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International Journal of
eISSN: 2574-9862

Avian & Wildlife Biology

Research Article Volume 3 Issue 2

Effects of soybean and maize bran supplementation on carcass yield of local chickens under scavenging condition in mkwinda EPA, lilongwe, malawi

Hendrina Kassim, Tanganyika

Lilongwe University of Agriculture and Natural Resources (LUANAR), Malawi

Correspondence: Jonathan Tanganyika, Animal Science Department, Bunda campus, Lilongwe University of Agriculture and Natural Resources (LUANAR), PO Box 219, Lilongwe, Malawi

Received: February 15, 2018 | Published: March 28, 2018

Citation: Kassim H, Tanganyika J. Effects of soybean and maize bran supplementation on carcass yield of local chickens under scavenging condition in mkwinda EPA, lilongwe, malawi. Int J Avian & Wildlife Biol. 2018;3(2):126–131. DOI: 10.15406/ijawb.2018.03.00071

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Abstract

An evaluation study on effect of supplementation on carcass yield of indigenous chicken was carried out at Mkwinda Extension Planning Area (E.P.A), Lilongwe. A total of thirty six chickens (18 cocks and 18 hens) were selected randomly from different clusters and were kept under scavenging system. The chickens were wing tagged for identification and allocated to three treatments [simple ration (89% maize bran, 10.75% soybean meal and 0.25% salt), maize bran and scavenging only as a control] under complete randomized design. The feedstuffs were analyzed for crude protein, crude fiber, ether extract, and dry matter before experiment. The supplementation was done in the morning and evening but age was not considered. The normal feathered chickens were selected for this experiment because they were mostly found in this EPA. Data collected included live weights, hot carcass dressed weight, cold carcass weight and visceral organs and parts. The results showed that simple ration significantly had highest live weights (1298g), hot carcass dressed weigh t(1098g), cold carcass weight (899.68g) amongst all the treatments; scavenging live weights (998.25g), hot dressed weight (801.125g), cold carcass weight (776.13g) and maize bran only live weights(1100g), hot dressed weight (1060.8g), cold carcass weight (899.43g). The same trend was observed in weights of visceral organ parts. It was also observed that cocks had higher carcass and organ yield compared to hens in all the treatments. It is concluded that supplementing indigenous chickens under scavenging conditions with simple ration result in more carcass and organs yield. Therefore farmers should be supplementing indigenous chickens by formulating simple ration for better carcass yield in indigenous chickens.

Keywords: Carcass, indigenous chicken, lilongwe, treatment

Introduction

Village chickens are an important source of high-quality protein for the ever increasing rural and urban population and further provide the former with additional income, especially to the resource-poor communities.1 Village chickens in Africa are in general hardy, adaptive to rural environments, survive on little or no inputs and adjust to fluctuations in feed availability.2 Village chickens have a natural tendency to scavenge for their food resources. There has been a renewed enthusiasm in animal products that come from organic systems or the so called ‘natural’ systems. The recognized importance of village chickens in providing meat, cash income, socio-cultural values to rural people and their efficient scavenging system has led to increased research on the species during the past years.3

The scavenging feed resource base (SFRB) is defined as those feed resources available at farm level that consists of household refuse and all the materials available in the immediate environment that the scavenging birds can use as feed.1 The major feed sources for village chickens are worms, insects, seeds, green leaves and other plant materials available in the backyard.4 According to,5 grains, bran and household food leftovers are occasional sources of supplementary feed in purely free-ranging systems. The SFRB for village chickens varies immensely with season, climate and location. This has been reported in studies conducted in countries such as Ethiopia, Indonesia, Sri Lanka and Tanzania.6,7,4 Although not clearly estimated, sufficient SFRB may be available to scavenging village chickens in the rainy season, but there is scarcity when it is dry, especially during the spring season when there are less crop residues and the plants are beginning to sprout. In the rainy season, insects/worms and green forage materials are in abundance whilst in the harvesting season there is a high supply of cereal grains and a low supply of green forages and insects/worms.4,1 However, there is little information regarding the carcass yield characteristics, of indigenous chickens. Therefore, this study will provide basic information on indigenous chicken in Malawi which then will assist farmers, researchers and policy makers for indigenous chicken’s improvement programs in future.

