-Pierre, N. R. (2003). Reassessment of biases in predicted nitrogen flows to the duodenum by NRC 2001. Journal of Dairy Science , 86(1), 344-350. doi: 10.3168/jds.S0022-0302(03)73612-1.
https://doi.org/10.3168/jds.S0022-0302(0... ), the intercept of regressing residuals (observed minus predicted value) on predicted values indicates mean bias of the prediction (accuracy) and the slope of the line, represented by regression coefficient b, indicates linear bias (systematic error). The intercept and coefficient assume a value of zero if the model is not biased. With the centralization of the independent variable (predicted methane) around its mean value, the two parameters estimated (intercept and regression coefficient) become orthogonal and, thus, independent. The application of the approach of St-Pierre (2003) revealed the absence of mean bias in the equations developed here, except for Equations 2 and 9 that showed linear bias (-0.691 MJ d CH₄ ^-1, p < 0.0001 and -1.348 MJ d CH₄ ^-1, p = 0.017, respectively). These equations tended to underestimate the predicted values, with the difference between observed and expected methane decreasing as the value predicted with these equations increased.

Evaluation of equations described in the literature

The best equations described in the literature Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675.
https://doi.org/10.3168/jds.2006-675... ) included DMI, metabolizable energy intake, acid detergent fiber intake and lignin intake (Table 2, Eq. 11b and 14b). Similar results have been reported by the same authors in a subsequent study (Ellis et al., 2009). The RMSPE of Eq. 2b described by Ellis et al. (2007) and of Eq. A described by Ellis et al. (2009), which included DMI as a single variable, was close to that obtained with the equation developed in the present study based on DMI (Table 5, Equation 1). However, Eq. A of Ellis et al. (2009) underestimated methane emission by approximately 0.861 MJ d^-1, which was not observed for Eq. 2b (Table 6). The high RMSPE values of equation of Axelsson (1949Axelsson, J. (1949). The amount of produced methane energy in the European metabolic experiments with adult cattle. Annals of the Royal Agricultural College of Sweden, 16, 404-419.) and Linear 1 of Mills et al. (2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x.
https://doi.org/10.2527/2003.81123141x.... ) was also reported by Ellis et al. (2007), evaluating these two equations for a beef and a dairy database and for the two databases combined (37.8 and 55.5%, 40.4 and 33.5%, and 40.9 and 40.7%, respectively). Although showing no systematic error, these equations overestimated methane emission in the present study by 3.55 and 4.65 MJ d^-1. Similarly, Wilkerson, Casper, and Mertens (1995Wilkerson, V. A., Casper, D. P., & Mertens, D. R. (1995). The Prediction of Methane Production of Holstein Cows by Several Equations1. Journal of Dairy Science , 78(11), 2402-2414. doi: 10.3168/jds.S0022-0302(95)76869-2.
https://doi.org/10.3168/jds.S0022-0302(9... ) observed that the equation of Axelsson (1949) overestimated methane emission from lactating and dry cows.

The equations described by Mills et al. (2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x.
https://doi.org/10.2527/2003.81123141x.... ), which were developed for dairy cows fed diets formulated for the lactation phase, estimated higher DMI and methane emission than those reported in the present study (12.5 ± 2.8 kg DM d^-1 and 16.8 ± 2.8 MJ d^-1, respectively), a fact that could explain the overestimation of methane emission by this equation. The equation described by Moe and Tyrrell (1979Moe, P. W., & Tyrrell, H. F. (1979). Methane production in dairy cows. Journal of Dairy Science , 62(10), 1583-1586. doi: 10.3168/jds.S0022-0302(79)83465-7.
https://doi.org/10.3168/jds.S0022-0302(7... ), which was based on carbohydrate intake, resulted in a high RMSPE and mean bias, and overestimated methane emission from the animals of the present study by 1.686 MJ d^-1. Equation 1b of Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675.
https://doi.org/10.3168/jds.2006-675... ) resulted in a lower RMSPE than Linear 2 of Mills et al. (2003). Both equations were developed based on metabolizable energy intake. However, the two equations overestimated methane emission by 0.467 and 5.167 MJ d^-1, respectively.

