Managing and Feeding Beef Cows Using Body Condition Scores
Clay P. Mathis, Extension Livestock Specialist
Jason E. Sawyer, Extension Livestock Specialist
Ron Parker, Department Head, Department of Extension Animal Resources
College of Agriculture, Consumer and Environmental Sciences New Mexico State University. (Print Freindly PDF)
One of the greatest challenges facing cow-calf producers is maintaining a defined and short calving season. Maintaining a short calving season gives producers the ability to strategically manage their cow herd and to market uniformly aged calves at weaning. Strategic management includes a goal-oriented, low-cost nutrition program designed to meet the specific needs of all cows at the same time. With a short calving season, the cows are all in a similar production stage (lactation, gestation, etc.) at a given time during the production year. This makes developing a targeted nutrition program much easier and more efficient. Nutrient supplementation typically is the producer’s largest variable cost and is highly influenced by the environment. During periods of drought or excessive snow cover, or when low-quality forage cannot meet nutritional needs, beef producers must intervene by providing additional feed, leasing extra pasture, or selling a portion of the cow herd to maintain balance with the range resource and meet production goals. Intervention of this nature is expensive and, therefore, must generate a positive return on the investment.
A cow’s reproductive performance is closely associated with her body energy reserves. To help the beef industry communicate information relating animal performance to a cow’s degree of body energy reserves, a numerical body condition scoring (BCS) system was developed. Understanding this scoring system provides producers with a tool to develop and monitor their cow herd management program. This publication describes the BCS system, the influence of energy reserves on reproductive performance, and some ways to apply the system to developing an efficient management strategy.
The Body Condition Scoring System
Body condition scores are numbers that indicate a cow’s relative fatness, or body energy reserves. The system most commonly used for beef cows is a scale from 1 to 9, with 1 being severely emaciated and 9 extremely obese. Thus, a cow with a BCS of 5 is considered to be neither lean or fat.
Body fat is the most visible indicator of body energy reserves, since excess energy is stored as fat. Therefore, many of the BCS system’s points are based on the fat depth over certain areas of the cow’s body. The degree of fat cover over bony structures is easily seen. However, differences in BCS among thin cows (BCS 1 to 4) primarily result from variations in energy stored in the muscles. The criteria used in the BCS system are described in tables 1 and 2. Fig. 1 illustrates key areas of the cow’s body to evaluate when assigning BCS. Fig. 2 depicts a cross-sectional view of a cow’s back, showing the relationship of the spinous process, musculature, and fat cover. It is important to have a clear understanding of the cow’s anatomy to accurately evaluate body condition.
Table 1. Description of the body condition scoring system.
|1||Severely emaciated. All ribs and bone structure easily visible
and physically weak. Animal has difficulty standing or
walking. No external fat present by sight or touch.
|2||Emaciated. Similar to 1, but not weakened.|
|3||Very thin. No visible fat on the ribs or brisket. Individual
muscles in the hindquarters are easily visible and spinous
processes are very apparent.
|4||Thin. Ribs and pin bones are easily visible, and fat is not
apparent by palpation of ribs or pin bones. Individual muscles
in the hindquarters are apparent.
|5||Ribs are less apparent than in 4, and there is less than 0.2
inches of fat over the ribeye. Last two or three ribs can be felt
easily. No fat in the brisket. At least 0.4 inches of fat can be
palpated over pin bones. Individual muscles in the
hindquarters are not apparent.
|6||Smooth appearance throughout. Some fat deposition in the
brisket. Individual ribs are not visible. About 0.4 inches of fat
on the pin bones and on the last two or three ribs.
|7||Brisket is full. Tail head and pin bones have protruding fat
deposits on them. Back appears square due to fat. Indentation
over the spine due to fat on each side. Between 0.4 and 0.8
inches of fat on the last two to three ribs.
|8||Obese. Back is very square. Brisket is distended with fat.
Large protruding deposits of fat on tail head and pin bones.