Materials and methods

Study area

The study was conducted at Mkwinda EPA. Specifically Mkwinda, Kudowole and Kuchinani village. Each village had three clusters which were 1km apart to prevent the mixed up of the chickens from one cluster to another. Each cluster had a maximum of 12 chickens where by all experimental chickens were wing tagged for identification. According to age they were adults. Chickens used for study were from the clusters which were bought by the Indigenous Chicken Improvement Program (InCIP)

Experimental animals and design

Thirty six (36) chickens were randomly selected from the clusters. From each cluster at least four chickens were randomly selected based on their feeding system. These feeding systems were complete ration, maize bran and salt then control. The feed ration contains 89% maize bran 10.75% soybean and 0.25% salt. The chickens were starved overnight but water was provided for easy evisceration procedure and also to know their actual live weight, weighed and Slaughtered, de feathered manually and feathers were air dried to find their weight at Sakhula farm thereafter measurements were done using the electronic scale (Table 1).

Treatments

Hens

Cocks

Total

Scavenging only

5

7

12

Maize bran only

6

6

12

Simple ration

7

5

12

18

18

36

Table 1 The way chickens were bought from the clusters (36 chickens)

Data collection

The data collected was based on the live weight, sex by observation, live weight of the chickens; weight of feathers, Weight of empty gizzards, empty intestines, thighs, heads, breast muscles, wings, blood, liver, necks, hot dressed, back portion, drumstick wing, cold dressed weight, weight after bleeding, drumstick, empty crop.

Data analysis

The data collected was subjected to two ways ANOVA of the Statistical Packages for Social Science (SPSS) package considering effects of feeding system, Turkey’s test, descriptive statistics, and estimated means was used to compare the means at the level of significance of P< 0.05 (Table 2).

Feed

CP%

CF%

EE%

DM%

Simple ration

14.42

66.36

15.83

4.08

Control

-

-

-

-

Maize bran

10.03

63.16

19.21

5.24

Table 2 The approximate analysis

Statistical model

Y ijk = μ +  M i +  S j +  ( MS ) ij +  e ijk MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGak0Jf9crFfpeea0xh9v8qiW7rqqrFfpeea0xe9Lq=Jc9 vqaqpepm0xbbG8FasPYRqj0=yi0dXdbba9pGe9xq=JbbG8A8frFve9 Fve9Ff0dmeaabaqaciGacaGaaeqabaWaaeaaeaaakeaajugibabaaa aaaaaapeGaamywaOWdamaaBaaajeaqbaqcLbmapeGaamyAaiaadQga caWGRbaal8aabeaajugib8qacqGH9aqpcaqGGaGaeqiVd0Maaeiiai abgUcaRiaabccacaWGnbGcpaWaaSbaaKqaafaajugWa8qacaWGPbaa l8aabeaajugib8qacqGHRaWkcaqGGaGaam4uaOWdamaaBaaajeayba qcLbmapeGaamOAaaWcpaqabaqcLbsapeGaey4kaSIaaeiiaOWdamaa bmaabaqcLbsapeGaamytaiaadofaaOWdaiaawIcacaGLPaaadaWgaa qcbauaaKqzadWdbiaadMgacaWGQbaal8aabeaajugib8qacqGHRaWk caqGGaGaamyzaOWdamaaBaaajeaqbaqcLbmapeGaamyAaiaadQgaca WGRbaal8aabeaaaaa@5FCE@

Where;

Y ijk MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGak0Jf9crFfpeea0xh9v8qiW7rqqrFfpeea0xe9Lq=Jc9 vqaqpepm0xbbG8FasPYRqj0=yi0dXdbba9pGe9xq=JbbG8A8frFve9 Fve9Ff0dmeaabaqaciGacaGaaeqabaWaaeaaeaaakeaajugibabaaa aaaaaapeGaamywaOWdamaaBaaajeaqbaqcLbmapeGaamyAaiaadQga caWGRbaal8aabeaaaaa@3EA6@ =              Observed carcass yield characteristics

