Relationships among carbon dioxide, feed intake, and feed efficiency traits in ad libitum fed beef cattle.

Angus cattle from 2 beef cattle projects on which carbon dioxide production rate (CPR) was measured were used in this study to examine the relationships among BW, DMI, and carbon dioxide traits of beef cattle fed ad libitum on a roughage diet or a grain-based feedlot diet, and to evaluate potential proxies for DMI and feed efficiency. In both projects, the GreenFeed Emission Monitoring system, which provides multiple short-term breath measures of carbon dioxide production, was used as a tool to measure CPR. The data were from 119 Angus heifers over 15 d on a roughage diet and 326 Angus steers over 70 d on a feedlot diet. Mean (±SD) age, BW, and DMI were 372 ± 28 d, 355 ± 37 kg, and 8.1 ± 1.3 kg/d for the heifers, and 554 ± 86 d, 577 ± 69 kg, and 13.3 ± 2.0 kg/d for the steers, respectively. The corresponding mean CPR was 5760 ± 644 g/d for heifers and 8939 ± 1212 g/d for steers. Other traits studied included carbon dioxide yield (CY; CPR/DMI) and intensity (CI; CPR/BW) and 5 forms of residual carbon dioxide production (RCP), which is a measure of actual minus predicted CPR. Feed efficiency traits studied included feed conversion ratio (FCR) and residual feed intake (RFI). The relationship between CPR and DMI, and between CPR and BW was both positive and linear, for the heifers and also for the steers. For the combined heifer and steer datasets, the R2 for the relationship between CPR and BW, and between CPR and DMI was 0.82 and 0.78, respectively. The correlation between CPR and DMI (r = 0.84 for heifers; r = 0.83 for steers) was similar to that between CPR and BW (r = 0.84 for heifers; r = 0.87 for steers). Most of the carbon dioxide traits were significantly (P < 0.05) correlated with one or both feed efficiency traits. One of the RCP traits (RCPMA) was computed by maintaining metabolic BW (M) and average daily gain (A) in the formula for RFI, but substituting the DMI with CPR. The correlation (r = 0.27) between RCPMA and RFI, though significantly different from zero, was not strong enough for its use as proxy for RFI. On the other hand, a strong correlation (r = 0.73) was obtained between the CPR to gain ratio (CGR) and FCR. This indicates that, where DMI is not available, CPR could be used in its place to compute a feed efficiency trait similar to FCR, since the computation of CGR was similar to that for FCR, except that DMI was substituted with CPR in the FCR formula.

[1]  S. Gunter,et al.  Measuring the respiratory gas exchange by grazing cattle using an automated, open-circuit gas quantification system. , 2018, Translational animal science.

[2]  R. Herd,et al.  Phenotypic relationships among methane production traits assessed under ad libitum feeding of beef cattle. , 2017, Journal of animal science.

[3]  R. Herd,et al.  Optimizing test procedures for estimating daily methane and carbon dioxide emissions in cattle using short-term breath measures. , 2017, Journal of animal science.

[4]  J. Basarab,et al.  Repeatability and variability of short-term spot measurement of methane and carbon dioxide emissions from beef cattle using GreenFeed emissions monitoring system , 2016, Canadian Journal of Animal Science.

[5]  R. Herd,et al.  Proxies to adjust methane production rate of beef cattle when the quantity of feed consumed is unknown , 2016 .

[6]  R. Herd,et al.  Repeatability of methane emission measurements in Australian beef cattle , 2016 .

[7]  C. Dorich,et al.  Integrating spot short-term measurements of carbon emissions and backward dietary energy partition calculations to estimate intake in lactating dairy cows fed ad libitum or restricted. , 2015, Journal of dairy science.

[8]  D. Revell,et al.  Feed intake of sheep when allowed ad libitum access to feed in methane respiration chambers. , 2014, Journal of animal science.

[9]  D. Berry,et al.  Cell Biology Symposium: genetics of feed efficiency in dairy and beef cattle. , 2013, Journal of animal science.

[10]  K. Ominski,et al.  Estimation of carbon dioxide production and energy expenditure of grazing cattle by the sulphur hexafluoride (SF6) tracer gas technique , 2008 .

[11]  C. Pinares-Patiño,et al.  Effects of stocking rate on methane and carbon dioxide emissions from grazing cattle , 2007 .

[12]  A. D. Kennedy,et al.  Validation of the sulphur hexafluoride (SF6) tracer gas technique for measurement of methane and carbon dioxide production by cattle , 2002 .

[13]  B. M. Bindon,et al.  Genesis of the Cooperative Research Centre for the Cattle and Beef Industry: integration of resources for beef quality research (1993-2000) , 2001 .

[14]  J. Archer,et al.  Genetic and phenotypic variance and covariance components for feed intake, feed efficiency, and other postweaning traits in Angus cattle. , 2001, Journal of animal science.

[15]  J. Archer,et al.  Optimum postweaning test for measurement of growth rate, feed intake, and feed efficiency in British breed cattle. , 1997, Journal of animal science.

[16]  G. Schwarz Estimating the Dimension of a Model , 1978 .

[17]  J. Brockway,et al.  Measurement of carbon dioxide production in sheep by isotope dilution. , 1972, Quarterly journal of experimental physiology and cognate medical sciences.

[18]  F. T. Jung The Fire of Life , 1962 .

[19]  K. L. Blaxter,et al.  The energy metabolism of ruminants. , 1962 .