The equations developed in the present study that included DMI and total carbohydrate intake, metabolizable energy intake and cellulose intake, and DMI and non-fiber carbohydrate intake were the most accurate to predict enteric methane emission. Among the equations described in the literature, the equations proposed by Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675.
https://doi.org/10.3168/jds.2006-675... ) that included DMI, metabolizable energy intake, acid detergent fiber intake and lignin intake resulted in the lowest RMSPE when the database of the present study was used. The equations developed in this study showed higher accuracy in predicting methane emission and can be considered more specific for Zebu production systems in tropical climates. The equations developed in the present study can be used for predicting methane emission from cattle under conditions similar to those evaluated here, either to estimate emissions from cattle herds or in national inventories to determine methane emission in beef cattle production systems.

Conclusion

Dry matter and nutrient intake, except for lignin and ether extract intake, are positively correlated with methane emission. The mean error of predicting enteric methane emission with the equations developed in this study based on DMI and nutrient intake is 17% and the most accurate predictions are obtained with equations that include dry matter intake, carbohydrate intake and metabolizable energy intake. Among the equations described in the literature and evaluated using our database, the most accurate predictions are obtained with those that include dry matter intake, metabolizable energy intake, acid detergent fiber intake, and lignin intake.

Acknowledgements

The authors thank Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq-Proc. 562783/2010-5) and Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP-Proc. 2010/52201-1) for financial support, and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for the scholarship granted to the first author.

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Publication Dates

Publication in this collection
07 Jan 2019
Date of issue
2019

History

Received
23 Apr 2018
Accepted
09 July 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Association Official Analytical Chemists [AOAC]. (1990). Official Methods of Analysis (15th ed.). Arlington, VA: AOAC International.

[2] Axelsson, J. (1949). The amount of produced methane energy in the European metabolic experiments with adult cattle. Annals of the Royal Agricultural College of Sweden, 16, 404-419.

[3] Benchaar, C., Pomar, C., & Chiquette, J. (2001). Evaluation of dietary strategies to reduce methane production in ruminants: A modelling approach. Canadian Journal of Animal Science, 81(4), 563-574. doi: doi.org/10.4141/A00-119.
» https://doi.org/doi.org/10.4141/A00-119.

[4] Blaxter, K. L., & Clapperton, J. L. (1965). Prediction of the amount of methane produced by ruminants. British Journal of Nutrition, 19(1), 511-522. doi: 10.1079/BJN19650046.
» https://doi.org/10.1079/BJN19650046.

[5] Boadi, D., Benchaar, C., Chiquette, J., & Massé, D. (2004). Mitigation strategies to reduce enteric methane emissions from dairy cows: Update review. Canadian Journal of Animal Science , 84(3), 319-335. doi: 10.4141/A03-109.
» https://doi.org/10.4141/A03-109.

[6] Caro, D., Davis, S. J., Bastianoni, S., & Caldeira, K. (2014). Global and regional trends in greenhouse gas emissions from livestock. Climatic Change, 126(1-2), 203-216. doi: 10.1007/s10584-014-1197-x.
» https://doi.org/10.1007/s10584-014-1197-x.

[7] Corvino, T. L. S., Branco, R. H., Bonilha, S. F. M., Castilhos, A. M., Figueiredo, L. A., Razook, A. G., & Mercadante, M. E. Z. (2011). Residual feed intake and relationships with performance of Nellore cattle selected for post weaning weight. Revista Brasileira de Zootecnia, 40, 929-937. doi: 10.1590/S1516-35982011000400030.
» https://doi.org/10.1590/S1516-35982011000400030.