μ MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGak0Jf9crFfpeea0xh9v8qiW7rqqrFfpeea0xe9Lq=Jc9 vqaqpepm0xbbG8FasPYRqj0=yi0dXdbba9pGe9xq=JbbG8A8frFve9 Fve9Ff0dmeaabaqaciGacaGaaeqabaWaaeaaeaaakeaajugibabaaa aaaaaapeGaeqiVd0gaaa@3AD5@ =              Overall mean of the observation

M i MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGak0Jf9crFfpeea0xh9v8qiW7rqqrFfpeea0xe9Lq=Jc9 vqaqpepm0xbbG8FasPYRqj0=yi0dXdbba9pGe9xq=JbbG8A8frFve9 Fve9Ff0dmeaabaqaciGacaGaaeqabaWaaeaaeaaakeaaieGajugiba baaaaaaaaapeGaa8xtaKqba+aadaWgaaqcbauaaKqzadWdbiaa=Lga aKqaa9aabeaaaaa@3D81@ =             Effect of feeding systems on meat yield

S j MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGak0Jf9crFfpeea0xh9v8qiW7rqqrFfpeea0xe9Lq=Jc9 vqaqpepm0xbbG8FasPYRqj0=yi0dXdbba9pGe9xq=JbbG8A8frFve9 Fve9Ff0dmeaabaqaciGacaGaaeqabaWaaeaaeaaakeaajugibabaaa aaaaaapeGaam4uaOWdamaaBaaajeaqbaqcLbmapeGaamOAaaWcpaqa baaaaa@3CC2@ =              Effect of the sex on carcass yield

( MS ) ik MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGak0Jf9crFfpeea0xh9v8qiW7rqqrFfpeea0xe9Lq=Jc9 vqaqpepm0xbbG8FasPYRqj0=yi0dXdbba9pGe9xq=JbbG8A8frFve9 Fve9Ff0dmeaabaqaciGacaGaaeqabaWaaeaaeaaakeaadaqadaqaaK qzGeaeaaaaaaaaa8qacaWGnbGaam4uaaGcpaGaayjkaiaawMcaamaa BaaajeaqbaqcLbmapeGaamyAaiaadUgaaSWdaeqaaaaa@400C@ =                Interaction effect of the ith feeding systems and the jth sex

e ijk MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGak0Jf9crFfpeea0xh9v8qiW7rqqrFfpeea0xe9Lq=Jc9 vqaqpepm0xbbG8FasPYRqj0=yi0dXdbba9pGe9xq=JbbG8A8frFve9 Fve9Ff0dmeaabaqaciGacaGaaeqabaWaaeaaeaaakeaajugibabaaa aaaaaapeGaamyzaOWdamaaBaaajeaqbaqcLbmapeGaamyAaiaadQga caWGRbaal8aabeaaaaa@3EB2@ =              Random error component

Results and discussion

The effect of feed on carcass yield

Effect of feed on carcass characteristics were also significant (P<0.05) as summarized in (Table 3). Feed significantly (P<0.05) affected all the parameters measured. The experiment further revealed that cocks showed remarkable and better carcass yield than hens for all the traits measured (Table 3). A two way ANOVA was conducted that examined the effect of feed and sex on meat yield. There was statistically significant difference on live weight, cold dressed weight after de feathered and weight after bleeding of hens and cocks on simple ration followed by those on maize bran then control meaning that feed had an effect on live weight cold dressed weight, weight after de feathered and weight after bleeding. The above results indicate that supplementing the indigenous chickens improves the performance of the chickens in terms of the meat yield as well as growth rate.

