Corrigendum - Comparative breed studies of beef cattle. III. Carcass composition

1964 ◽  
Vol 15 (2) ◽  
pp. 333
Author(s):  
NM Tulloh
Keyword(s):  
Body Weight ◽  
Age Groups ◽  
Carcass Composition ◽  
Carcass Weight ◽  
Published Data ◽  
Regression Equations ◽  
Comparison Study ◽  
Differential Growth ◽  
Breed Differences ◽  
Breed Comparison

An investigation was made of published data on the carcass composition of cattle, based on dissection of carcasses into bone, muscle, and fat. The data included females and castrate males, without regard to breed, age, or nutritional history. It was found that the relation between each carcass component and empty body weight could be described by a linear regression equation by using logarithmic values for the variables. The differential growth ratios given by the regression equations indicated, as empty body weight increased, that: (a) the weight of each of the dissected carcass components (i.e. bone, muscle, and fat) also increased; (b) the proportion of carcass bone fell, that of fat increased, and that of muscle remained almost constant. The relations between dissected bone, muscle, and fat and carcass weight were similar to those obtained between dissected carcass components and empty body weight. To obtain evidence on whether the differential growth ratios between dissected carcass components and empty body weight or carcass weight showed any change throughout post-natal life, quadratic equations were computed by using logarithmic values for the variables. These ratios fell for all carcass components, but in only three out of six equations were the quadratic terms statistically significant. This re-examination of published data indicates that any comparisons of the carcass composition of cattle may be invalid unless they are made at the same body (or carcass) weights. In addition, a comparison made by using regression equations, with the variables expressed as percentages, is confusing because it may not reveal abnormal composition in animals of particular weights. A satisfactory type of analysis can be made by using regression techniques with the original data. The above principles of analysis were applied in a breed comparison study of the carcass composition of 28 Hereford, 25 Angus, and 18 Shorthorn steers. These cattle comprised two age groups, born in 1957 and 1958 respectively. Carcass composition was estimated by dissecting, into bone, muscle and fat, the left and right 11th ribcuts from the carcasses of the 1957 steers, and the 9th–10th–11th rib-cuts from the left sides of the carcasses of the 1958 steers. When the rib-cut data were plotted, the relations appeared linear; the data were therefore analysed by using linear regressions with arithmetical values for the variables. Results showed that the fat content was greater and the muscle content smaller in the rib-cuts of the Shorthorns in both years than in those of either Hereford or Angus steers. Differences between Herefords and Angus were small. In view of the high correlations found by other workers between the results of rib-cut dissections and carcass composition, it is assumed that the breed differences reported here in rib-cut composition were reflections of breed differences in carcass composition. The carcass compositions of the cattle used in the breed comparison study were also estimated from hot carcass weight by using regression equations derived from the literature. A comparison of the two methods of estimating carcass composition suggests that, if hot carcass weight is to be used, regression equations will need to be developed for each breed in various environments.

Comparative breed studies of beef cattle. III. Carcass composition

1964 ◽  
Vol 15 (2) ◽  
pp. 333
Author(s):  
NM Tulloh
Keyword(s):  
Body Weight ◽  
Age Groups ◽  
Carcass Composition ◽  
Carcass Weight ◽  
Published Data ◽  
Regression Equations ◽  
Comparison Study ◽  
Differential Growth ◽  
Breed Differences ◽  
Breed Comparison

An investigation was made of published data on the carcass composition of cattle, based on dissection of carcasses into bone, muscle, and fat. The data included females and castrate males, without regard to breed, age, or nutritional history. It was found that the relation between each carcass component and empty body weight could be described by a linear regression equation by using logarithmic values for the variables. The differential growth ratios given by the regression equations indicated, as empty body weight increased, that: (a) the weight of each of the dissected carcass components (i.e. bone, muscle, and fat) also increased; (b) the proportion of carcass bone fell, that of fat increased, and that of muscle remained almost constant. The relations between dissected bone, muscle, and fat and carcass weight were similar to those obtained between dissected carcass components and empty body weight. To obtain evidence on whether the differential growth ratios between dissected carcass components and empty body weight or carcass weight showed any change throughout post-natal life, quadratic equations were computed by using logarithmic values for the variables. These ratios fell for all carcass components, but in only three out of six equations were the quadratic terms statistically significant. This re-examination of published data indicates that any comparisons of the carcass composition of cattle may be invalid unless they are made at the same body (or carcass) weights. In addition, a comparison made by using regression equations, with the variables expressed as percentages, is confusing because it may not reveal abnormal composition in animals of particular weights. A satisfactory type of analysis can be made by using regression techniques with the original data. The above principles of analysis were applied in a breed comparison study of the carcass composition of 28 Hereford, 25 Angus, and 18 Shorthorn steers. These cattle comprised two age groups, born in 1957 and 1958 respectively. Carcass composition was estimated by dissecting, into bone, muscle and fat, the left and right 11th ribcuts from the carcasses of the 1957 steers, and the 9th–10th–11th rib-cuts from the left sides of the carcasses of the 1958 steers. When the rib-cut data were plotted, the relations appeared linear; the data were therefore analysed by using linear regressions with arithmetical values for the variables. Results showed that the fat content was greater and the muscle content smaller in the rib-cuts of the Shorthorns in both years than in those of either Hereford or Angus steers. Differences between Herefords and Angus were small. In view of the high correlations found by other workers between the results of rib-cut dissections and carcass composition, it is assumed that the breed differences reported here in rib-cut composition were reflections of breed differences in carcass composition. The carcass compositions of the cattle used in the breed comparison study were also estimated from hot carcass weight by using regression equations derived from the literature. A comparison of the two methods of estimating carcass composition suggests that, if hot carcass weight is to be used, regression equations will need to be developed for each breed in various environments.

