What is in this article?:
- Feeds For Cattle And Sheep
- Source of table information
Source of table information
Several sources of information were used in arriving at the typical values shown in this table. Where information wasn’t available, but a reasonable estimate could be made from similar feeds or stage of maturity, this was done; after all, it’s not very helpful to have a table with considerable missing information. Where zeros appear, the amount of that item is so small that it can be considered insignificant in practical diet formulation. Blanks indicate an unknown value.
Using the table information
Feed names: The most obvious or commonly used feed names are used in the table. Feeds designated as “fresh” are feeds that are grazed or fed as fresh-cut materials.
Dry matter: Typical dry matter (DM) values are shown, but the moisture content of feeds can vary greatly. Thus, DM content can be the biggest reason for variation in feed composition on an “as-fed basis.” For this reason, chemical constituents and biological attributes of feeds in the table are on a DM basis.
Since DM can vary greatly and one of the factors regulating total feed intake is the DM content of feeds, diet formulation on a DM basis is preferred rather than using “as-fed” values. If one wants to convert a value to an “as-fed basis,” multiply the decimal equivalent of the DM content times the compositional value shown in the table.
Energy: The table lists four measures of the energy value of feeds. Total digestible nutrients (TDN) is shown because there are more determined TDN values and it’s been the standard system for expressing the energy value of feeds for cattle and sheep.
There are several technical problems with TDN, however. For one, the digestibility of crude fiber (CF) may be higher than for nitrogen-free extract (NFE) in certain feeds due to the partition of lignin in the CF analysis. TDN also overestimates the energy value of roughages compared to concentrates in producing animals. Some argue that since energy isn’t measured in pounds or percent, TDN isn’t a valid energy measure. This, however, is more a scientific argument than a criticism of TDN’s predictive value.
Digestible energy (DE) values aren’t included in the table. There’s a fairly constant relationship between TDN and DE in cattle and sheep; DE (Mcal/cwt.) can be calculated by multiplying the %TDN content by 2. The ability of TDN and DE to predict animal performance is therefore the same.
Interest in using net energy (NE) in feed evaluation was renewed with the development of the California Net Energy System. This is due to the improved predictability of the productive response of animals depending on whether feed energy is being used for maintenance (NEm), growth (NEg), or lactation (NEl).
The major problem in using these NE values is predicting feed intake and thus the proportion of feed that will be used for maintenance and production. Some only use NEg but this suffers the equal, but opposite, criticism mentioned for TDN; NEg will overestimate the feeding value of concentrates relative to roughages.
The average of the two NE values can be used, but this would be true only for cattle and sheep eating twice their maintenance energy requirement. The most accurate way to use these NE values to formulate diets is to use the NEm value plus a multiplier times the NEg value all divided by one plus the multiplier. The multiplier is the level of feed intake relative to maintenance. For example, if 700-lb. cattle are expected to eat 18 lbs. of DM, 8 lbs. of which will be required for maintenance, the diet’s NE value would be: NE = [NEm + (10/8)(NEg)]/[1 + (10/8)].
In deciding the energy system to use, there’s no question on NE’s theoretical superiority over TDN in predicting animal performance. But this superiority is lost if only NEg is used to formulate diets. If NE is used, some combination of NEm and NEg is more accurate. NEl values are also shown but few have actually been determined. NEl values are similar to NEm values except for very high and low energy feeds.
Protein: Crude protein (CP) values are shown, which are Kjeldahl nitrogen times 100/16 or 6.25, since proteins contain an average of 16% nitrogen. CP doesn’t give any information about the actual protein and non-protein nitrogen (NPN) content of a feed.
Digestible protein (DP) isn’t included in these tables, as the contribution of microbial and body protein to the protein in feces makes it more misleading than CP. However, one can estimate DP from the CP content of the diet fed to cattle or sheep by the following equation: %DP = 0.9(%CP) – 3 where %DP and %CP are the diet values on a DM basis.
Undegradable intake protein (UIP, rumen “by-pass” or escape protein) values are shown. This value represents the percent of the CP passing through the rumen without degradation by rumen microorganisms. Degradable intake protein (DIP) is the percent of the CP degraded in the rumen and is equal to 100 minus UIP. Like other biological attributes, these values aren’t constant. UIP values on many feeds haven’t been determined and reasonable estimates are difficult to make.
