FINISHING CULL DAIRY COWS FOR BEEF PRODUCTION Project No. 7278 English Beef and Lamb Executive (EBLEX) HCC (Meat Promotion Wales) QMS (Quality Meat Scotland) Conducted by The Animal Science Research Group (ASRG) Department of Agriculture Earley Gate, University of Reading READING RG6 6AJ, United Kingdom. Report Authors D. T. Juniper, P.C. Aikman, C. Green, and R. H. Phipps Report No. 243 August 2006 Contents Executive summary INTRODUCTION MATERIALS AND METHODS Dietary treatments Animals and experimental design Animal management Animal performance measurements Slaughter Statistical analysis Ration composition Animal performance 3.2.1 Animal health 3.2.2 Nutrient intake 3.2.3 Physical performance 3.2.4 Carcass characteristics 3.2.5 Financial evaluation DISCUSSION CONCLUSION APPENDIX Executive Summary
1. A study to determine performance benchmarks of modern dairy cull cows fed
autumn/winter forage-based feeding systems was undertaken at the Animal
Production Research Unit, Centre for Dairy Research (CEDAR), The
2. A total of 24 cull cows (equal numbers of Holstein Friesian and Friesians)
born between November 1996 and November 2003 were enrolled onto the
study having met predetermined health criteria.
3. The study was of a randomised complete block design. At enrolment animals
were weighed and condition scored and subsequently blocked by breed, live
weight and condition score and randomly allocated to one of three dietary
treatments, namely grass silage only (G), grass silage plus 3 kg cracked wheat
(GW) or maize silage total mixed ration (M) which consisted of maize silage
and a small supplement of soyabean and rapeseed meal to produced a 12%
4. Animals received their respective diets individually through Calan Broadbent
electronic gates throughout the duration of the study (63 days). Diets were
offered fresh daily following the removal of the previous days feed. Feed was
offered ad-libitum with refusals maintained at approximately 100g/kg intake).
5. Live weight was recorded on two consecutive days at the start of the study,
weekly throughout the study period and on two consecutive days prior to
slaughter. Body condition scoring was performed weekly at the same time as
weighing by the same personnel throughout the study.
6. With the exception of three animals all other cattle remained healthy and
completed the study. Of the three animals that were treated, two were
removed from the gated area due to chronic lameness (diet G) and the third
7. Dry matter intakes were significantly (P < 0.001) greater in diet M. Similarly
rates of gain were higher in diet M (P = 0.085) when compared to diets G and
GW. However, although feed conversion efficiency was numerically better in
diet M it failed to reach statistical significance
8. There was no effect of dietary treatment on either body condition score or
change in body condition score, although on average animals gained 0.4 of a
condition score. Similarly there were no effects of dietary treatment on
carcass characteristics, all animals having similar carcass weights, killing out
percentages, fat and conformation scores.
9. Overall feed costs were greater than actual net gains in carcass value resulting
in net losses per head of £8.71, £26.35 and £21.78 for diets G, GW and M,
10. Based on calculations that removed the effect of carcase conformation on
carcase value (which was not effected by treatment but differed considerably
due to animal genetics) feed costs exceeded the net increase in carcase value
by £17.47, £21.69 and £4.64 per head for diets, G, GM and M, respectively.
Farmer Summary
Holstein Friesian dairy cows were dried off and feed for a period of 9 weeks
on one of 3 dietary treatments whilst housed in cubicles and bedded on
TMR of maize silage : soyabean meal : rapeseed meal (91:4.8:4.2
Diet composition in terms of crude protein ranged between 12-14.5% (M-
GW). Starch intake increased from 0 for diet G to 4.1 kg/d for diet M.
Dry matter intakes, subsequent growth rates and rates of feed conversion
efficiency were highest with the maize silage TMR and lowest in the grass
Mean growth rates for diet G were 0.20 kg/d. Growth rates for diets GW and
M were 0.66 and 1.25 kg/day. Respective feed conversion efficiencies were,
25.4, 11.5, 7.4 kg of DM intake required to gain 1 kg of live weight.