Effects of three different growth rates on empty body weight, carcass weight and dissected carcass composition of cattle

1974 ◽  
Vol 82 (3) ◽  
pp. 535-547 ◽  
Author(s):  
D. M. Murray ◽  
N. M. Tulloh ◽  
W. H. Winter
Keyword(s):  
Body Weight ◽  
Growth Rates ◽  
Subcutaneous Fat ◽  
Allometric Equation ◽  
Carcass Composition ◽  
Carcass Weight ◽  
Abdominal Muscles ◽  
Regression Equations ◽  
General Group ◽  
Relative Growth

SUMMARYA study was made of the effect on body composition of growing Angus steers from 300 to 440 kg at three different rates. The rates were: High (H) 0·8 kg/day, Low (L) 0·4 kg/day and High-Maintenance (HM) 0·8 kg/day followed by a period during which body weight was maintained constant.The animals were individually penned and the different growth rates were achieved by controlling intakes of a pelleted feed. Two animals (part of H treatment) were killed at 300 kg and the remaining 27 animals (nine in each treatment), were killed at common body weights of 330, 363, 400 and 440 kg.Analyses of covariance were used to compare linear regression equations representing results from each treatment. In order to do this, the logarithmic transformation of the allometric equation, y = axb, was used. As a proportion of empty body weight (EBW), hot carcass weight (HCW) was greater in both the HM and L groups than in the H group, indicating a greater offal component of EBW in the H animals. The loss in weight of the dressed carcass during storage at 2 °C for 24 h was similar in all three groups and was 0·98% of HCW. The proportions of HCW in the fore- and hind-quarters were similar in each group.At the same dissected side weight (DSW), the weight of bone was significantly greater in both the HM and L groups than in the H group indicating that bone development was related to both age and carcass weight. There were no significant differences between the groups in the proportions of either muscle or total fat. However, the proportion of kidney and channel fat in the H group was greater than in the HM and L groups and the proportion of subcutaneous fat was also greater in the H than in the L group. The amount of connective tissue in the three groups followed, in general, group differences in bone. Analyses of the dissected components of the separate fore- and hind-quarters showed that the difference between the H and L groups in the proportion of subcutaneous fat in the DSW was due to a relatively greater development of this fat in the fore-quarter of the H animals.No differences were found between treatments in the proportion of ‘expensive muscles’ relative to total side muscle (TSM). However, there were treatment effects on the proportions of TSM formed by certain groups of muscles; two examples are: the proportion of group 4 muscles (abdominal muscles) was higher and the proportion of group 6 muscles (distal muscles of the fore-leg) was lower in the H than in the L treatments. Bone weight distribution was similar in all treatments.There were differences between the H and HM groups in the relative growth ratios for all fat tissues (subcutaneous, intermuscular and kidney and channel fat) compared with total side fat. However, in the H and L groups, the relative growth ratios for corresponding fat categories were similar. The weight of kidney and channel fat in the left side of the carcass was significantly greater than in the right side of the carcass in all treatments.

