THE USE OF UNTRADITIONAL RATION CONSTITUENTS IN FEEDING OF GROWING DUCKS A- DRIED POULTRY WASTE

Authors

Dept. of Clinical Nutrition and Animal Nutrition Faculty of Veterinary Medicine

Abstract

The present study was performed to investigate the effect of feeding different levels of dried poultry waste (DPW) as untraditional ration constituent on duck performance, carcass traits and some blood biochemical constituents. 60 unsexed one day old Muscovy ducklings were fed ad-libitum on a control starter diet until 2 weeks of age. At that time, they were wighed and randomly distributed into 5 groups each of 12 ducklings. The first group was considered as a control (T1) and was fed ad libitum on a grower/ finisher diet. The other four groups (T2, T3, T4 & T5) were fed diets containing DPW at levels of 5, 10, 15 and 20% respectively. All diets were formulated to be isocaloric (3000 kcal/kg ME), isonitrogenous (16% CP) as recommended by NRC (1994) for growing ducks. The experiment was extended for 10 weeks. The body weight development, body weight gain, feed intake, feed conversion ratio, protein efficiency ratio and caloric efficiency ratio were determined. In addition, some blood constituents, carcass traits, mortality rate and economical evaluation were also measured. The results showed that, there were no mortalities in control group and groups fed diets with 5 and 10% DPW. However groups fed on diets with 15% and 20% dried poultry waste recorded 8.33% and 25.0% mortality rate, respectively. There were no significant differences, in performance measurements between control group and other treatments. There were no significant differences between control group and other treatments in carcass dressing percentage and relative percentage of internal organs. Also, there were no significant differences in blood parameters between control group and other treatments. It could be concluded that, addition of dried poultry waste to the duck diets up to 10% leads to decrease in the cost of the ration without any adverse effect on the duck performance and may help to alleviate pollution problems.

Keywords


Dept. of Clinical Nutrition and Animal Nutrition

Faculty of Veterinary Medicine

 

THE USE OF UNTRADITIONAL RATION CONSTITUENTS IN FEEDING OF GROWING DUCKS

A- DRIED POULTRY WASTE

(With 6 Tables)

 

By

G.M. Mosaad, A.M. Abdellah, A.N. Sayed and Rasha I. Hassan

(Received at 10/10/2009)

 

إستخدام مکونات علائق غير تقليدية فى تغذية البط النامى

أ- زرق الدواجن الجاف

 

جمال مهنى مسعد ، عبد الستار محمد عبد اللاه ، عبد الباسط نصر سيد ، رشا إبراهيم حسن

 

أجريت هذه الدراسة لقياس تأثير تغذية مستويات مختلفة من زرق الدواجن الجاف کمکون علائق غير تقليدي على کفاءة الأداء ومواصفات الذبيحة وبعض مکونات الدم فى البط المسکوفى. تم تغذية عدد ٦٠ بطة من صغار البط المسکوفى فى عمر يوم على عليقة ضابطة لمدة  أسبوعين ثم قسمت عشوائيا الى ٥ مجموعات بکل منها عدد  ١٢ بطة. غذيت المجموعة الاولى على عليقة ضابطة بينما غذيت باقى المجموعات الاربعة على علائق تحتوى ٥ ٬١٠٬ ١٥ ٬ ٢٠٪ من زرق الدواجن الجاف. کانت جميع العلائق متساوية فى الطاقة ( ٣٠٠٠ کيلو کالورى طاقة ممثلة/کجم عليقة) والبروتين (١٦٪ بروتين خام) طبقا للاحتياجات الموصى بها فى الجداول القياسية إن آر سى 1994. استمرت التغذية لمدة عشرة أسابيع. تم تقدير کل من وزن الجسم الحى و مقدار الزيادة المطلقة فى وزن الجسم ومعدل استهلاک الغذاء ومعدل التحويل الغذائى وکفاءة استخدام کل من البروتين والطاقة وکذلک تقدير بعض مکونات الدم و صفات الذبيحة وحساب معدل النفوق والکفاءة الاقتصادية. وقد أوضحت نتائج التجربة أنهلايوجد نفوق فى کل من المجموعة الضابطة وکذلک المجموعات المغذاة على علائق تحتوى ٥ ١٠٬ ٪  من زرق الدواجن الجاف بينما سجلت المجموعات المغذاه على علائق تحتوى ١٥٪ ,٢٠٪  نسبة نفوق تعادل ٨٫٣٣ , ٢٥ ٪ کما أوضحت النتائج أنه لا توجد فروق معنوية في مقاييس الأداء ونسبة التصافي ونسبة الأحشاء الداخلية للذبيحة بين طيور المعاملات المختلفة والضابطة. کما إتضح أيضا أنه لا توجد فروق معنوية فى مقاييس دم کل من  الطيور المختبرة والضابطة. وقد خلصت النتائج الى ان اضافة زرق الدواجن الجاف حتى ١٠ ٪ فى علائق البط المسکوفى النامى يؤدى الى تخفيض تکاليف العليقة بدون أى تأثير سلبى على الأداء بالاضافة الى التخلص من الأثار الضارة على البيئة التى قد تنتج من تراکم کميات کبيرة من هذه المخلفات.