Animals on average, and irrespective of diet, gained 0.4 of a body condition
score, theoretically improving EUROP fat class by one point from 3 to 4L.
There were no differences in killing-out percentages nor carcase fatness, with
carcase weights increasing from 330 kg for diet G to 328 kg for diet GW and
Based on current feed and cull cow prices all three systems resulted in net
financial losses (increase in carcass value – feed costs). Feed costs of £3.97,
£2.12 and £0.85 per kg of live weight produced were recorded for diets G,
GW and M, respectively. The prevailing market value for these cows was
considerably lower than any of these feed costs at approximately £0.52/kg
liveweight. Losses of between approximately £5 and £22 per head were
calculated (increase in carcase value – feed costs).
Given the relatively high breakeven cull cow price required to cover feed
costs, selection criteria for dairy cows intended for finishing needs careful
consideration. A number of factors such body condition at culling, reason for
culling, age, health status etc, may have a significant bearing on how well
these animals perform and the subsequent financial outcome.
Both cull cow prices and feed costs are highly variable and may vary from
farm to farm. Therefore individual farmers need to assess whether their feed
costs and opportunities for finishing of cull dairy cows is financially viable.
1. INTRODUCTION
As a result of the closure of the over thirty month scheme on 7 November 2005 about
635,000 cull cows from dairy and suckler herds will be eligible to enter the beef
supply chain. A report entitled Finishing Cull Suckler and Dairy Cows for Beef
Production was commissioned in 2004 by the Meat and Livestock Commission. The
lack of available data on this topic is emphasised in the report as only 14 scientific
papers, summaries or other reports could be found in the literature. The report noted
that while cull cows could be finished off pasture during spring and summer, there
were three main systems based on grass silage, maize silage or concentrate for cull
cows being finished in the autumn and winter. It was recognised that forage based
systems would be more widely used due to the higher cost of concentrates. While the
report outlined a number of future research and development areas it highlights the
lack of available information on feed intakes and live weight gain of modern dairy
cull cows in the UK. Applied research studies are needed to establish industry
performance benchmarks for beef produced under UK conditions from this class of
The objectives of this study were to determine performance benchmarks of the
modern dairy cull cow fed on autumn/winter forage-based feeding systems.
MATERIALS AND METHODS 2.1 Dietary treatments
The three diets used in this study comprised either grass silage as the sole feed (G),
grass silage plus 3kg cracked wheat top dressed once daily (GW) or a maize silage
total mixed ration (M) [Table 1]. Maize and grass silages were sourced from the same
clamps throughout the study. Thorough mixing of diet M was performed using a
small self-propelled mixer wagon (Calan Super Data Ranger, American Calan Inc.,
USA), fitted with a weighing device (Weightronix Model 1015, Fairmount, USA)
which recorded the weight of forage and concentrate added to the hopper. Following
mixing the ration was transferred to an experimental feed wagon (CEDAR design)
fitted with an electronic weighing device (Digi-star E22000, Fort Atkinson, WI,
USA.) which recorded the weight of feed dispensed into the feed bin. Grass silage for
treatments G and GW was dispensed into feed bins using the same feeder wagon. A
mineral supplement of 80 g/head was top dressed onto all diets once daily. Uneaten
feed was removed daily prior to feeding and weighed to enable individual feed intake
Table 1 Component ingredients of maize silage total mixed ration (diet M) Animals and experimental design
The study comprised 24 Holstein-Friesian/Friesian cull cows (equal numbers of each
breed) born between November 1996 and November 2003, that were sourced from
both the CEDAR herd and off farm. Animals were housed in six pens, with each pen
containing four individually fed animals. Animals were blocked according to breed,
live weight and body condition score and then randomly allocated to one of the three
dietary treatments which they received for the 63 day duration of the study. Mean
start live weight was 494 ± 35.9 kg with mean body condition score 3.2 ± 1.7.
