Effects of grain species and grain processing method on DMI, rate and efficiency of gain, and feeding value for cattle fed high concentrate diets were appraised by statistically compiling results from 605 comparisons from feeding trials published in North American journals and experiment station bulletins since 1974. Metabolizable energy (ME) values for each grain and processing method were calculated by quadratic procedures from DMI and animal performance. Averaged across processing methods, ME values for corn, milo, and wheat grain (3.40, 3.22, and 3.46 Mcal/kg DM) fell within 9% of ME estimates from NRC (1996) for beef cattle. In contrast, ME values for barley and oats grain (3.55 and 3.46 Mcal/kg DM) were 24% and 17% greater than NRC (1996) estimates. Compared with the dry rolled forms, high moisture corn and milo resulted in lower ADG and DMI. Compared with dry rolling, either steam rolling or flaking of corn, milo, and wheat decreased DMI without decreasing ADG and improved feed efficiency by 10, 15, and 10%, respectively. Compared with dry rolled grain, steam flaking increased (P < .05) body weight-adjusted ME of corn and milo grain by 15 and 21%, respectively; body weight-adjusted ME for whole corn was 9% greater (P < .05) than for rolled corn grain. Steam flaking was surprisingly effective (13%) at increasing (P < .05) the body weight-adjusted ME of wheat, but steam flaking failed to increase the ME of barley and oats. Higher moisture content of high-moisture corn decreased dry matter intake without depressing ADG and improved efficiency and increased ME of the grain. Compared with steam flakes of moderate thinness, processing milo or barley to a very thin flake tended to reduce ADG and failed to improve feed efficiency. The ideal roughage source and roughage moisture content for maximum ME and ADG varied with grain processing method. Feeding corn silage rather than alfalfa and wet rather than dry roughage depressed (P < .01) ADG of cattle and reduced (P < .01) body weight-adjusted ME of cattle fed high-moisture corn grain but tended to increase both with steam-flaked corn or wheat.
[1]
W. H. Hale.
Influence of Processing on the Utilization of Grains (Starch) by Ruminants
,
1973
.
[2]
D. Waldo.
Extent and Partition of Cereal Grain Starch Digestion in Ruminants
,
1973
.
[3]
T. Klopfenstein,et al.
Adaptation to High Concentrate Diets by Beef Cattle. I. Adaptation to Corn and Wheat Diets
,
1979
.
[4]
Roughage levels in feedlot rations
,
1981
.
[5]
F. Owens,et al.
Influence of feed intake level on site of digestion in steers fed a high concentrate diet.
,
1983,
Journal of animal science.
[6]
F. Owens,et al.
Limits to starch digestion in the ruminant small intestine.
,
1986,
Journal of animal science.
[7]
C. B. Theurer.
Grain processing effects on starch utilization by ruminants.
,
1986,
Journal of animal science.
[8]
E. Ørskov.
Starch digestion and utilization in ruminants.
,
1986
.
[9]
L. Rooney,et al.
Factors affecting starch digestibility with special emphasis on sorghum and corn.
,
1986,
Journal of animal science.
[10]
R. Preston,et al.
Improved enzymatic method to measure processing effects and starch availability in sorghum grain.
,
1990,
Journal of animal science.
[11]
R. Zinn.
Influence of flake density on the comparative feeding value of steam-flaked corn for feedlot cattle.
,
1990,
Journal of animal science.
[12]
R. Zinn.
Influence of processing on the comparative feeding value of barley for feedlot cattle.
,
1993,
Journal of animal science.
[13]
T. Klopfenstein,et al.
Effect of protein source and grain type on finishing calf performance and ruminal metabolism.
,
1993,
Journal of animal science.
[14]
F. Fluharty,et al.
The influence of intake level and corn processing on digestibility and ruminal metabolism in steers fed all-concentrate diets.
,
1994,
Journal of animal science.