By:Bob Myer and Matt Hersom - Department of Animal Sciences, Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida
Corn gluten feed (CGF) is a co-product from the wet-corn milling industry that manufactures starch, sweeteners, syrup, and oil from corn (Weigel et al). Corn gluten feed is readily available in the southeastern USA and its price has been favorable when compared to other feeds. Corn gluten feed is a good feed for beef cattle; however, producers should be aware of some potential problems with this feedstuff.
Utilizing Corn Gluten Feed
Corn gluten feed is mainly composed of corn bran and steep liquor, with the amount of steep liquor inclusion affecting the final color and nutritive quality. Corn gluten feed is available either in a dry or wet form. Dry CGF is the most common form available in the deep southeast, and can be purchased as a meal or pellets. Since the starch and oil are removed, CGF is relatively high in crude protein. Crude protein averages 23.5% (dry matter (DM) basis) but can range from 16 to 30% (Dairy One Laboratory).
The energy valve of CGF is good, almost as high as corn. The total digestible nutrients (TDN) value of CGF is about 75 to 83%, compared to whole corn grain which has a TDN value of 88%. However, the form of energy in CGF is different from corn. Most of the energy in corn is from starch, whereas in CGF the energy comes from digestible fiber (bran fraction). Corn gluten feed is an excellent compliment to forage based diets because it is a low starch, high fiber energy source. Additionally, CGF does contain some fat that will increase the energy density of the diet. The composition of CGF is presented in Table 1.
Since CGF is a good source of both protein and energy, the relative economic value of this feed depends upon the relative price of corn and of a protein supplement such as soybean meal. The protein and energy provided by 100 lbs of CGF (90% DM) is roughly equal to 75 lbs of corn and 25 lbs of soybean meal (48% CP). The CGF product is a good source of degradable intake protein. Approximately 50% of the crude protein of CGF is soluble with 70-75% of the protein being ruminally degradable.
Considerations for Use
A few cautions about feeding CGF. First, the sulfur (S) concentration of CGF is high relative to the animal's requirement. Sulfur dioxide is added during the wet milling process to aid in the extraction of starch. The added S ends up in the steep liquor which is one of the components of CGF. The sulfur concentration in CGF averages around 0.5% (DM basis), with a range of 0.33 to 0.73%. The S requirement for beef cattle is 0.15 to 0.2% total dietary S. The upper safe limit is 0.4% total dietary S (NRC, 2005). Feeding large amounts of CGF with a high S concentration can lead to S toxicity, resulting in reduced feed intake and possibly death. A specific disorder associated with excess S is polioencephalomalacia (PEM or commonly referred to as "brainers"; Niles et al., 2000). This disorder affects the nervous system resulting in blindness, incoordination, and seizures (Gould, 1998). Excess S in the diet can also increase the risk of a copper deficiency. Copper is an essential trace mineral important for growth, immunity, and other metabolic functions (NRC, 2005). The potential risk of high S in the total diet could limit the amount of CGF than can be used in a feeding program.
Another caution is the high phosphorus (P) concentration. Phosphorus is an essential nutrient, however, the concentration in CGF (0.9 to 1.1%) far exceeds requirement (0.25 to 0.35%; DM basis). Dietary P excess has been associated with the formation of urinary calculi ("waterbelly") in cattle. The problem of excess P can be minimized by insuring adequate intake of calcium (Ca). Excess P concentration along with a low Ca concentration would worsen the detrimental effect(s) of excess P. High P intake can also result in high P excretion by the animal resulting in high P concentrations in the urine and manure.
Finally, be aware that the nutrient content of CGF is quite variable. As mentioned above, crude protein, the protein's degradability, and mineral content of CGF can vary widely. Thus, it would be desirable to have CGF analyzed, especially if large amounts are used. The color of CGF should be yellow to tan. Dark coloring along with a "burned" smell would indicate "scorching". Scorching can have a negative effect on nutritive value, particularly the protein availability and digestibility.