Neck is thick. Between 1.2 and 1.8 inches of fat on the last
three ribs. Large indentation over the spine.
|9||Very obese. Description similar to 8, but taken to a greater
Table 2. Key points for condition scoring beef cows.
|Outline of spine visible||Yes||Yes||Yes||Slight||No||No||No||No||No|
|Outline of ribs visible||All||All||All||3 to 5||1 to 2||0||0||0||0|
|Fat in brisket and flanks||No||No||No||No||No||Some||Full||Full||Extreme|
|Outline of hip and pin bones visible||Yes||Yes||Yes||Yes||Yes||Yes||Slight||No||No|
|Fat udder and patchy fat around tailhead||No||No||No||No||No||No||No||Slight||Yes|
|Backfat estimates, inches||0||0||.05||.11||.19||.29||.41||.54||.68|
|aMuscle of loin, rump, and hindquarters are concave, indicating muscle tissue loss.|
Figure 1. Key points for body condition scoring: 1. back; 2. tail head; 3. pins; 4. hooks; 5. ribs; 6. brisket.
Figure 2. Cross-sectional view of a cow’s back.
Figs. 3-9 show cows in BCS 2–8. The white-faced cow is shown in BCS 2, 3, 5, 6, and 7, while the solid red cow is shown in BCS 4–7. On average, a 1-point increment in BCS is equal to about 80 pounds of body weight. This varies somewhat based on the cow’s frame size.
Figure 3. BCS 2: Ribs and bone structure easily visible, but no signs of physical weakness.
Figure 4. BCS 3: Very thin. No visible fat is on the ribs or brisket. Individual muscles in the hindquarters are easily visible and spinous processes are very apparent.
Figure 5. BCS 4: Thin. Ribs and pin bones are easily visible, and fat over the ribs is not apparent. Two to five ribs are visible. Individual muscles in the hindquarters are apparent.
Figure 6. BCS 5: Ribs are less apparent than in 4, and there is less than 0.2 inches of fat over the ribeye. Last one or two ribs may be apparent. No fat is present in the brisket. Individual muscles in the hindquarters are not apparent
Figure 7. BCS 6: Appearance is smooth throughout. Some fat deposition is apparent in the brisket. Individual ribs are not visible.
Figure 8. BCS 7: Brisket is full. Tail head and pin bones have protruding deposits of fat on them. Back appears square due to fat. There is indentation over the spine due to fat on each side. Between 0.4 and 0.8 inches of fat covers the last two to three ribs.
Figure 9. BCS 8: Obese. Back is very square. Brisket is distended with fat. Large protruding deposits of fat are on tail head and pin bones. Neck is thick. Between 1.2 and 1.8 inches of fat covers the last three ribs. Large indentation over the spine is present.
|Photos by Clay Mathis.|
Influence of Energy Reserves on Reproduction
The relationship between reproductive success and body condition at calving is based on energy. Cows must have energy to support all bodily activities, but some functions have a higher priority for energy use than others. Table 3 shows the approximate “priority list” by which energy consumed by the cow is partitioned to different bodily functions.
Table 3. Priority of energy use by the cow.
|2||Grazing and other physical activities|
|4||Supporting basic energy reserves|
|5||Maintaining an existing pregnancy|
|7||Adding to energy reserves|
|8||Estrous cycling and initiating pregnancy|
|9||Storing excess energy|
|Short et al., 1990|
From this table, it is apparent that energy required to initiate cycling after calving is only available if the cow’s diet contains enough energy to exceed the requirements for priorities one through seven. A lactating cow’s energy demand can be very high. It is important that the cow has adequate body condition at calving, so that she has stored energy that can be used to meet her energy requirements. If she does not have enough stored energy at calving, she must gain weight during lactation so that she will have enough energy left over to begin cycling again. This can be difficult to achieve, especially with high milk-producing cows.
Body condition score at calving typically is the most important factor influencing the length of the postpartum anestrous period (time between calving and first heat) and pregnancy rate in beef cattle. In general, as body condition at calving decreases, the length of the postpartum anestrous period increases. Thus, the number of cows in heat early in the breeding season is reduced. Subsequently, calf age and weight at weaning is reduced.
Figs. 10 and 11 show the relationship between BCS at calving and the length of the postpartum anestrous period. Clearly, fleshier cows have a better chance of becoming pregnant and calving on or before the same day the following year. It may not be economical or desirable to keep cows in a BCS of 7 to 9. However, these findings illustrate the advantage heavier conditioned females have to become pregnant and deliver a calf early the following calving season. A cow’s gestation period averages 283 days, thus the cow has 82 days to become pregnant and maintain a calving cycle of 365 days or less. Based on fig. 12, BCS 3 cows have little chance of maintaining a 365-day calving interval. BCS 4 cows averaged only one heat cycle to become pregnant and maintain a 365-day calving interval. Yet cows of BCS 5 or greater averaged two or more heat cycles to potentially conceive and still produce a calf on or before the same date the following year.