Breed differences in body composition of equally mature sheep

1976 ◽  
Vol 23 (3) ◽  
pp. 281-293 ◽  
Author(s):  
T. H. McClelland ◽  
B. Bonaiti ◽  
C. S. Taylor
Keyword(s):  
Body Composition ◽  
Body Weight ◽  
Sex Differences ◽  
Carcass Composition ◽  
The Other ◽  
Carcass Weight ◽  
Fat Percentage ◽  
Breed Differences ◽  
Degree Of Maturity ◽  
Total Muscle

SUMMARYSheep from the Soay, Finnish Landrace, Southdown and Oxford Down breeds were serially slaughtered at about 40, 50, 60 and 70% of their estimated mature body weight. Breed and sex comparisons were made at these degrees of maturity. Large differences were found in the weight of muscle, fat and bone, total muscle ranging from a mean of 3·3 kg in the Soay to 13·0 kg in the Oxford Down; the corresponding range for dissected fat was 1·2 to 9·2 kg.Most of the breed and sex differences observed at the same degree of maturity disappeared when expressed as a percentage of body or carcass weight. Thus both sexes had almost the same body and carcass composition in terms of fat, muscle and bone percentage. There were breed differences in fat percentage, with the Soay significantly less fat than the other breeds. Total muscle as a percentage of body weight was remarkably close to 28·5% in all breeds in both sexes, and at all four stages of maturity.

scholarly journals Prediction of the meat content of the carcass and valuable carcass parts in French lop rabbits using some traits measured in vivo and post mortem

2011 ◽  
Vol 51 (No. 9) ◽  
pp. 406-415 ◽  
Author(s):  
D. Michalik ◽  
A. Lewczuk ◽  
E. Wilkiewicz-Wawro ◽  
W. Brzozowski
Keyword(s):  
Body Weight ◽  
Carcass Weight ◽  
Head Width ◽  
Regression Equations ◽  
Post Mortem ◽  
Hip Circumference ◽  
Thigh Circumference ◽  
Meat Weight ◽  
Chest Girth

The experiment was performed on 60 French lop rabbits raised under extensive conditions and sacrificed at body weight of about 3 kg. It was found that the best indicators of meat weight (g) in rabbit carcasses were body weight, head width and lower thigh length among the traits measured in vivo, and carcass weight, chest girth and thigh circumference among the traits measured post mortem. In vivo prediction of saddle meatiness may be based on body weight, trunk length and thigh length, whereas post-slaughter estimation – on carcass weight, hip circumference and thigh circumference. Total meat weight in the hind half of the carcass may be predicted in vivo on the basis of body weight, head width and lower thigh length, and post mortem – on the basis of carcass weight, chest girth, hip circumference, thigh circumference and pelvic width. Multiple regression equations for meat weight estimation in the whole carcass and its middle and hind part were derived in the study. These equations may be applied in selection work directed towards an improvement in carcass meatiness. They may also be used to evaluate the results of experiments conducted on French lops.  

Prediction of body weights of Nellore sheep under field condition

2015 ◽  
Author(s):  
M. Rani ◽  
B. Ekambaram ◽  
B. Punya Kumari
Keyword(s):  
Body Weight ◽  
Body Length ◽  
Age Groups ◽  
The Body ◽  
Coefficient Of Determination ◽  
Regression Equations ◽  
Body Weights ◽  
Chest Girth ◽  
Males And Females ◽  
Nellore Sheep

Data on 1350 Nellore sheep of 2, 4, 6 and 8-teeth age, reared under field conditions in 12 mandals of Chittoor district of Andhra Pradesh were utilized for development of prediction equations and study the phenotypic association among body measurements and body weights. The coefficients of correlation between body weight with the height at withers, chest girth, paunch girth, hip width and body length were positive and high in magnitude in both males and females in majority of the age groups studied. Step-down regression equations were fitted to predict the body weight based on biometrical measurements at different ages. The height at withers, chest girth, paunch girth, hip width and body length have contributed significantly to the expression of body weights at the majority of the ages studied. High coefficient of determination (R2) value was observed in males at 6 and 8-teeth age as 88 per cent, while in females 50 per cent at 2-teeth age.

Developmental growth and body weight loss of cattle. IV. Chemical components of the commercially dressed and jointed carcass

1969 ◽  
Vol 20 (1) ◽  
pp. 199 ◽  
Author(s):  
RM Seebeck ◽  
NM Tulloh
Keyword(s):  
Weight Loss ◽  
Body Weight ◽  
Body Weight Loss ◽  
Carcass Composition ◽  
Chemical Component ◽  
Carcass Weight ◽  
Chemical Components ◽  
Single Chemical ◽  
Group A ◽  
Group B