2.3 Animal management
Cows were foot trimmed and assessed for foot health upon arrival. Animals were
housed in groups of four animals in six yards that contained eight Calan Broadbent
electronic gates and eight cubicles fitted with rubber comfort mats covered with white
wood shavings. No other bedding substrate was available. Wet or soiled shavings
were removed and replenished daily. Feed and loafing passages were scraped once
Animals were trained to one gate within each yard prior to commencement of the
study and remained with the same gate throughout the course of the study. During the
period of gate training animals were offered a maize silage grass silage mixture
(50:50 FW). This ration was progressively changed so that animals were receiving
their respective experimental diets at commencement of the study. Data collected
within the first week was highly variable indicating that animals had not completely
adapted to the diets or feeding system. These data was subsequently disregarded and
Fresh potable water was available at all times throughout the study from mains fed
water tanks which were drained and cleaned regularly.
2.4 Animal performance measurements
Individual dry matter intake (DMI) was recorded on all cattle through electronic feed
gates, by weighing feed offered and refused on a daily basis. Forage was offered
twice daily ad libitum, maintaining refusals at approximately 100g/kg of daily intake.
Throughout the study live weight and body condition score (BCS) of the cattle was
recorded after feeding and rates of daily live weight gain (DLWG) and change in
body condition score calculated from these data. Cattle were weighed and condition
scored weekly, condition scoring was undertaken by the same person throughout the
study. Live weight was recorded on two consecutive days at the start of the
experiment and on the day prior to and day of transport to the abattoir. Feed
conversion efficiency (F.C.E) was calculated as the amount of DM required to
2.5 Slaughter
All cattle were transported to Guilford abattoir on 7th August 2006 and slaughtered on
8th August 2006. Cattle were slaughtered by captive bolt and exsanguination. All
carcasses were visually graded for conformation and external fat cover using two
classification scales; the European Carcass Classification Scheme and the 15-point
carcass classification scale. Fat and conformation scores were converted to numerical
values for statistical evaluation (DFAS, University of Bristol). Killing out percentages
were calculated as the proportion of cold carcass weight to final live weight.
Statistical analysis
Statistically significant differences between individual treatments for all experimental
variables were determined by analysis of variance using the GLM procedure (Minitab
V.14). The data set contained 24 observations and the model consisted of diet (2 d.f.)
and breed (1 d.f.) as sources of variation. Results are presented as LSM with the s.e.d.
Average DLWG for each individual animal were calculated by linear regression
yielding the equation y = mx + c. Statistical differences between treatments in
coefficients m of the resulting equations were determined by ANOVA using the GLM
3. RESULTS 3.1 Ration composition
Mean laboratory derived nutrient densities of component feed stuffs are shown in
Table 2. The grass silage used in this study was of moderate quality with mean D-
value of 650 g/kg with mean dry matter (DM), crude protein (CP) and estimated
metabolisable energy (ME) contents of 300 g/kg fresh weight (FW), 144 g/kg DM and
10.6 MJ/kg DM, respectively. The maize silage had a mean D-value of 680 g/kg with
mean DM, CP and estimated ME contents of 373 g/kg FW, 88 g/kg DM and 10.9
The concentrate used in the TMR had a mean CP content of 450 g/kg DM and was
initially formulated from book values to give a TMR CP content of 120 g/kg DM
when included in the TMR at a forage to concentrate ratio of approximately 9:1.
Subsequent laboratory analysis of the TMR gave a mean CP content of 117 ± 3.9 g/kg
Table 2 Laboratory determined nutritional values of ration components (g/kg DM 3.2 Animal performance
In the latter part of the study three animals were removed from the experiment. Two
of these were chronically lame (diet G) and was attributed to a possible joint or
tendon injury. These animals were removed from the gated area and placed into a
larger pen as it was considered that the kerbs either side of the feed and loafing
passages were aggravating the condition. The third animal (diet GW) had recurrent
mastitis which was treated with antibiotic and dry cow therapy. Again, this animal
was removed from the gated area so as to prevent further infection and to aid
recovery. These three animals were considered by veterinary surgeon as not fit to
travel to the abattoir for slaughter. All other animals remained healthy. Regular foot
bathing with zinc sulphate solution was undertaken as a precautionary measure in an
attempt to maintain foot health and control lameness resulting from microbial
Mean nutrient intakes based on average DMI and laboratory determined nutritional
composition of feeding stuffs are shown in Table 3. In general intakes of CP, ME,
starch, NDF and ash were all significantly (P < 0.005) greater in diet M than in diets
G and GW. The greater intakes of CP and NDF are the result of the significantly
higher DMI of cattle receiving diet M, since CP and NDF concentrations of diets G
and GW per unit DM were higher than those of diet M. The majority of the starch
consumed by diet M cattle comprised maize starch, as the concentrate blend used in
the TMR contained very little starch itself (Table 2). All of the starch consumed by
cattle receiving diet GW comprised wheat starch, which was derived from the 3kg of
cracked wheat that was top dressed daily.