Feeding Guidelines
Because of the risk of high S intake, CGF should be limited to 50% or less of the total dry matter intake. For example, a 600 lb calf should receive no more than 6 lbs per day, or a mature beef cow, 12 lbs per day. It should be pointed out that many nutritionists recommend even lower limits (i.e., 0.5% of body weight per day which in the above examples would be 3 lbs and 6 lbs per day). An effective practice is to blend CGF with another feed such as soybean hulls. In fact, a 50:50 blend of CGF and soyhulls is a good feed for a backgrounding program. Because of the high P concentration in CGF, ensure an acceptable total dietary Ca:P by providing adequate supplemental Ca either as part of the mixed ration or included as a component of a free choice salt-mineral mix. The final consideration is that CGF, like corn itself, is low in the amino acid lysine. If dietary lysine concentration is a concern, amino acid evaluation and amino acid supplementation could be considered.
In all, CGF is a good feed for beef cattle. However, be aware of potential problems with the feed, especially when fed at a high level.
References and Further Reading
Dairy One laboratory analyses results library accumulated data 5/21/2000 - 4/30/2007. www.dairyone.com Accessed Feb. 25, 2008
Gould, D. H. 1998. Polioencephalomalacia. J. Anim. Sci. 76:309-314.
Niles, G.A., S. Morgan, W.C. Edwards, and D.L. Lelman. 2000. Effects of increasing dietary sulfur concentration on the incidence and pathology of polioencephalomalicia in weaned beef calves. Anim. Sci. Res. Rpt., Dept. of Animal Science, Oklahoma State University, Stillwater, OK. Pp 55-60. http://www.ansi.okstate.edu/research/2000rr/11.htm .
NRC. 2005. Mineral tolerance of domestic animals. National Research Council, Natl Academy of Sciences, Natl Academy Press, Washington DC. Pp 134-153.
NRC. 2000. Nutrient Requirements of Beef Cattle 7th ed (2000 update). Natl Academy Press, Washington DC. Pp 136-137.
Weigel, J.C., D. Loy, and L. Kilmer. Feed co-products of the corn wet milling process. Natl Corn Growers Assoc., St. Louis, MO. 21 pg.
EDIS publications:
Plant Protein By-product Feedstuffs for Dairy Cattle,
Florida Cow-Calf Management, 2nd Edition -- Maintaining a Healthy Herd,
Total Protein Requirement of Beef Cattle II: Feeding By-product Feedstuffs, and
Average Nutrient Content and Bulk Price of Byproduct Feeds Commonly Available to Florida Cattle Producers.
Tables
Table 1. Typical nutrient composition of corn gluten feed, a co-product of corn wet milling process.a
Dairy Oneb
Item
Averagea
Range
NRC 2000c
Dry matter, %
89.0
85.6 - 92.5
90
Crude protein, %
23.6
16.6 - 30.6
23.8
Crude fat, %
3.9
2.1 - 5.6
3.9
Crude fibre, %
8.0
5.9 - 10.1
7.5
NDFd, %
35.9
29.2 - 42.6
36.2
ADFe, %
11.1
8.3 - 13.9
12.7
TDNf, %
73.1
70.2 - 76.0
80
NEgg, mcal/lb
0.49
0.46 - 0.54
0.59
NEmh, mcal/lb
0.78
0.73 - 0.83
0.88
Phosphorus, %
1.07
0.83 - 1.32
0.95
Potassium, %
1.50
1.09 - 1.91
1.4
Calcium, %
0.14
0.00 - 0.36
0.07
Magnesium, %
0.42
0.32 - 0.53
0.4
Sodium, %
0.29
0.02 - 0.55
0.25
Sulfur, %
0.53
0.33 - 0.73
0.47
Copper, ppm
6.6
0.0 - 23.7
7.0
a Dry matter (moisture free) basis.
b Dairy One Forage Laboratory accumulated data 5/21/200 - 4/30/2007 accessed Feb. 25, 2008.(Please note that energy value given (TDN and NE) tend to be lower, about 10% lower, than from other labs).
c National Research Council.
d Neural detergent fiber.
e Acid detergent fiber.
f Total digestible nutrients.
g Net energy for gain.
h Net energy for maintenance.
Footnotes
1. This document is AN201, one of a series of the Department of Animal Sciences, Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida. Visit the EDIS Web Site. Published: April 2008.
2. Bob Myer, Professor, North Florida Research and Education Center, Marianna, FL and Matt Hersom, Assistant Professor, Department of Animal Sciences, Cooperative Extension Service, UF/IFAS, Gainesville, FL 32611.