[8] Dong, Y., Bae, H. D., McAllister, T. A., Mathison, G. W., & Cheng, K. J. (1997). Lipid-induced depression of methane production and digestibility in the artificial rumen system (RUSITEC). Canadian Journal of Animal Science , 77(2), 269-278. doi: 10.4141/A96-078.
» https://doi.org/10.4141/A96-078.

[9] Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725.
» https://doi.org/10.2527/jas.2007-0725.

[10] Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675.
» https://doi.org/10.3168/jds.2006-675

[11] Etheridge, R. D., Pesti, G. M., & Foster, E. H. (1998). A comparison of nitrogen values obtained utilizing the Kjeldahl nitrogen and Dumas combustion methodologies (Leco CNS 2000) on samples typical of an animal nutrition analytical laboratory. Animal Feed Science and Technology, 73(1-2), 21-28. doi: 10.1016/S0377-8401(98)00136-9.
» https://doi.org/10.1016/S0377-8401(98)00136-9.

[12] Fitzsimons, C., Kenny, D. A., Deighton, M. H., Fahey, A. G., & McGee, M. (2013). Methane emissions, body composition, and rumen fermentation traits of beef heifers differing in residual feed intake. Journal of Animal Science , 91(12), 5789-5800. doi: /10.2527/jas.2013-6956.
» https://doi.org//10.2527/jas.2013-6956.

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» https://doi.org/10.2527/2003.81123141x.

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» https://doi.org/10.3168/jds.S0022-0302(79)83465-7.

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» https://doi.org/10.3168/jds.S0022-0302(95)76869-2.

Item¹	Ingredients			Total diet
Item¹	Hay	Corn	Cottonseed meal
DM, g kg^-1	894	857	886	868
OM, g kg^-1 DM	944	979	948	941
Ash, g kg^-1 DM	55.6	20.7	52.6	42.0
CP, g kg^-1 DM	57.7	102	315	139
EE, g kg^-1 DM	12.2	78.8	17.1	34.5
NDF, g kg^-1 DM	774	451	609	620
NDFap, g kg^-1 DM	743	416	569	587
ADF, g kg^-1 DM	444	57.4	336	288
Lignin, g kg^-1 DM	68.1	6.50	111	56.2
Cellulose, g kg^-1 DM	376	50.9	225	232
Hemicellulose, g kg^-1 DM	330	394	273	332
TDN, g kg^-1 DM	535	807	489	602
TCH, g kg^-1 DM	875	799	615	784
NFC, g kg^-1 DM	131	383	45.6	198
GE, Mcal kg^-1	4.18	4.5.2	4.50	4.28
DE, Mcal kg^-1	2.36	3.6.4	2.28	2.71
ME, Mcal kg^-1	1.93	3.22	1.85	2.29