Parameter

Control

Simple ration

Maize bran

Hens

Live weight

998.25±0.49c

1297.43±0.470a

1099.4±0.470b

Hot dressed wt

798.38±0.42c

1094.39±0.410a

899.8±0.410b

Cold dressed wt

776.13±0.5c

1048.57±0.458a

881.4±0.458b

After bleeding

973.75±1.213c

1275±.986a

1077±.973b

DE feathered

948.625±1.233c

1250±1.318a

1052±1.560b

Cocks

Live weight

999±0.491c

1298.8±0.470a

1100±0.470b

Hot dressed wt

801.125±0.498c

1098.29±0.410a

1060.8±0.410b

Cold dressed wt

780.125±0.479c

1079.57±0.458a

899.43±0.458b

After bleeding

977.750±0.996c

1276±0.953a

1078±0.953b

De feathered

954.250±1.744c

1251±1.560a

1054±1.318b

Table 3 The effect of feed on carcass yield (mean±SE)

abc means with different superscript within the rows are significantly different at P<0.05

Because of its movement, indigenous chickens require more energy in search of the feed, they consume additional energy feed for scavenging activities and stop feeding when the crop and gizzard are filled to capacity (nibbling).8 Since village chickens mainly scavenge in order to obtain feed, the scavenging feed resources are not concentrated enough in terms of energy because they do not contain sufficient quantity of starch and they have high fiber content. Cereals have high amounts of crude fiber and cellulose (20-30%).9 According to Theerachai10 reported that male normal feathered indigenous chicken cocks had higher proportion of total carcass due to sex differences which arises due to physiological activities where hens involved in egg laying activities which requires high energy and reduce their weights compared to cocks. Furthermore, supplementing village chickens with commercial feed tend to give them intramuscular fat and resulting in better sensory attributes.11 Consumers’ preferences for village chicken meat is attributed to leanness, flavor and presumed organic origin than broilers (Table 4).

Results in Table 4 showed that there was high significant difference (P<0.05) of chicken parts on those chickens under simple ration followed by those on maize bran and control meaning that simple ration had an effect on chicken parts. The above means of the thigh, breast muscle, back portion, drum stick and drumstick wing of chickens (cocks) under simple ration were high compared to those means of cocks on the maize bran and control, meaning that simple ration had an effect on chicken parts on cocks the same trend occurred in hens under simple ration, maize bran and control. Meaning that when the local chickens under free range are supplemented with simple ration there is much yield of chicken parts compared to those on the full scavenging and those on maize bran, when the local chickens are supplemented with the feed contain the protein it improves the productivity of the local chickens according to Theerachai.10 Rearing chickens with full feed supplements result in village chickens with high percentage of breast muscle, which was tenderer and of a better quality than muscle from an extensive system.11

Parameter(g)

Control

Simple ration

Maize bran

Hens

Drumstick

88.14±2.828b

135.142±2.193a

96.4±2.302b

Thigh

99.75±1.669c

186.429±2.370a

157±2b

Back portion

126.5±1.604b

189.143±0.469a

137.4±1.673a

Breast muscle

128.25±0.109b

136.143±0.206a

130±0.668b

Drumstick wing

57.25±2.375b

93.286±0.175a

68.6±1.673b

Cocks

Drumstick

88.5±0.691b

136.14±0.660a

96.4±0.660b

Thigh

100.25±0.562b

187.4±0.538a

159±0.538a

Back portion

128.75±0.957b

196.8±0.924a

138±1.915b

Breast muscle

155.75±0.417b

165.2±0.417b

163.57±0.417b

Drumstick wing

56.2±1.082b

98.2±1.681a

66.857±1.681b

Table 4 The effect of feed on carcass yield on parts (mean ±SE)

abc means with different superscript within the rows are significantly different at P<0.05

Table 5 indicates the visceral organs and there means, the means of empty gizzards, empty intestines and liver of chickens under simple ration were high compared to those on maize bran and control meaning that simple ration had an effect on the visceral organs and there was high significant difference (P<0.05) on visceral organs under simple ration followed by those on maize bran and control, because after analysis there was correlation of results of visceral organs under maize bran and control (P<0.001) toward to significant difference. There were much of these correlations because when chickens are supplemented or changed to another feed the gizzard tends to increase in size for digestion of the feed, this is so because gizzard helps grinding the feed. The empty intestines tend to have high weights due to the processes of absorption. Based on literature according to Aderemi12 found that the percentage of gizzard of indigenous chicken was higher than in broilers and that this may be due to the work load required to grind the feed particles of different nature available to the birds in scavenging system.