This paper describes a study of chemical components of the carcasses from Angus steers. The left side of each carcass was jointed commercially and each joint was analysed for protein (N x 6.25), water, ash, and fat (ether extract). Two groups of steers were used, viz. group A which grew continuously and group B which grew like group A and were then subjected to a period of weight loss before slaughter. Corresponding animals in both groups were killed at the same body weight. Statistical analysis was by analyses of covariance of the weights of components converted to logarithms. As carcass weight increased, the proportions in the carcass of protein, water, and ash decreased while the proportion of chemical fat increased. When carcass composition was calculated on a fat-free basis, there were significant changes in the proportions of protein, water, and ash as the weight of the fat-free carcass increased during the age range of 12 to 24 months. These are contrary indications to the theory of chemical maturity put forward by Moulton (1923). As carcass weight increased, the weight of each chemical component increased but changes occurred in the distribution throughout the carcass of protein, ash, and chemical fat. The effect of the weight loss treatment on the proportion of each chemical component was independent of carcass weight. When group A and group B animals were compared at the same carcass weight, weight loss led to a significant increase in the proportion of ash and a significant decrease in that of protein. The weight of ash in group B carcasses was estimated to be slightly less than that expected in these animals at their peak of body weight, i.e. before weight loss commenced. There were significant differences between groups A and B in the distribution of the chemical components (particularly protein and fat); these treatment differences in distribution indicate a limitation to the use of chemical analyses of a single joint for predicting whole carcass composition. When relationships between chemical and dissected components were studied, each single chemical component was well related to its corresponding dissected component. For each dissected component except muscle, however, there were significant differences between groups A and B in the equation of best fit, either in slope or in the intercept (difference between adjusted means). Differences of this type limit the use of chemical analysis for estimating dissected components where differences between groups are being studied.

The effect of pre- and post-natal nutrition on the growth of beef cattle. 3. The effect of severe restriction in early post-natal life on the development of the body components and chemical composition

1980 ◽  
Vol 31 (1) ◽  
pp. 191 ◽  
Author(s):  
GD Tudor ◽  
DW Utting ◽  
PK O'Rourke
Keyword(s):  
Body Weight ◽  
Carcass Composition ◽  
The Body ◽  
Fat Free Mass ◽  
Carcass Weight ◽  
Feeding Period ◽  
Castrate Male ◽  
Before And After ◽  
Body Components ◽  
Female Cattle

The effects of restricted growth of cattle both before and after birth, of the method of their realimentation, and of sex on (1) body and carcass composition, (2) the weights of visceral components, (3) the weights of selected individual muscles and bones, and (4) the heights of the animals at the withers and pelvis were ascertained. Castrate male and entire female cattle were slaughtered when their liveweights reached 400 and 370 kg respectively. Other male and female calves were slaughtered at 200 days of age following a controlled feeding period on either a high or a low plane diet. Although pre-natal nutrition significantly (P < 0.05) affected the height of the calves at 3 days of age, it had no lasting effect on this or other components. When adjusted to the same empty body weight or carcass weight, animals restricted in growth then intensively realimented had (P < 0.01) more fat and less protein, water and ash than animals unrestricted in growth and later fed intensively. Animals finished on pasture had (P < 0.01) less fat and more protein, water and ash than the intensively finished calves, but their composition was unaffected by the controlled feeding treatments. Significant differences (P < 0.01) between restricted and unrestricted animals in the percentage water or protein in the fat-free mass at the end of the controlled feeding period were eliminated when the animals had recovered. The weights of visceral components, individual muscles and bones were not influenced by the level of nutrition during the controlled feeding period. Animals finished on pasture had (P < 0.01) more blood, heavier livers, heavier individual muscles and bones than the intensively finished animals. They also had (P < 0.01) lighter fasted liveweight, empty body weight, hot carcass weight, dressing percentage and heavier wet rumen-reticulum contents than the intensively finished cattle. Although the pasture finished animals were (P < 0.01) shorter at 200 and 300 days of age than the intensively finished animals, they were (P < 0.01) taller just prior to slaughter. It is suggested that meat-producing animals can overcome restrictions imposed on growth immediately after birth to attain marketable weight on either pasture or intensive feeding.

Body growth and carcass composition of lean reindeer (Rangifer tarandus tarandus L.) from birth to sexual maturity

1981 ◽  
Vol 59 (6) ◽  
pp. 1040-1044 ◽  
Author(s):  
Tata M. Ringberg ◽  
Robert G. White ◽  
Dan F. Holleman ◽  
Jack R. Luick
Keyword(s):  
Body Weight ◽  
Rangifer Tarandus ◽  
Neonatal Period ◽  
Growth Period ◽  
Carcass Composition ◽  
Body Growth ◽  
Carcass Weight ◽  
Parotid Glands ◽  
Wet Weight ◽  
The Brain

Body growth and carcass composition were measured in lean reindeer during the juvenile growth period between birth and 3 years of age. Mean carcass weight in these lean reindeer was 56 ± 4% of body weight and the deposition of body muscle and bone mass was linearly correlated with body weight after the 1st month of age. The weight of the brain relative to body weight and carcass weight declined, while the relative changes in heart, liver, kidneys, parotid glands, and tissues of the gastrointestinal tract were small after the neonatal period. The extractable fat content in carcasses increased from 4.4 to 11.4% of wet weight or approximately 100 g fat at birth and 3.5 kg fat in adult reindeer. Fat-free dry matter represented a constant percentage (18–20%) of wet carcass weight independent of body weight after the neonatal period, while a significant inverse relationship between carcass fat and body water was found.