Table 3 Mean daily nutrient intakes of finishing cull cows fed grass silage and maize
silage based finishing rations (kg/day unless otherwise stated).
Data pertaining to animal physical performance are shown in Table 4. There were no
differences between treatments in start weights or finish weights, although total
weights gains and DLWG, whether calculated from absolute values or estimated by
regression analysis, were highest in diet M when compared to the other two
treatments. Furthermore, although there was no treatment effects on FCE, values
were notably higher in diet G when compared to diets GW and M.
Table 4 Mean start weights, finish weights, total gains, DLWG, FCE and BCS of
finishing cull cows fed grass silage and maize silage based finishing rations
1 Absolute DLWG (Total weight gain/no. of days)
2 DLWG determined by regression analysis
There were no effects of dietary treatment on start and finish BCS or change in BCS,
all treatments on average gaining between 0.3 and 0.5 of a score. Similarly, there
were no effects of dietary treatment on the EBLEX live grade with values ranging
The relationship between daily ME intake and daily rates of live weight gain, with
respect to treatment, is shown in Figure 2. Extrapolation of the regression equation
indicates that at ME intakes lower than 85 MJ/day may result in net weight loss and
that additional ME intake above this would result in modest increases in live weight
Figure 1 Relationship between daily ME intake and daily rates of gain in cull cows
receiving grass silage and maize silage based finishing rations.
The relationship between total live weight gain and change in body condition score
(weighted by dietary treatment) can be expressed in the following equation:
Change in condition score = 1.86 – 0.471x + 0.00458y
In general, for each full point score above a BCS of 3 it would require an additional
100 kg of weight gain to achieve a one point shift in BCS. However, due to the
relatively good enrolment body condition of the cattle used in this study and the
subsequent lack of data pertaining to condition scores lower than score 3 it is not
possible to estimate weight gains required for one score shifts in animals with BCS
Data relating to carcass characteristics are shown in Table 5. Neither carcass weights
nor killing out percentages were influenced by dietary treatment. However, not all
cattle were dressed to the same specification as twelve animals were dressed to the
new EU specification whereas the remainder had additional external fat removed.
This was not balanced across treatments and it is likely that this may have influenced
killing out percentage and carcass weight. All cattle were slaughtered as commercial
cattle through a commercial abattoir and not under experimental conditions. MLC
staff had at the time pointed out the different dressing specifications but nothing could
Table 5 Carcass weights, killing out percentages, MLC conformation and fat scores
and 15 point fat and conformation scores of finishing cull cows fed grass silage and
MLC conformation 23.33 21.30 21.25 2.42 0.802
EUROP conformation scores; 10 = -P 20 = P+ 30 = -O 55 = O+ EUROP fat scores
All carcasses were graded for fat and conformation on the 15 point scale following the
removal of the hide but prior to any trimming of external fat. Fat and conformation
scores on the EUROP scale were conducted following fat trimming. There were no
effects of dietary treatment on fat scores or conformation scores. Conformation
scores, irrespective of treatment, were generally poor and corresponded to an MLC
conformation grade of P+ whereas fat cover was generally better with an average
The relationship between body condition scores of cattle recorded prior to dispatch to
the abattoir and the MLC and 15 point fat scores recorded following slaughter are
shown in Figure 2. Generally, in the context of this study, animals at enrolment had a
mean BCS of 3.2 which corresponded to an estimated MLC and 15 point fat score of
poor 3 and -3, respectively. The average post-mortem MLC fat score of 4L and 15
point fat score of -4 indicates a full one score shift in fat class irrespective of the fat
scoring system. However, there is a disparity between these two fat scoring systems
in the estimates of required changes in BCS to achieve the observed increases in fat
scores, with changes of 0.6 and 0.2 of one BCS for the MLC and 15 point scoring
systems, respectively, probably a result of the fat trimming which occurred prior to
carcass classification using the 15 point system.