Summary

 

The present study was performed to investigate the effect of feeding different levels of dried poultry waste (DPW) as untraditional ration constituent on duck performance, carcass traits and some blood biochemical constituents. 60 unsexed one day old Muscovy ducklings were fed ad-libitum on a control starter diet until 2 weeks of age. At that time, they were wighed and randomly distributed into 5 groups each of 12 ducklings. The first group was considered as a control (T1) and was fed ad libitum on a grower/ finisher diet. The other four groups (T2, T3, T4 & T5) were fed diets containing DPW at levels of 5, 10, 15 and 20% respectively. All diets were formulated to be isocaloric (3000 kcal/kg ME), isonitrogenous (16% CP) as recommended by NRC (1994) for growing ducks. The experiment was extended for 10 weeks. The body weight development, body weight gain, feed intake, feed conversion ratio, protein efficiency ratio and caloric efficiency ratio were determined. In addition, some blood constituents, carcass traits, mortality rate and economical evaluation were also measured. The results showed that, there were no mortalities in control group and groups fed diets with 5 and 10% DPW. However groups fed on diets with 15% and 20% dried poultry waste recorded 8.33% and 25.0% mortality rate, respectively. There were no significant differences, in performance measurements between control group and other treatments. There were no significant differences between control group and other treatments in carcass dressing percentage and relative percentage of internal organs. Also, there were no significant differences in blood parameters between control group and other treatments. It could be concluded that, addition of dried poultry waste to the duck diets up to 10% leads to decrease in the cost of the ration without any adverse effect on the duck performance and may help to alleviate pollution problems.

 

Key words: Ducks, feeding, dried poultry waste, performance.

 

Introduction

 