Source	Equation
Ellis et al. (2009Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725. https://doi.org/10.2527/jas.2007-0725.... ) Eq. A	$C H_{4} (M J d^{- 1}) = 2.29 + 0.670 D M I (k g d^{- 1})$
Ellis et al. (2009Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725. https://doi.org/10.2527/jas.2007-0725.... ) Eq. B	$C H_{4} (M J d^{- 1}) = 3.05 + 3.71 C E L I (k g d^{- 1})$
Ellis et al. (2009Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725. https://doi.org/10.2527/jas.2007-0725.... ) Eq. D	$C H_{4} (M J d^{- 1}) = 6.01 + 0.345 N F C I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 1b	$C H_{4} (M J d^{- 1}) = 4.38 + 0.0586 M E I (M J d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 2b	$C H_{4} (M J d^{- 1}) = 3.96 + 0.561 D M I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 4b	$C H_{4} (M J d^{- 1}) = 5.26 + 6.93 L I G I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 5b	$C H_{4} (M J d^{- 1}) = 5.58 + 0.848 N D F I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 6b	$C H_{4} (M J d^{- 1}) = 5.70 + 1.41 A D F I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 7b	$C H_{4} (M J d^{- 1}) = 3.05 + 0.0371 M E I (M J d^{- 1}) + 0.801 N D F I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 8b	$C H_{4} (M J d^{- 1}) = 3.31 + 0.0382 M E I (M J d^{- 1}) + 1.05 A D F I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 11b	$C H_{4} (M J d^{- 1}) = 2.30 + 1.12 D M I (k g d^{- 1}) - 6.26 L I G I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 12b	$C H_{4} (M J d^{- 1}) = 2.70 + 1.16 D M I (k g d^{- 1}) - 15.8 E E I (k g d^{- 1})$
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 14b	$C H_{4} (M J d^{- 1}) = 2.94 + 0.0585 M E I (M J d^{- 1}) + 1.44 A D F I (k g d^{- 1}) - 4.16 L I G I (k g d^{- 1})$
Axelsson (1949Axelsson, J. (1949). The amount of produced methane energy in the European metabolic experiments with adult cattle. Annals of the Royal Agricultural College of Sweden, 16, 404-419.)	$C H_{4} (M J d^{- 1}) = 2.07 + 2.64 D M I (k g d^{- 1}) - 0.105 D M I^{2} (k g d^{- 1})$
Mills et al. (2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x. https://doi.org/10.2527/2003.81123141x.... ) Linear 1	$C H_{4} (M J d^{- 1}) = 5.93 + 0.92 D M I (k g d^{- 1})$
Mills et al. (2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x. https://doi.org/10.2527/2003.81123141x.... ) Linear 2	$C H_{4} (M J d^{- 1}) = 8.25 + 0.07 M E I (k g d^{- 1})$
Moe and Tyrrel (1979Moe, P. W., & Tyrrell, H. F. (1979). Methane production in dairy cows. Journal of Dairy Science , 62(10), 1583-1586. doi: 10.3168/jds.S0022-0302(79)83465-7. https://doi.org/10.3168/jds.S0022-0302(7... )	$C H_{4} (M J d^{- 1}) = 0.341 + 0.511 N F C I (k g d^{- 1}) + 1.75 H E M I (k g d^{- 1}) + 2.65 C E L I (k g d^{- 1})$

Variable	Mean	SD	CV (%)	Minimum	Maximum
LW, kg	332	35.3	10.6	225	409
DMI, kg d^-1	7.49	0.77	10.3	5.41	9.14
OMI, kg d^-1	7.04	0.739	10.5	5.05	8.64
MEI, MJ d^-1	72.6	7.32	10.1	53.1	87.4
GEI, MJ d^-1	1.35	0.13	9.66	0.989	1.61
CPI, kg d^-1	1.08	0.107	9.64	0.795	1.3
EEI, kg d^-1	0.269	0.048	17.7	0.185	0.367
NDFIap, kg d^-1	4.32	0.449	10.4	3.11	5.29
ADFI, kg d^-1	2.09	0.244	11.7	1.46	2.66
LIGI, kg d^-1	0.413	0.046	11.2	0.319	0.504
CELI, kg d^-1	1.69	0.229	13.5	1.15	2.2
HEMI, kg d^-1	2.48	0.252	10.1	1.79	3.0
TCHI, kg d^-1	5.69	0.63	11.0	4.02	7.08
NFCI, kg d^-1	1.38	0.209	15.2	0.909	1.79
TDNI, kg d^-1	4.58	0.471	10.3	3.32	5.56
Methane emission
CH₄, MJ d^-1	8.17	1.47	18.0	5.07	12.2
CH₄, g d^-1	148	26.6	18.0	92.0	222
CH₄, g kg^-1 DMI	19.9	3.13	15.7	11.8	26.8
CH₄, % GEI	6.10	1.13	18.6	3.57	9.49