Parameter(g)

Control

Simple ration

Maize bran

Cocks

Empty gizzards

36.25±0.98b

50.6± 0.94a

38.57± 0.83b

Empty intestines

36.5±.1.113b

52.4±1.065a

41±.1.065b

Liver

24±.528b

26.6± .505a

25.285±0.505b

Hens

Empty gizzards

35.25±0.984b

47.71±0.941a

36.4±0 .941b

Empty intestines

34.625±1.113b

50.29±1.065a

38.6±1.065b

Liver

23.125± 0.528b

26.123±0 .505a

25.2±0.505b

Table 5 The effect of feed on carcass yield on visceral organs (mean ± SE)

abc means with different superscript within the rows are significantly different at P<0.05

Comparison of meat yield of cocks and hens on different supplements

After conducting the two way ANOVA to examine the effect of simple ration, maize bran and control on cocks under these treatments, the cocks showed the highest dressing percentage, cold dressing weight, weight after bleeding, weight after de feathered (P<0.05) compared to cocks on maize bran and control on the same parameters. The same trend occurred on hens under both treatments. According to Theerachai10 reported that male normal feathered indigenous chicken cocks had higher proportion of total carcass. But still there was slight difference on hens under simple ration and maize bran in terms of their weights showing that the energy that are stored in the body are used for the movement to search feed for those hens under control but those hens under simple ration and maize bran they had enough energy and the movement in search of feed was limited and the body was able to convert the stored energy into usable resources such as fat, that is why their weights were high compared to those on control. The results indicate that although hens undergo physiological activities such as egg laying, when the feed is available they still maintain their weights since the energy and proteins used during these physiological activities are replaced with the feed supplemented hence the meat yield of hens under scavenging were improved. Stocking density is an important factor that governs the birds’ ability to exercise and this has an effect on the bird’s energy utilization.

The low stocking density under outdoor production systems increases the birds’ ability to exercise through exhibiting natural behaviors like walking, scratching and wing flapping.13 These activities favor myogenesis instead of lipogenesis14 because protein synthesis is stimulated by the increased activity.15 Based on results findings in this experiment indicates that when cocks and hens are supplemented with feed containing protein and energy will improve the meat yield and quality of meat. To have more yield in local cocks and hens farmers need to do supplementation using complete feed doing this will help them to get more profit.

Comparison of meat yield of parts between the cocks among different supplements

After conducting the two way ANOVA to examine the feed supplementation on chicken parts of cocks, it indicates that drumstick, thigh, back portion, breast muscle and drumstick wing under simple ration were high compared to those on maize bran and control meaning that simple ration had an effect on chicken parts of cocks and there was high significant difference (P<0.05) compared to those on maize bran and control. The same trend occurred in hens under both treatments. Chickens under scavenging conditions they stimulates a hypertrophic muscular growth of thigh and breast muscle that’s according to Dransfield et al.15 The results are similar with the findings of Castellini et al.14 who reported that the breast meat increased when birds were managed at a lower stocking density in outdoor management systems. Since birds under scavenging conditions are more adapted to stress conditions than the confined counterparts, this could reduce pre-slaughter stress thus conserving more glycogen in the muscles. Meat with a lower ultimate pH has been reported to have a longer shelf life because low pH increases the lag phase time of psychrotrophic bacteria that are known to spoil meat16,17 (Table 6).

Parameter(g)

Control

Simple ration

Maize bran

Cocks

Empty gizzards

36.25±0.98b

50.6± 0.94a

38.57±0.83b

Empty intestines

36.5±.1.113b

52.4±1.065a

41±.1.065b

Liver

24±.528b

26.6± .505a

25.285±0.505b

Hens

Empty gizzards

35.25±0.984b

47.71±0.941a

36.4±0 .941b

Empty intestines

34.625±1.113b

50.29±1.065a

38.6± 1.065b

Liver

23.125± 0.528b

26.123±0 .505a

25.2±0.505b

Table 6 Comparison of visceral organs of cocks and hens on different supplements (means±SE)

abc means with different superscript within the rows are significantly different at P<0.05

The two way ANOVA showed that there was correlation of results of empty gizzard, liver, and empty intestines of those cocks under simple ration and maize bran at significant level of P<0.05 and there means were high meaning that simple ration and maize bran had an effect on visceral organs. The same trend occurred in visceral organs of hens. According to Aderemi12 found that the percentage of gizzard of indigenous chicken was higher than in broilers and that this may be due to the work load required to grind the feed particles of different nature available to the birds in scavenging system and Tamilvanan18 reported that the weight of liver of indigenous chickens was higher than in broilers which could be due to increased metabolic activities in an effort to make up for the reduced availability of protein as the indigenous chickens are reared in free range system (Table 7).