In the developing countries in particular increases in population practically erodes increases in food production leaving no hope of ever having surplus grains to compound economically viable livestock feeds (Christopher et al., 1997 and Onimisi, 2005). Generally, feed accounts for upward of 60% of the total costs of raising farm animals. Shortage of the conventional feedstuffs like maize and soybeans (which has led to the high costs of feeds for livestock) is occasioned by the competition between man and livestock for these feed sources (Vander Zijpp, 1997).In Egypt, a considerable attention has been paid to use such untraditional cheap and good feedstuffs in formulating animals and poultry diets to achieve a suitable efficiency of utilization and economic efficiency of production to overcome the feed shortage of livestock. Increasing poultry production through low cost feeds will therefore be of immense contribution to the quest for increased animal protein supply in most of our developing countries. There is therefore an urgent need for alternative locally available and cheap sources of feed ingredients particularly those that do not attract competition in consumption between human and livestock. Much efforts are being made to study the possibilities of utilizing poultry manure in the nutrition of animals including poultry (Henuk and Dingle, 2002). This can lead to a reduction of traditional feed ingredients such as maize, wheat and soybeans that can be consumed by humans and considered as animal feeds (El-Boushy and Van der Poel, 2000). In addition, utilization of animal excreta for feed nutrients may help to alleviate pollution problems, decrease feed costs and increase the supplies of available nitrogen and essential mineral sources (Arndt et al., 1979).In feeding poultry wastes to livestock, the first limiting factor is energy, the secondary limiting factor is a high ash content which limits the level of poultry wastes that can be used. The nutritive value of poultry droppings is dependent on producing species, age of waste, feeding plan of producing animal, housing and management system and handling, storage and processing of waste (Smith, 1981). Dried poultry manure after proper treatment could be used as feedstuff because it contains microorganisms able to convert some of uric acid to microbial protein can be utilized by poultry         (El-Boushy and Vink, 1977). The present study was carried out to evaluate the effects of feeding dried poultry waste on performance, carcass traits and some blood biochemical parameters of ducklings.

 

Materials and methods

 

Birds and housing

60 Muscovy ducklings of one-day old were obtained from local commercial source and were fed ad libitum on a control starter diet until 2 weeks of age. At that time, all ducklings were weighed and randomly distributed into 5 equal groups, each of 12. Birds had a similar initial average weight (402.53±10.17g). Birds were housed in a room previously disinfected with 4% formalin and divided into compartments each of 2m2 floor area and bedded with a layer of chaffed wheat straw. Experimental compartments were equipped with a cylindrical galvanized feeder, waterers, thermostatically controlled heaters and ventilation fans to maintain room temperature and air flow. Birds were vaccinated at      7 days of age against Avian Influenza Virus (H5N2). The prophylactic measures were taken to control diseases and to increase the viability of the birds. The experiment was carried out in Dept. of animal and clinical nutrition, Assiut University, Egypt.

Diets and feeding

Five levels of dried poultry waste (DPW; 0, 5, 10, 15 and 20%) were added to the diets of T1, T2, T3, T4 and T5 groups, respectively during the period from 2 - 12 weeks of age. Poultry waste used in this study was dried and processed as reported by Fontenot and Webb (1975). Diets were formulated to contain approximately the same crude protein (16%) and metabolizable energy (3000 kcal/kg diet) levels as recommended by NRC (1994). The leg banded ducklings in the five groups were fed ad libitum on the respective diets in mash form and given free access to fresh and clean water throughout the experimental period. The composition and metabolizable energy value of the ingredients and the experimental diets are presented in tables 1 and 2.

 

Table 1: Chemical composition (%) and metabolizable energy value of the ingredients

DPW*

 

Dried

Fat

Wheat

Bran

Fish

meal

Soybean

meal

Yellow

Corn

               Ingredients

 

    Items                                 

93.20

96.25

91.00

95.00

91.12

88.50

Dry matter

25.00

4.68

14.51

39.50

45.00

8.60

Crude protein

4.06

55.98

5.45

14.50

3.28

4.68

Ether- extract

15.36

3.36

11.00

0.81

6.55

2.22

Crude fiber

28.28

11.23

55.49

1.88

30.44

71.89

Nitrogen free-extract

20.50

21.00

4.55

38.31

5.85

1.11

Ash

4.48

2.75

0.18

5.36

0.36

0.03

Calcium

1.29

0.42

1.35

2.25

0.66

0.31

Total phosphorus    

0.41

0.00

1.73

1.37

2.69

0.26

Lysine

0.16

0.00

0.50

0.50

0.62

0.18

Methionine

2252

5271

1647

2712

2372

3390

ME (kcal/kg diet)**

  * DPW= Dried poultry waste                                                                                                                                   

** ME calculated, according toJanssen (1989) and Carpenter and Clegg (1956).

Table 2: Composition of the experimental diets

 