Variable	CH₄ (MJ d^-1)	P-value
DMI, kg d^-1	0.40	0.005
OMI, kg DM d^-1	0.43	0.002
MEI, MJ d^-1	0.37	0.010
DEI, MJ d^-1	0.37	0.010
CPI, kg DM d^-1	0.40	0.005
EEI, kg DM d^-1	-0.40	0.005
NDFIap, kg DM d^-1	0.36	0.011
ADFI, kg DM d^-1	0.50	0.0003
LIGI, kg DM d^-1	-0.009	0.952
CELI, kg DM d^-1	0.58	<0.0001
HEMI, kg DM d^-1	0.35	0.015
TCHI, kg DM d^-1	0.47	0.0007
NFCI, kg DM d^-1	0.63	<0.0001
TDNI, kg DM d^-1	0.41	0.004

Equation		RMSPE
Equation 1	$C H_{4} (M J d^{- 1}) = 4.41 (\pm 1.86) + 0.50 (\pm 0.227) D M I (k g d^{- 1})$	17.00
Equation 2	$C H_{4} (M J d^{- 1}) = 5.26 (\pm 2.78) + 2.53 (\pm 0.792) D M I (k g d^{- 1}) - 59.7 (\pm 22.3) E E I (k g d^{- 1})$	29.73
Equation 3	$C H_{4} (M J d^{- 1}) = 4.97 (\pm 1.71) - 1.31 (\pm 0.507) D M I (k g d^{- 1}) + 7.69 (\pm 1.70) C E L I (k g d^{- 1})$	19.61
Equation 4	$C H_{4} (M J d^{- 1}) = 4.08 (\pm 1.65) + 11.6 (\pm 2.34) D M I (k g d^{- 1}) - 33.4 (\pm 7.21) H E M I (k g d^{- 1})$	14.34
Equation 5	$C H_{4} (M J d^{- 1}) = 5.26 (\pm 1.69) - 6.30 (\pm 1.47) D M I (k g d^{- 1}) + 8.80 (\pm 1.81) T C H I (k g d^{- 1})$	14.05
Equation 6	$C H_{4} (M J d^{- 1}) = 4.55 (\pm 1.89) + 0.050 (\pm 0.024) M E I (M J d^{- 1})$	17.11
Equation 7	$C H_{4} (M J d^{- 1}) = 5.16 (\pm 1.72) - 0.130 (\pm 0.048) M E I (M J d^{- 1}) + 7.37 (\pm 1.53) C E L I (k g d^{- 1})$	14.26
Equation 8	$C H_{4} (M J d^{- 1}) = 4.06 (\pm 1.65) + 2.42 (\pm 0.926) C E L I (k g d^{- 1})$	15.73
Equation 9	$C H_{4} (M J d^{- 1}) = 4.75 (\pm 1.92) + 8.26 (\pm 3.95) L I G I (k g d^{- 1})$	18.83
Equation 10	$C H_{4} (M J d^{- 1}) = 4.32 (\pm 1.72) + 1.85 (\pm 0.760) A D F I (k g d^{- 1})$	16.26
Equation 11	$C H_{4} (M J d^{- 1}) = 4.55 (\pm 1.83) + 0.838 (\pm 0.383) N D F I_{a p} (k g d^{- 1})$	17.12
Equation 12	$C H_{4} (M J d^{- 1}) = 4.35 (\pm 1.84) + 0.543 (\pm 0.241) O M I (k g d^{- 1})$	16.74
Equation 13	$C H_{4} (M J d^{- 1}) = 4.50 (\pm 1.94) + 3.40 (\pm 1.66) C P I (k g d^{- 1})$	16.84
Equation 14	$C H_{4} (M J d^{- 1}) = 4.27 (\pm 1.80) + 0.685 (\pm 0.292) T C H I (k g d^{- 1})$	16.48
Equation 15	$C H_{4} (M J d^{- 1}) = 3.14 (\pm 1.48) + 3.65 (\pm 1.05) N F C I (k g d^{- 1})$	14.73
Equation 16	$C H_{4} (M J d^{- 1}) = 4.44 (\pm 1.87) + 0.813 (\pm 0.374) T D N I (k g d^{- 1})$	16.87
Equation 17	$C H_{4} (M J d^{- 1}) = 4.75 (\pm 1.87) + 1.45 (\pm 0.683) H E M I (k g d^{- 1})$	17.21
Equation 18	$C H_{4} (M J d^{- 1}) = 4.53 (\pm 1.88) + 0.042 (\pm 0.020) D E I (M J d^{- 1})$	17.28