Figure 2 Relationship between live body condition score and post-mortem MLC and
The financial consequences of this feeding trial have been evaluated in two ways:
1. Using regression of carcase data and value to estimate initial carcase value
accompanied with actual deadweight carcase returns to calculate the increase
2. Initial carcase value was estimated using a mean killing out percentage across
all treatments and assumed a carcase fatness classification of 3. The slaughter
carcase value was calculated using actual carcase weights multiplied by a
uniform carcase value that reflected the increase in fatness observed, i.e. it was
assumed that carcase fatness increased by 1 fat class during the feeding trial,
from 3 to 4L (as suggested by the increased body condition score recorded
The two different financial calculations described above were made because it
became apparent that the first calculation method was devaluing carcases on some
treatments more than others due to poor conformation classification. Estimating
carcase values at the start of the study was difficult because no carcase data were
available for cows starting the trial. Since the results of the study found no significant
differences between treatments on final carcase fatness, conformation or killing out
percentage it seemed reasonable to estimate carcase valuation changes using a
common carcase weight value across treatments. In calculation 2 this unit value was
the market value for P+3 carcases (£1.05 kg/dw) at the start of the trial and P+4L
Estimates of carcass values (using the two calculations above) and of feed costs
(CEDAR valuation prices) with respect to treatment are shown in Tables 6a and 6b,
Table 6a Financial evaluation using calculation 1 of different forage based feeding
systems for finishing cull dairy cows (£/head, unless otherwise stated).
Carcase value
Start carcase value † 352.1 340.5 338.1
Finishing Net Margin
† Estimates of pre-treatment carcass values are based on applying the same pricing system to the
conversion of initial BCS to an estimate of pre-treatment MLC fat score using the equation derived
from the regression analysis shown in Figure 1 and estimates of start carcass weights (KO% x start
Table 6b Financial evaluation using calculation 2 of different forage based feeding
systems for finishing cull dairy cows (£/head, unless otherwise stated).
Carcase value Finishing Net Margin
The increase in carcase valuation estimating using calculation method 1 does not
reflect the physical performance recorded during the study. For instance, for diet G
an increase in carcase value of £32 was calculated compared to £25 for diet GW, this
was despite liveweight gains for diet GW being twice those of diet G (24 kg
For this reason it was considered that calculation 2 offer a better estimate of carcase
value changes during the study given the information available. This calculation
estimated that the increase in value of carcases from diets G, GW and M were, £23,
£30 and £59, respectively. These results were a better reflection of the physical
performance of the cows on the trial and consequently these are the financial results
referred to in the executive and farmer summary and subsequently in this report.
Total feed costs were lowest in diet G increasing on average by £10 and £20 for diets
GW and M, respectively, although when expressed as a function of live weight gain
feed costs were considerably higher for diet G at 397 p/kg LW when compared to
costs of 212 and 85 p/kg LW for diets GW and M respectively. Feed costs were
higher than estimates of improvements in carcass values. Net losses per animal were
estimated to be £17.47, £21.69 and £4.64 for diets G, GW and M respectively.