Treatments

(Dried poultry waste)

 

 

Ingredients

T5

20%

T4

15%

T3

10%

T2

5%

T1

0%

 

54.92

7.47

4.00

7.50

5.28

20.00

0.33

0.11

0.09

0.30

 

55.96

9.35

4.00

9.71

5.22

15.00

0.33

0.06

0.07

0.30

 

55.25

11.18

4.00

12.84

6.00

10.00

0.33

0.03

0.07

0.30

 

51.07

12.84

4.00

17.90

8.50

5.00

0.33

0.00

0.06

0.30

 

43.02

14.44

4.00

24.96

12.90

0.00

0.33

0.00

0.05

0.30

Physical composition (%)

Yellow corn, ground

Soybean meal

Fish meal

Wheat bran

Dried fat

Poultry waste, dried

Common salt

Lysine

Methionine

Premix*

 

90.57

16.00

7.56

5.82

53.06

8.13

1.31

0.74

0.65

0.30

3000

187.5

 

90.42

16.00

7.57

5.43

54.10

7.32

1.10

0.67

0.65

0.30

3000

187.5

 

90.39

16.00

8.00

5.15

54.53

6.71

0.91

0.66

0.65

0.30

3000

187.5

 

90.51

16.00

9.33

5.03

53.67

6.48

0.77

0.68

0.68

0.30

3000

187.5

 

90.84

16.00

11.64

5.11

51.38

6.71

0.68

0.71

0.72

0.30

3000

187.5

Chemical composition (%)

Dry matter

Crude protein

Ether- extract

Crude fiber

Nitrogen free-extract

Ash

Calcium

phosphorus Total

Lysine

Methionine

ME (kcal/kg diet)

Calorie/protein ratio

 

  * Each 2.5 kg contains: Vit. A, 12000000 IU; Vit. D3, 2000000 IU;Vit. E, 10 g; Vit. k3, 2g; Vit. B1, 1g; Vit. B2, 5 g; Vit. B6, 1.5 g; Vit. B12, 10 g; Nicotinic acid 30 g; Pantothenic acid 10g; Folic acid 1g; Biotin 50 g; Choline chloride 5o % 250 g; Iron 30 g; Copper 10 g; Zinc 50 g; Manganese 60 g; Iodine 1g; Selenium 0.1.

 

Measurements

                                                                                                                                                                                                                                   

Body weight development (g) and feed intake (g) of ducklings were recorded on 7-days interval until 12 weeks of age. Mortality rate was also monitored on group basis. Feed conversion ratio, protein efficiency ratio (PER) and caloric efficiency ratio (CER) were calculated. The proximate analysis of the experimental feeds was performed using procedures detailed by the Official Analytical Chemistry (AOAC, 1990). Calcium in prepared samples was determined in g/kg by using test kits supplied by BIOGAMMA-ITALYCompany after the method described by Kaplan and Pesce (1996) using colorimetric spectrophotometer. Phosphorus was determined in g/kg using the test kits supplied by LABKIT company after the method described byYoung (2001).

 

Carcass traits

At the end of the experiment, three birds from each group were slaughtered after fasting overnight, processed and the weight of carcass, gizzard, proventriculus, liver, spleen and heart were recorded. Dressed carcass is the weight of the slaughtered birds after removal of feathers, head and feet but including all edible offals. The organs weight was expressed as relative weight proportionate to pre-slaughter live body weight.  

 

Blood samples and biochemistry

Blood samples were collected from the slaughtered birds, allotted to clot at ambient temperature, centrifuged for 15 minutes at 3000 rpm and then extracted. The serum samples were kept at -20 0C until biochemical parameters were measured. Serum total protein and uric acid was determined using commercial kits (SGM ItaliaCompany) based on the methods outlined byKaplan and Pesce (1996). Serum albumin was determined using commercial kits (BIOCON Company) after the method described by Marshall (1989). Serum urea was determined using commercial kits (DP International Company) based on the methods outlined by Patton and Crouch(1977).