Figure 10. Effects of body condition at calving on postpartum duration. (Adapted from Houghton, 1990.)
Figure 11. Effects of body condition score at calving on percentage of cows cycling by 60 and 90 days postpartum. (Adapted from Whitman, 1975.)
Figure 12. Relative energy requirements of a springcalving beef cow.
Fig. 11 shows the influence of BCS at calving on postpartum anestrous period with a slightly different categorical approach. It shows the portion of cows cycling by 60 and 90 days after calving. The most important information in this figure is that 92 percent of the BCS 5 and 6 cows showed heat within 90 days of calving, whereas only 66 percent of the BCS 4 or less cows exhibited heat by that time.
Body condition at weaning also is related to reproductive performance. A nine-year summary of data from more than 77,000 cows (table 4) clearly shows that cows that are thin at weaning are less likely to become pregnant during the following breeding season.
Table 4. Relationship of body condition score at weaning and pregnancy ratea.
|Body Condition Score|
|3 or less||4||5||6||7 or more|
|Number of cows||3,415||23,811||379,740||26,213||9,654|
|aBowman and Sowell, 1998.|
Developing a Body Condition Target
Since body condition is associated with reproductive success, the BCS system can be used to set a predictable target. It is important to strive for a BCS at calving that will allow for cows to be reproductively efficient. This target BCS may not be the same for all operations, although scientific findings indicate that a cow calving in BCS 5 is a low-risk target. However, it may be beneficial to target a slightly higher BCS of 5.5 to 6 for first-calf heifers to compensate for the larger energy demands of continued growth during her first lactation.
When determining a BCS target as a management goal, the concept of “risk and reward” must be considered. A supplementing strategy designed to achieve a BCS of 5 may be more expensive than one designed to achieve a BCS of 4 or 4.5. Cows in BCS 4 may have only one chance to become pregnant in time to maintain a 365-day calving interval, while those with BCS 5 may have two or more chances. If all cows conceived at first service, the thinner cows might be more economical. Research conducted in Nebraska indicated that while cows with a BCS of 5 or greater had the highest pregnancy rates, cows with a BCS between 4 and 5, specifically an average of BCS 4.3 achieved the highest net returns (Ferrell and Jenkins, 1996). This was due, in part, to the reduced amount of feed required to maintain the cows in lesser body conditions. However, since a cow with a marginal BCS of 4.5 or less does not have far to fall to be highly unproductive, additional body condition can be considered insurance. Individual managers must evaluate their tolerance for risk in making this decision.
Grouping the Cow Herd Using Body Condition Scores
One of the keys to using BCS to manage reproductive performance successfully is having the capability to sort and supplement cows relative to a target BCS. For example, cows could be sorted into two groups—those at or above the target BCS that need no special management, and those below the target that need additional nutrients to improve their chances of becoming pregnant early in the breeding season. Further sorting of cows that are below the targeted BCS into two or more groups also may improve the precision of the nutrition program. The degree of sorting depends on the availability of facilities and pastures to accommodate the different cow groups. When possible, it may be beneficial to move cows between groups as needed.
Grouping cattle according to BCS allows producers to manage the nutrition program strategically, targeting nutrients to cows that are least likely to become pregnant early in the breeding season (below target BCS). The objective is to group the thin cattle together and provide supplemental feed (grazed or fed) sufficient to meet production goals, without pouring unneeded feed and dollars into cows that are already in acceptable condition.
When is the Best Time to Determine BCS and Sort Cows?
The most reasonable opportunities to determine BCS and sort cows are at weaning (generally in the fall), one to two months prior to calving, or at calving. The advantages and disadvantages of each will be discussed relative to a spring-calving cow herd.
Sorting at Weaning. Sorting cattle by BCS at fall weaning may be the best choice. A cow’s energy requirements are the lowest directly after weaning, because she is no longer lactating and requirements for fetal development are still relatively low (fig. 12). Additionally, as a cow “dries up” because her calf is no longer nursing, she maintains some advantage in the efficiency of converting ingested feed into energy reserves. This small window of opportunity generally is the most economical physiological stage for increasing body energy reserves.