Carcass composition in lambs of Greek dairy breeds of sheep

1990 ◽  
Vol 50 (2) ◽  
pp. 261-269 ◽  
Author(s):  
D. Zygoyiannis ◽  
K. Stamataris ◽  
S. Kouimtzis ◽  
J. M. Doney
Keyword(s):  
Live Weight ◽  
General Characteristic ◽  
Carcass Composition ◽  
Carcass Weight ◽  
Equal Weight ◽  
Equal Proportion ◽  
Quadratic Regression ◽  
The United Kingdom ◽  
Breed Differences ◽  
The Mean

ABSTRACTNine male and nine female lambs each from the Karagouniko (K), Chios (C) and East Friesland (F) breeds were weaned at a mean age of 50 days and were killed over a commercial range of live weight from 16 to 44 kg (carcass weights 6 to 22 kg).Carcass weight was linearly related to fasted live weight prior to slaughter (r = 0·994). There were significant but small differences between breeds in mean weight of lungs, pelt and internal fat. The carcass components of bone, muscle and fat tissues were related to carcass weight by linear or quadratic regression. Adjusted to mean carcass weight, the mean weight of bone did not differ between breeds (2·82 kg, s.e. = 0·056 at 12·8 kg carcass). The K and C lambs had significantly less muscle than the F lambs (6·77, 6·63 and 8·20 kg, respectively, s.e.d. = 0·094) and more fat (2·87, 2·95 and 1·29 kg, respectively, s.e.d. = 0·017) when compared at mean carcass weight. The breed differences were significant over the whole range whether compared at equal weight or at an equal proportion of estimated mature weight. At the same proportion of carcass fat, corresponding to the United Kingdom market average (250 g/kg) the calculated carcass weights were 16, 17 and 30 kg, respectively, for K, C and F lambs.It is concluded that the Friesland breed differs from many others in the proportions of muscle or fat at corresponding carcass weights but this difference is not a general characteristic of dairy sheep. Comparison of breeds at defined proportions of carcass components, as determined by market standards, can be effectively achieved by serial slaughter over a suitable weight range.

RESPONSE OF MALE AND FEMALE BROILERS TO DIET PROTEIN

1988 ◽  
Vol 68 (3) ◽  
pp. 881-889 ◽  
Author(s):  
S. LEESON ◽  
L. J. CASTON ◽  
J. D. SUMMERS
Keyword(s):  
Body Weight ◽  
Protein Content ◽  
Abdominal Fat ◽  
Carcass Composition ◽  
Carcass Weight ◽  
Breast Meat ◽  
Meat Yield ◽  
Low Protein ◽  
Breast Meat Yield ◽  
Protein Diets

Two experiments were conducted to note the broilers' response to graded levels of dietary protein (CP). Female birds were fed one of six diet series ranging from 22–20–18 to 18–18–16% CP from 0–21 days, 21–35 days and 35–42 days, respectively. Males were fed diet series from 28–24–22 to 20–18–16 over the same time periods (Table 1). Each diet program was tested with four replicate groups of 60 birds. Body weight and feed intake were monitored at time of feed change-over and at termination of experiment. Twenty birds per replicate were used for carcass analyses. Females were heavier when diets of higher protein content were offered (P < 0.05). These birds consumed more feed (P < 0.05) but exhibited feed efficiency that was not different to birds fed diets of lower protein content. Carcass weight and breast meat yield were not influenced by diet, although higher-protein diet series resulted in reduced proportional abdominal fat pad size (P < 0.01). Diet protein had no effect on body weight of male birds at 42 d (P > 0.05). Male birds reared on a program involving die lowest CP levels of 20–18–16 exhibited inferior feed utilization relative to birds from most other treatments (P < 0.05). Programs with low-protein diets for males resulted in reduced carcass weight, reduced breast meat yield and increased abdominal fat deposition (P < 0.05). It is concluded that male birds can be reared on very low protein diets without loss of weight, although carcass quality will be inferior. Female broilers are heavier when diet protein intake is increased through use of diets with higher protein content. Key words: Broiler, diet protein, performance, carcass composition

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