 

Statistical analysis

Statistical analysis of the obtained data was carried out according to procedures of completely random design SPSS (2001).

 

Results

 

The results in table 3 indicated that, there was no significant difference in body weight and weight gain between control and tested groups, however, a significant difference was found between tested groups. The values of feed intake and feed conversion were increased with increase the level of DPW, however, PER and CER were decreased. Groups fed diets with 15 and 20% DPW had a mortality percentage of 8.33 and 25.0%, respectively.   

 

 

Table 3: Performance and mortality rate of ducks fed different levels of dried poultry waste

Dried poultry waste (%)

 

Item

 

T5

20

T4

15

T3

10

T2

5

T1

0

400±17.4

2979±113.9b

2548±72.6b

11156

4.38

1.43

0.076

25.00

400.2±17.1

3075±87.6b

2694±79.2b

11053

4.10

1.52

0.081

08.33

404.2±27.8

3425±110.5 a

3021±68.4a

11975

3.96

1.58

0.084

00.00

408.3±22.9

3367±47.7 a

2959±76.8a

11370

3.84

1.63

0.087

00.00

400±29.5

3218±82.8ab*

2818±89.2ab

10741

3.81

1.64

0.087

00.00

  Initial weight

  Final weight

  Weight gain (g)

  Feed intake (g)

  Feed conversion

  Protein eff. ratio

  Caloric eff. ratio

  Mortality rate  

 

* Means within the same row with different superscripts are significantly different      (P < 0.05).

 

Data in table 4 indicated that, serum total protein, albumin, globulin, albumin/globulin ratio, urea and uric acid in ducks were not significantly affected by feeding different levels of dried poultry waste.

  

Table 4:  Blood parameters of ducks in the experiment

 

 

Item

Dried poultry waste (%)

T1

0

T2

5

T3

10

T4

15

T5

20

Total protein g/dl

 

Albumin g/dl

 

Globulin g/dl

 

Alb/Glob ratio

 

Urea mg/dl

 

Uric acid mg/dl

4.78±0.04

 

2.23±0.03

 

2.54±0.01

 

0.88±0.03

 

  24.41±0.23

 

5.75±0.03

4.47±0.03

 

  1.96±0.01

 

  2.50±0.02

 

  0.79±0.003

 

  24.66±0.04

 

5.45±0.03

4.92±0.03

 

2.25±0.03

 

2.67±0.06

 

0.84±0.03

 

  24.90±0.05

 

5.44±0.05

4.62±0.04

 

2.08±0.02

 

2.53±0.07

 

0.82±0.03

 

  25.34±0.28

 

5.83±0.04

4.78±0.02

 

2.22±0.04

 

2.56±0.02

 

0.87±0.02

 

  27.10±0.05

 

5.94±0.03

 

Carcass traits including carcass weight, dressing percentages, weights of internal organs proportionate to pre-slaughter live body weight are revealed in table 5. There were no significant difference between different groups in these parameters.

Table 5: Carcass traits parameters of ducks in the experiment

 

 

Parameters

Dried poultry waste (%)

T1

0

T2

5

T3

10

T4

15

T5

20

 

Preslaughter, wt. (gm)

    Evacerated carcass (gm)

Carcass (%)

Dressing weight (gm)

Dressing (%)

Liver, %

Heart, %

Proventriculus,%

Gizzard, %       

Spleen, %

 

3433.33±261

2513±232

73.00±1.47

2710±259

78.69±1.91

2.24±0.13

0.85±0.08

      0.29±0.01

2.60±0.25

0.10±0.00

 

 

3411.67±198

2515.67±159

73.66±1.10

2713.33±156

79.55±0.64

2.75±0.26

0.76±0.01

0.28±0.06

2.51±0.69

0.10±0.00

 

3483.33±166

2538.67±144

72.86±1.73

2733.33±158

78.44±2.00

2.20±0.19

0.77±0.03

0.27±0.03

2.61±0.06

0.08±0.003

 