4. DISCUSSION
Much of the data that currently exists pertaining to performance benchmarks of cull
dairy cows is dated, and since their publication there have been a number of
significant changes in dairy cow genotype. The modern dairy cow has been selected
to maximise milk yield, as there is a positive correlation between yield and gross
efficiency. However, these increases in yields from high genetic merit cows were
being fuelled by increased losses of body condition, as intake potential was unable to
meet the nutrient demands placed upon the animal to remain in step with increased
performance. As a consequence, in addition to selecting animals on the traits of
increased milk production animals were also selected for increased feed intake. The
combination of these two selection criteria have resulted in a much larger framed
animal with greater intake potential that has been selected to partition nutrient
resources into milk. Consequently, data that applied to cull cow finishing
performance at the start of the over thirty month scheme in 1996 may not be
appropriate for today’s modern day Holstein Friesian dairy cow. The aim of this
study was to address this information shortfall by assessing animal growth
performance and post-mortem carcass characteristics of modern dairy cull cows fed
forage based finishing diets for a 63 day finishing period and to evaluate the financial
implications of each. However a recent study investigating the effects of feeding a
single forage based diet to finishing cull cows had indicated that a finishing period of
30 days was sufficient. Data derived from this study did indicate that further
improvements in animals performance beyond 30 day finishing period were negligible
in cattle offered diets from grass silage based systems. This was not the case for
cattle receiving maize silage based diets whose performance did not alter appreciably
The diets used in this study were predominantly of conserved forages, namely grass
and maize silages that were either offered as grass silage as the sole feed (G), grass
silage plus 3 kg/day of cracked wheat (GW) or a maize silage TMR that contained a
small quantity of a soyabean and rapeseed protein supplement, and represented three
over wintering forage based finishing systems that would be appropriate for cull dairy
Intakes of CP, ME, NDF and ash were notably higher in those animals receiving diet
M, principally due to the greater DMI of this treatment. Only intakes of starch in diet
M were a function of DMI whereas starch intakes in diet GW were unrelated to DMI
as its source was from the 3 kg of cracked wheat topped dressed on to the forage
Overall weight gains were notably better in diet M, with animals gaining
approximately 50 and 64kg more weight during the course of the study than diets GW
and G respectively. However, this failed to reach statistical difference, in part due to
the large variation seen in total weight gains. This is also reflected in absolute rates of
DLWG. Daily live weight gains calculated from regression analysis indicate trends in
live weight gain and tend to compensate for occasional perturbations in animal
performance. This method of determining rates of gain reduced overall variation and
indicated better rates of gain than absolute values. However, these still fail to achieve
statistical significance, despite the large numerical differences seen between treatment
means. Furthermore, there were indications those animals receiving grass silage based
diets performed better in the first half of the study when compared to the latter half,
whereas the opposite was true for those animals receiving the maize silage TMR.
Five animals from diet G and one animal each from diets GW and M either failed to
gain or lost weight over the duration of the study which was accompanied by lower
than average DMI. Of these seven animals exhibiting low DMI and poor weight
gains, one animal from diet GW developed mastitis and was removed from the Calan
gates during the last week of the study. Two animals from diet G developed chronic
lameness that appeared to be the result of joint or tendon problems rather than
microbial infection and these animals were also removed from the Calan gates. There
were no other health issues with the remaining four animals that had exhibited weight
loss, although these four animals were identified as being some of the older animals
The relationship between ME intake and DLWG shown in Figure 2 indicates that
animals on this study gained weight when ME intakes were in excess of 85 MJ/day,
probably representing ME required for maintenance. Despite mean intakes of ME in
diet G being below this 85 MJ/day threshold of weight gain, cattle receiving this diet
gained approximately 0.2 kg/day. Intakes of ME in diet GW were higher than the
threshold value with ME intakes of 106 MJ/day, although 36 MJ of this was provided
by the 3kg of cracked wheat that was top dressed daily. ME intakes in diet M were
twice that of those of diet G and is reflected in the rates of live weight gain which was
approximately 1.2 kg/day which is 1.0 kg/day better than those recorded in diet G.
Carcass weights tended to be heavier in diet M animals than those offered diet G
although killing out percentages appeared to be nearly identical between these two
treatments. However, not all animals were dressed to the same specification and
dressing specification was not uniform between treatments, such that prior to
determination of carcass weight more animals from treatment G underwent additional
trimming than those of treatments GW and M.