Under most New Mexico range conditions, a nonlactating cow that consumes only dormant forage plus protein supplement will lose 40 to 80 pounds (.5 to 1 BCS) during the winter grazing season. Logically, the most economical approach to increasing body condition of thin cows is with the least possible input of energy feeds. Forage quality on rangelands declines during winter months. Also, a cow’s energy needs are at the lowest immediately after weaning. Therefore, typically the most economical time to add body condition to thin cows is immediately following weaning. Group thin cows that are less likely to become pregnant during the following breeding season and feed them to achieve at least BCS of 5, during this “window of opportunity” following weaning (See the later section, “Feeding to Increase BCS,” for potential feeding techniques).
Sorting Prior to Calving. Creating BCS groups prior to calving may be another viable management strategy. If cows are sorted 60 to 90 days before the expected calving season begins, thinner cows can be manipulated to still meet targeted BCS by their calving date. However, this may require intensive inputs, since forage quality often is at the lowest during the late winter, and the cow’s nutritional requirements are increasing to support the developing calf. The efficiency of gain usually is lower during this period than the period directly following weaning. It should be noted that it takes approximately 40 to 55 days to increase BCS by 1 unit, when cows are gaining 1.5 to 2.0 pounds of nonfetal weight per day. Large gains in BCS may not be feasible at this time. This period allows producers to maintain some flexibility and to take advantage of any favorable environmental conditions. However, it may carry slightly more risk than sorting at weaning in the fall and ensuring that cows are in acceptable body condition prior to the winter grazing season.
Table 5 shows that providing a higher energy level before calving can impact the length of the postpartum anestrous period and potential age and weight of the following calf crop at weaning. However, it is important to note that both precalving nutrition levels yielded a postpartum anestrous period of less than 82 days. Cows fed the higher energy level before calving had two chances to become pregnant and maintain a 365-day calving interval, whereas cows in the low energy group only had one chance. As with any input, the relationship of cost to return should be evaluated. An effort to maintain a high energy level for an extended period of time before calving should be limited to cows that are exceptionally thin and at high risk of calving too late or being open at the end of the breeding season.
Table 5. Influence of high and low energy diets fed for 90 days precalving on length of the postpartum anestrous period in beef cows.
|Precalving Diet||Postpartum Anestrous Duration|
|aHigh = 14.1 pounds of total digestible nutrients / day
bLow = 7.1 pounds of total digestible nutrients / day
|Adapted from Bellows and Short, 1978.|
Sorting at Calving. Achieving the target BCS by calving is important, and evaluating cows at calving does not allow any catch-up time to reach the BCS target. However, sorting at calving does provide producers with the opportunity to place cows into groups that need special attention because they failed to meet the targeted calving BCS. Producers can manage cows that are thin at calving to improve the chances of meeting reproduction goals. However, sorting at calving should be used primarily to take care of cows that have slipped through the cracks at other evaluation periods, are too thin, and have a high probability of being open at the end of the breeding season. Researchers have demonstrated that cows that are thin at calving, but fed a higher level of energy after calving still can achieve acceptable reproductive rates. Additional research has demonstrated that postcalving nutrition can impact performance of first-calf heifers (table 6). In general, it is better for a thin cow to gain weight after calving than for a well-conditioned cow to lose large amounts of weight between calving and breeding (table 7). Nevertheless, it still is more desirable for all cows to be in the targeted BCS range at calving than to sort off and feed thin cows extra, while they are nursing calves.