3416.67±120

2557±85

74.85±0.39

2761.67±77

80.87±0.57

2.67±0.33

0.87±0.02

0.36±0.01

2.48±0.33

0.09±0.00

 

2970±316

2222.33±233

74.33±0.28

2401.67±274

80.73±0.66

2.78±0.11

      0.80±0.03

0.28±0.06

2.83±0.19

0.08±0.00

 

            Economical evaluation of duck performance in the different experimental groups are presented in table (6). Groups fed diets with 5, 10 and 15% DPW had more economic feed efficiency and relative feed efficiency than control one. However group fed diet with 20% DPW shows the lowest economic feed efficiency.

 

Dried poultry waste (%)

 

                                   Item

 

T5

20

T4

15

T3

10

T2

5

T1

0

 

11.16

1.91

21.31

51.31

2.979

18.00

53.62

2.31

4.50

39.82

 

 

11.05

1.97

21.77

46.32

3.075

18.00

55.35

9.03

19.49

172.48

 

11.98

2.11

25.39

47.89

3.425

18.00

61.65

13.76

28.73

254.25

 

11.37

2.12

24.10

46.60

3.367

18.00

60.61

14.01

30.06

266.02

 

10.74

2.75

29.54

52.04

3.218

18.00

57.92

5.88

11.30

100

 

Average feed intake (kg/bird)

Price/kg feed (L.E)

Total feed cost (L.E)

Total production cost (L.E)

Body weight (kg/bird)

Price/kg body weight (L.E)

Total revenue (L.E)

Net revenue (L.E)

Economic feed efficiency ( % )

Relative economic feed eff.

Table 6: Economical evaluation of ducks in the experiment

  

Discussion

 

Growth performance

The results obtained in table 3 indicated that, the final body weight and weight gain of ducks fed diets with 5 and 10% dried poultry waste were significantly (P < 0.05) higher than those fed diets with 15 and 20% dried poultry waste. The results are in agreement with that reported by Hady (1989); Momtaz and Abidur (1990); Nambi et al. (1992); Attia et al. (1993 ) and Olorede et al. (1995)  who recorded that, the level of DPW between 10 and 20% could be included in broiler diets with no adverse effect on performance. On the contrary, these results was disagreed with that reported by Adeyemo and Oyejola (2004) who revealed that growth of broiler chicks was progressively decreased as the amount of dried poultry waste was increased from 5 to 20%. The generally better growth performance achieved by birds fed DPW might have contributed to the unidentified growth factor reported to be present in poultry waste. The finding also revealed that, body weight and body weight gain of ducks fed diets with 15 and 20% DPW were lower than in other groups. The adverse effect of the high level of DPW may be attributed to 2/3 of the nitrogen in DPW is uric acid which has been shown to be unavailable and possibly toxic to the ducks. The variability in the effect of DPW on growth rate of ducks may be ascribed to the quality of the undegraded protein in the droppings and to the extent to which the diets meets the requirements of the ducks.

The data related to the feed intake were agreedwith that found by Momtaz and Abidur (1990)who found that, there was no significant difference in feed intake between duckling groups fed on diets contained 0, 5, 10 or 15% poultry droppings. Moreover, Udedibie and Omekam (2001) found that, feed intake of broilers fed diets contained 0, 5, 10, 15 and 25% DPW were significantly (P< 0.05) decreased only at the level of 25%. At the same time, the finding results disagreed with that reported by Ali et al. (1995) who recorded that inclusion of poultry manure in the broiler diet up to 20% might reduced or increased the feed intake. The increase in feed intake in our results with higher levels of DPW in the diet may be attributed to the higher crude fibre content of DPW.