How should these values be used to improve the predictability of animal performance when fed various feeds? Generally, DIP can supply CP up to 7% of the diet. If the required CP in the diet exceeds 7% of the DM, all CP above this amount should be UIP. In other words, if the final diet is to contain 13% CP, 6 of the 13 percentage units, or 46% of the CP, should be UIP.
Once the relationship between UIP and DIP has been better quantified, CP requirements may be lowered, especially at higher CP levels. For diets high in rumen fermentable carbohydrate, DIP requirements may determine the total CP required in the diet.
Crude, acid detergent and neutral detergent fiber: Crude fiber (CF) is declining in use as a measure of poorly digested carbohydrates in feeds. CF’s major problem is that variable amounts of lignin, which isn’t digestible, are removed in the CF procedure. In the old scheme, the remaining carbohydrates (nitrogen-free extract or NFE) were thought to be more digestible than CF despite many feeds having higher CF digestibility than NFE. One reason CF remained in the analytical scheme was its apparent requirement for the TDN calculation.
Improved analytical procedures for fiber have been developed, namely acid detergent fiber (ADF) and neutral detergent fiber (NDF). ADF is related to feed digestibility and NDF is somewhat related to voluntary intake and the availability of net energy. Both measures relate more directly to predicted animal performance and thus are more valuable than CF. Lignification of NDF alters the availability of the surface area to fiber-digesting rumen microorganisms.
Recently, effective NDF (eNDF) has been used to better describe the dietary fiber function in high-concentrate, feedlot-type diets. While eNDF is defined as the percent of NDF retained on a screen similar in size to particles that will pass from the rumen, this value is further modified based on feed density and degree of hydration. Rumen pH is correlated with dietary eNDF when diets contain less than 26% eNDF. Thus, when formulating high-concentrate diets, including eNDF may help to prevent acidosis in the rumen.
In feedlot diets, the recommended eNDF levels range from 5-20% depending on bunk management, inclusion of ionophores, digestion of NDF and/or microbial protein synthesis in the rumen. Estimated eNDF values are shown for many feeds. These should be decreased depending on degree of feed processing (e.g., chopping, grinding, pelleting, flaking) and hydration (fresh forage, silages, high moisture grains) if these feed forms are not specified in the table.
Ether extract: Ether extract (EE) shows the crude fat content of the feed.
Minerals: Values are shown for only certain minerals. Calcium (Ca) and phosphorus (P) are important minerals to consider in most feeding situations. Potassium (K) is more important as the concentrate level increases and when NPN is substituted for intact protein in the diet.
Sulfur (S) also becomes more important as the NPN level increases in the diet. High dietary S levels compounded by high S levels in drinking water, however, can be detrimental. Zinc (Zn) is shown because it’s less variable and is more generally near a deficient level in cattle and sheep diets. Chlorine (Cl) is of increasing interest for its role in dietary acid-base relationships.
The mineral level in the soil on which feeds are grown or other environmental factors preclude showing a single value for many of the trace minerals in feeds. Iodine and selenium are required nutrients deficient in many diets, yet their level in a feed is more related to the conditions under which the feed is grown than a characteristic of the feed itself. Trace mineralized salt and trace mineral premixes are generally used to supplement trace minerals; their use is encouraged where deficiencies exist.
Vitamins: Vitamins are not included in the table. The only vitamin of general practical importance in cattle and sheep feeding is the vitamin A value (vitamin A and carotene) in feeds. This depends largely on maturity and conditions at harvest, and the length and conditions during storage. Thus, it’s probably unwise to rely entirely on harvested feeds as a source of vitamin A value.
When roughages are fed that contain good green color or are being fed as immature, fresh forages (e.g., pasture), there will probably be sufficient vitamin A value to meet animal requirements. Other vitamins, if required, should be supplied as supplements.
Future table revisions
A feed composition table is of value only if it’s relatively complete, contains feeds commonly fed and the data are constantly updated. I welcome suggestions and compositional data to keep this table useful to the cattle and sheep industry.
When sending compositional data, adequately describe the feed, indicate the DM or moisture content and if the analytical values are on an as-fed or DM basis. If more than one sample was analyzed, the number of samples analyzed should be indicated. Send them to Rodney Preston, 1495 E. Village Lane #B, Bellingham, WA 98226-8017.
Rodney Preston is an emeritus professor from Texas Tech University, where he was a Horn Distinguished Professor and held the Thornton Endowed Chair. He was a member of the NRC Committee on Animal Nutrition and president of the American Society of Animal Science.