Table 6. Influence of high, medium, and low energy intake levels by beef heifers after calving on pregnancy rate at 120 days postcalving.
|Postcalving Energy Intake||Pregnancy Rate, %|
|aHigh = 24.1 pounds of total digestible nutrients/day
bMedium = 13.7 pounds of total digestible nutrients/day
cLow = 7.1 pounds of total digestible nutrients/day
|Adapted from Dunn et al., 1969.|
Table 7. Influence of postcalving body condition gain on pregnancy rate.
|BCS 90 Days
|aHigh = 16 pounds of total digestible nutrients/day
bLow = 8 pounds of total digestible nutrients/day
|Adapted from Wiltbank et al, 1962.|
Feeding to Increase BCS
Developing a cost-effective feeding program depends greatly on local hay prices and/or the availability and price of other industries’ by-products that can be used as inexpensive energy sources. Nonetheless, feeding thin cows to increase their body condition does not have to be a complicated task. It may be practical to group thin cows after weaning and graze them in the best quality pasture saved for this purpose. In less extensive cattle operations, it has been successful to move cows to new pastures when they calve. However, in a relatively dry climate where forage supply often is limited, this technique caters to early calving females that have the greatest opportunity to select a high-quality diet, because they graze the new pasture first. Subsequently, the later calving females receive less benefit.
In general, it takes three weeks to one month to increase a nonlactating thin cow by 1 BCS, when the cow is fed all the medium quality hay she can eat (25-35 pounds of hay/day) in a small trap or drylot. Hay is not the only feedstuff that can produce the necessary weight gains, but it generally is one of the more readily available commodities. By-product feeds can be fed in the same manner as long as the diet is balanced and does not cause digestive upset. When available, grazing harvested corn and grain sorghum fields also may work well at a relatively low cost. When comparing potential energy sources, it is important to price by-products according to the energy they will provide to the cow ($/pound of total digestible nutrients: TDN).
The BCS system was created to help the cattle industry relate beef cow energy reserves to performance. Producers can use the system to identify critical energy reserve levels, primarily related to reproductive performance. Body condition at calving generally is the best indicator of the potential length of the postpartum anestrous period. A conservative target for cows at calving is BCS 5. However, every beef operation is different, and producers using BCS as a tool should set BCS targets based on their willingness to assume risk. It probably is most effective to sort out thin cows at weaning and provide them with additional energy directly after weaning when their requirements are low.
Bellows, R. A., and R. E. Short. 1978. Effects of precalving feed level on birth weight, calving difficulty and subsequent fertility. J. Anim. Sci. 46:1522-1528.
Bowman, J, and B. Sowell. 1998. Feeding the beef cow herd. In: Kellems, R. O., and D. C. Church (Ed.) Livestock Feeds and Feeding (4th Ed.). p 243. Prentice-Hall, Upper Saddle River, N.J.
Dunn, T. G., J. E. Ingalls, D. R. Zimmerman, and J. N. Wiltbank. 1969. Reproductive performance of 2-year-old Hereford and Angus heifers as induced by pre- and postcalving energy intake. J. Anim. Sci. 29:719-726.
Ferrell, C. L., and T. G. Jenkins. 1996. Influence of body condition on productivity of cows. J. Anim. Sci. 74 (Suppl. 1):36(Abstr.).
Houghton, P. L., R. P. Lemenager, L. A. Horstman, K. S. Kendrix, and G. E. Moss. 1990. Effects of body composition, pre- and postpartum energy level and early weaning on reproductive performance of beef cows and preweaning calf gain. J. Anim. Sci. 68:1438-1446.
Momont, P. A., and R. J. Pruitt. 1998. Condition scoring of beef cattle. Cow-Calf Management Guide and Cattle Producers’ Library. CL-720.
Short, R. E., R. A. Bellows, R. B. Staigmiller, J. G. Berardinelli, and E. E. Custer. 1990. Physiological mechanisms controlling anestrus and infertility in postpartum beef cattle. J. Anim. Sci. 68:799-816.
Whitman, R. W. 1975. Weight change, body condition, and beef cow reproduction. Ph.D. Dissertation. Colorado State University, Fort Collins, CO.
Wiltbank, J. N., W. W. Rowden, J. E. Ingalls, K. E. Gregory, and R. M. Koch. 1962. Effect of energy level on reproductive phenomena of mature Hereford cows. J. Anim. Sci. 22:219-225.
To find more resources for your business, home, or family, visit the College of Agricultural, Consumer and Environmental Sciences on the World Wide Web at aces.nmsu.edu.
Contents of publications may be freely reproduced for educational purposes. All other rights reserved. For permission to use publications for other purposes, contact email@example.com or the authors listed on the publication.
New Mexico State University is an equal opportunity/affirmative action employer and educator. NMSU and the U.S. Department of Agriculture cooperating.
Reprinted and electronically distributed November 2002, Las Cruces, NM.