The inclusion of dried poultry waste at the levels of 0, 5, 10, 15 and 20% to the diets of growing ducks did not significantly (P > 0.05) influence the feed conversion ratio at any growth phase. A result which was in line with earlier findings of Momtaz and Abidur (1990) who reported that, there were no significant differences in feed conversion between duckling groups fed on diets contained 0, 5, 10 or 15% poultry droppings. There were no significant differences in FCR among diets containing DPW at the level of 5-30% (Biely and Stapleton, 1976 and Gahain et al., 1993). On the contrary, the present results disagreed with that reported by pervious studies (Adeyemo and Oyejola, 2004) who concluded that, FCR was significantly decreased by the adding of DPW to the broiler diets. The slight decrease in FCR in our results may indicate that, DPW was lower in energy than we had estimated in formulating rations.

There were no significant difference in protein efficiency ratio and caloric efficiency ratio between the control and tested groups throughout the experimental period. The value of PER and CER were decreased by increasing the level of dried poultry waste in the diets. Birds fed diet with 20% DPW recorded the lowest one. These results were agreed with that found by Saikia et al. (1988) who found that, PER was decreased with increasing the levels of DPW in the diets of broiler chickens. On the contrary, Ali et al. (1995) reported that, the PER increased with increasing the level of DPW. Regarding mortality rate, ducks fed diet with 0, 5 and 10% dried poultry waste had no mortalities during the experiment while, feeding diets with 15 and 20% DPW were accompanied by 8.33 and 25.0% mortalities, respectively. These data agreed with that found by Mosaad et al. (2005) who reported that broiler chicken fed 15% dried poultry waste having a mortality rate of 25%.On thecontrary, the results disagreed with that reported by Biely and Stapleton (1976) and Elizabeth et al. (1978) who found that, mortality rate was negligible when broiler chicks were fed on diets with 0, 5, 10, 15 and 20% dried poultry waste.

Blood parameters

The results in table 4 illustrated that, there were no significant differences in the blood parameters between groups fed different levels of dried poultry waste. These results were agreed with that reported by El-Kerdawy et al. (1993) and Abdel-Azeem et al. (2007) who found that, total protein and its fractions and urea did not differ significantly when dried layer manure was added up to 30% in rabbit diets.Panda et al. (2007) reported that, sun dried caged layer manure up to 10% in the diet of broiler chickens did not influence serum concentration of albumin and globulin. However, the concentration of serum protein decreased and that of uric acid increased by incorporation of sun dried caged layer manure at 7.5% in the diet. Abdel-Azeem et al. (2007) found that, rabbits fed diets with 15% dried broiler manure gave the highest significant (P< 0.05) value for plasma proteins, while the lowest value was recorded with rabbit received the control diets. In addition, there were no significant effect (P > 0.05) in values of albumin, globulin, A/G ratio and urea between the rabbits given different dietary levels of two manures (dried broiler manure and dried layer manure ) when compared with those fed control diet.

Carcass trait parameters

The data in table 5 revealed that, the dressing % and relative percentage of internal organs of ducks fed on DPW was strikingly similar to that of the control diet. The diets were isocaloric which did not led to significant differences in dressing. These results are in agreement with those obtained by Adeyemo & Oyejola (2004) and Mosaad et al. (2005) and Abdel-Azeem et al. (2007) who showed that, dietary DPM did not affect neither dressing percentage nor percentage of internal organs in broilers and growing rabbits.El-Deek et al. (1995) found that, there were no significant differences among groups of muscovy duckling fed on 10% sun dried layer manure in the dressing percentage and weights of the internal organs.

Economical evaluation

Data in table 6 showed that, the price/kg feed was decreased with increasing the level of dried poultry waste. It was observed that, duck groups fed diets containing DPW at levels 5, 10 and 15% had higher economic feed efficiency (EFE) when compared to those received the control diet. However, ducks fed diet with 20% DPW had lower economic feed efficiency. The results are in agreement with that reported by Momtaz and Abidur (1990) who found that, feeding of ducks on diets containing 15% poultry droppings was economic and had no side effect. It could be concluded that, addition of dried poultry waste to the duck diets up to 10% leads to decrease in the cost of the ration without any adverse effect on the duck performance.