Conformation scores, irrespective of treatment, were generally poor with cattle
grading on average P+, as would be expected from animals principally bred for
efficiency of milk production. Conversely fat scores were good with cattle grading on
average 4L, although there were still no differences in fat score between dietary
treatments. Using the resultant equation from the plot of BCS against fat score it was
possible to estimate pre-treatment fat scores and subsequent changes in fat scores that
occurred during the course of the study. These equations indicated that animals at
enrolment had an MLC fat score of approximately 3 and that the half score shift in
BCS had resulted in a 1 point shift in MLC fat class (3 – 4L).
The finishing phase for animals principally kept for meat production tends to occur
before the animal reaches full maturity and whilst the animal still has potential for
lean tissue deposition. This is not necessarily the case for dairy cows, which can be
culled for a number of reasons which include a failure to conceive, mastitis, recurrent
lameness or other animal health related issues. As a result these animals tend to be
much older than those specifically bred for meat production, and as a consequence
may lack the potential to deposit lean tissue. This in turn may result in increased rates
of fat deposition and significantly poorer feed conversion efficiencies. Furthermore,
fat deposition not only occurs at inter and intra muscular sites but internally as well.
Internal fat deposits, unlike inter and intra muscular deposits, are subject to trimming
when the animal is dressed and as a consequence could reduce carcass weight and
subsequent killing out percentage. Rates and sites of tissue deposition were not
determined in this study and this information would have been beneficial in
determining whether the greater weight gains seen under one dietary treatment or the
poorer feed efficiencies of another were the result of increased fat deposition.
Total feed costs were higher than net gains in carcass values resulting in overall
financial losses irrespective of treatment. This would imply that with the feed prices
used in the calculations in this study and the cull cattle prices that were current at the
time of slaughter it would appear to be uneconomical to finish cull dairy cows.
However, neither feed costs and cull cattle prices are static and are liable to
considerable variation. To date, following the end of the OTM scheme, cull cow
prices have not exceeded 68.1 p/kg LW and have been as low as 46.7 p/kg LW.
These figures are, on average, notably lower than the calculated cull cow breakeven
prices of 67, 80 and 101 p/kg LW for diets G, M and GW, when feed costs were 397,
However, it should be noted that these financial assumptions are based on the physical
performance of a limited number of animals that were of good body condition score at
the start of the study. Discrete data sets such as these do not permit the inclusion of
other factors that may influence animal physical performance and eventual financial
outcomes. Studies involving larger numbers of animals that permit blocking of
additional factors are necessary to fully evaluate the potential for finishing cull dairy
1 Calculated using regression of carcase value gain against actual liveweight cull cow price
5 CONCLUSION
Dry matter intakes were significantly higher in those animals offered diet M when
compared to those of diets G and GW. Total weight gains and overall feed
conversion efficiency were notably better in those animals that had received diet M.
However, due to the large amounts of variation within each treatment group for each
of these parameters it was not possible to establish these differences statistically,
although larger numbers of animals within each treatment may have reduced this
variation. Similarly the lack of difference between treatments for change in condition
score may have been attributable to large variation within treatment groups, partially
because of the subjective nature of condition scoring and the variation that occurs
between animals. There were no effects of treatment on carcass weights, killing out
percentages or carcass classification; although carcass weights were heavier in
animals that had received diet M than diets G and GW. Feed costs, irrespective of
diet, in the context of this study, were greater than estimates of gains in carcass value,
resulting in net financial losses irrespective of treatment. However, these losses are
based on theoretical gains and current feed prices, the latter of which are prone to
fluctuation. Farmers should take the performance figures detailed in this report and
apply them according to their own circumstances.
REFERENCES
Rogers, CA., Fitzgerald, A.C., Carr, M.A., Covey, B.R., Thomas, J.D. and Looper,
M.L. (2004). On-farm management decisions to improve beef quality of market
dairy cows. Journal of Dairy Science, 87:5, 1558 – 1564. APPENDIX Table A1 Unit costs of component feeding stuffs (£/tonne DM) and cull cattle prices
† Lowest unit price since end of OTM (used for sensitivity test)
‡ Highest unit price since end of OTM (used for sensitivity test)
Table A2 Deadweight prices for EUROP fat and conformation scores (p/kg DW)
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