Equation	Mean bias¹		Linear bias²		RMSPE³	PC⁴
Equation	Exp (MJd^-1)	P	Exp (MJ d^-1)	P	(% Obs)
Ellis et al. (2009Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725. https://doi.org/10.2527/jas.2007-0725.... ) Eq. A	0.861	<0.0001	0.136	0.724	19.42	0.399**
Ellis et al. (2009Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725. https://doi.org/10.2527/jas.2007-0725.... ) Eq. B	-1.163	<0.0001	-0.003	0.990	20.31	0.579***
Ellis et al, (2009Ellis, J. L., Kebreab, E., Odongo, N. E., Beauchemin, K., McGinn, S., Nkrumah, J. D., ... McBride, B. W. (2009). Modeling methane production from beef cattle using linear and nonlinear approaches. Journal of Animal Science, 87(4), 1334-1345. doi: 10.2527/jas.2007-0725. https://doi.org/10.2527/jas.2007-0725.... ) Eq. D	1.631	<0.0001	11.596	<0.0001	26.85	0.630***
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 1b	-0.467	0.023	0.250	0.600	17.54	0.366*
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 2b	0.0086	0.965	0.353	0.446	16.39	0.399**
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 4b	0.0361	0.866	-1.043	0.127	18.23	-0.009^ns
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 5b	-1.072	<0.0001	0.400	0.455	21.21	0.363*
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 6b	-0.471	0.015	1.114	0.047	17.11	0.496**
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 7b	-1.034	<0.0001	-0.149	0.645	20.86	0.365*
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 8b	-0.106	0.585	0.201	0.587	16.11	0.433**
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 11b	0.071	0.701	0.125	0.652	15.27	0.516**
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 12b	1.033	<0.0001	-0.019	0.910	18.36	0.662***
Ellis et al. (2007Ellis, J. L., Kebreab, E., Odongo, N. E., McBride, B. W., Okine, E. K., & France, J. (2007). Prediction of methane production from dairy and beef cattle. Journal of Dairy Science, 90(7), 3456-3466. 10.3168/jds.2006-675. https://doi.org/10.3168/jds.2006-675... ) Eq. 14b	-0.304	0.105	0.161	0.576	15.74	0.513**
Axelsson (1949Axelsson, J. (1949). The amount of produced methane energy in the European metabolic experiments with adult cattle. Annals of the Royal Agricultural College of Sweden, 16, 404-419.)	-3.552	<0.0001	-0.336	0.160	46.59	0.383**
Mills et al. (2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x. https://doi.org/10.2527/2003.81123141x.... ) Linear 1	-4.650	<0.0001	-0.176	0.532	59.23	0.399**
Mills et al. (2003Mills, J. A. N., Kebreab, E., Yates, C. M., Crompton, L. A., Cammell, S. B., Dhanoa, M. S., ... France, J. (2003). Alternative approaches to predicting methane emissions from dairy cows. Journal of Animal Science , 81(12), 3141-3150. doi: 10.2527/2003.81123141x. https://doi.org/10.2527/2003.81123141x.... ) Linear 2	-5.167	<0.0001	0.046	0.907	65.38	0.366*
Moe and Tyrrel (1979Moe, P. W., & Tyrrell, H. F. (1979). Methane production in dairy cows. Journal of Dairy Science , 62(10), 1583-1586. doi: 10.3168/jds.S0022-0302(79)83465-7. https://doi.org/10.3168/jds.S0022-0302(7... )	-1.686	<0.0001	-0.319	0.061	26.01	0.516***