Parameter(g)

Feeding

Sex

Mean(±SE)

SIG

Live weight

Control

Male

999±.491

 

Female

998.25±.491

Simple ration

Male

1298.8±.470

*

Female

1194±.462

Maize bran

Male

1100±.470

 

Female

1099.4±429

Hot carcass

Control

Male

798.5±.429

 

Female

780.125±.429

Simple ration

Male

1098.236±.410

*

Female

1092.286±.515

Maize bran

Male

899.429±.410

 

Female

879.8±.390

Cold carcass

Control

Male

781.29±.479

 

Female

780.125±.429

Simple ration

Male

1079.4±1.949

*

Female

1070.57±.458

Maize bran

Male

881.57±.458

 

Female

879.4±458

Drumstick wing

Control

Male

56.25±1.758

 

Female

57.25±1.681

Simple ration

Male

98.2±1.681

*

Female

93.29±1.681

Maize bran

Male

68.85±1.758

 

Female

66.6±1.673

Breast muscle

Control

Male

155.2±.417

 

Female

130.25±.436

Simple ration

Male

165.75±.417

*

Female

125.14±.436

Maize bran
Maize bran

Male

163.57±.417

 

Female

96.4±2.302

 

Thigh

Control

Male

100.25±.565

 

Female

99.75±.669

Simple ration

Male

187.4±.538

*

Female

186.429±.538

Maze bran

Male

159±.538

 

Female

157±.538

Drumstick

Control

Male

88±.691

 

Female

86.5±.690

Simple ration

Male

135.4±.660

*

Female

86.68±.070

Maze bran

Male

96.286±.660

 

Female

94.4±.660

Back portion

Control

Male

137.75±.957

 

Female

128.4±1.673

Simple ration     

Male

196.8±1.924

*

Female

189.143±.105

Maze bran

Male

138±1.915

 

Female

126.5±1.604

Table 7 Interaction of feeding and sex on carcass yield characteristics (Mean ±SE)

**=Very significant, *=significant, NS=Not significant

A two way ANOVA was conducted that examined the effect of sex and feed on meat yield. There was a statistically significant interaction between the effect of sex and feed on meat yield P<0.05 level. Consistently higher weights found in various carcass parameters in normal feathered males of Malawian chickens than in normal females is consistent with Isidahomen et al.19 who found similar results in Nigerian indigenous chickens reared under both free range and intensive systems. It has also been reported that sex differences were usually due to differences in hormonal profile, aggressiveness and dominance especially when both sexes are reared together.20 In their report, Adedeji et al.21 stated that the aggressiveness of males over the females especially when reared together put the females at a disadvantage for feed and water. According to Musa et al.22 growth and carcass differences between cocks and hens were due to differences in feed metabolism and in the onset of fattening. From the results it shows that the cocks that were on simple ration and maize bran had more meat yield and better quality compared to females on both feeding systems but those hens under complete feed had more yield compared to the cocks on control.

Conclusion

 Supplementing indigenous chickens under scavenging conditions with simple ration (Soybean meal, maize bran and salt) result in more carcass and organs yield. It was also observed that cocks had higher carcass and organ yield compared to hens in all the treatments. Therefore farmers should be supplementing indigenous chickens by formulating simple ration (89% maize bran, 10.75% soybean meal and 0.25% salt).

Acknowledgements

The authors sincere give thanks to entire team of InCIP for their support and provision of resources used during research period, Mr. D Chiumia, Miss Mtisunge Chinunda, Mr.F Chimwendo for their assistance and advice; Prof .TN Gondwe and Dr .W. Jere for assisting in the data analysis and all members of staff in the Animal Science Department at Bunda campus.

Conflict of interest

Authors declare that there are no conflicts of interest.

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