 

References

 

Abdel-Azeem, F.; El-Bordeny, N.E. and Khorshed M.M. (2007): Efficacy of biogen in improving the utilization of dried poultry manure in rabbit diets. Egypt. J. of Rabbit Science, 17 (1):  119-138.

Adeyemo, A.I. and Oyejola, O. (2004): Performance of Guinea fowl Numida Meleagris fed varying levels of poultry droppings. International J. of Poultry Science, 3 (5): 357-360.

Ali, Y.; Saikia, A.; Baruah, K.K. and Saikia, B.N. (1995): Evaluation of dehydrated poultry manure as feed ingredients for broilers. J. of the Assam Veterinary Council, 5: 25-27.

A.O.A.C. (1990): Official Methods of Analysis. Association of Official Analytical Chemists, 15th Edition, Washington, D.C.USA.

Arndt, D.L.; Day, D.L. and Hotfield, E.E. (1979): Processing and handling of animal excreta for refeeding. Journal of Animal Science, 48 (1): 157-161.

Attia, F.M.; AL-Sobayel, A.A.; Bayoumi, M.S. and Haroun, I.Y. (1993): Body composition of two commercial strains subjected to early feed restriction or feeding with dried chick excreta. Anim. Sci and Tech. 44 (1-2): 85-91.

Biely, J. and Stapleton (1976): Recycled dried poultry manure in chick starter diets. Br. Poult. Sci.; 17: 5.

Carpenter, K.J. and Clegg, K.M. (1956): The metabolizable energy of poultry feedingstuffs in relation to their chemical composition. J. Sci. Food Agri., 7: 45-51.

Christopher, D.; Pierre, C. and Claude, C. (1997): The impact of livestock and fisheries on food availability and demand in 2020. American J. of Agriculture Economics, 79 (5):         1471-1475.

El-Boushy, A.R. and Vink, F.W.A (1977): The value of dried poultry waste as a feedstuff in broiler diets. Feedstuffs, 49 (51): 24-26.

El-Boushy, A.R.Y. and Van Der Poel, A.F.B. (2000): Hand book of poultry feed from waste: Processing and Use, 2nd edition, Kluwer Academic Publishers, Dordrecht.

El-Deek, A.A.; Attia, Y.A.; El-Samra, A.E.; Marfat Saleh, E. and Aser, M.A. (1995): Influence of feeding layer manure and rumen content on growing duckling performance. Egypt. Poult. Sci., 15: 169-203.

Elizabeth, V.K.; Venugopalan, C.K. and Unni, A.K.K. (1978):Utilisation of dried poultry manure in broiler rations. Kerala Journal of Veterinary Science, 9 (2): 235-240.

El-Kerdawy, D.M.A.; Ahmed, S.S. and Ibrahim, H. (1993): Effect of feeding layers manure on growth, slaughter traits, physiological aspects and nutrients digestibility in meat rabbits. Egyptian Journal Rabbit Science, 3 (1): 55-71.

Fontenot, J.P. And Webb, K.E. (1975): Health aspects of recycling animal wastes by feeding. J. Anim. Sci., 40: 1267.

Gahain, A.K.; Siakia, A.; Konwar, B.K. and Ahmed, H.F. (1993): Utilisation of sun-dried poultry litter waste in broiler ration. Poultry Adviser, 26 (6): 39-43.

Hady, Maha, M. (1989): Influence of feeding diets containing dried poultry manure on broiler performance. Zagazig. Vet. J. (7, 4): 116-125.

Henuk, Y.L. and Dingle, J.G. (2002): Poultry wastes: Current problems and solution. In: Global perspective in livestock waste managements: Proceeding of the 4th International Livestock Waste Management Symposium and Technology Expo, Penang, Malaysia, 19-23 May 2002, pp. 101-111.

Janssen, W.M.M.A. (1989): European Table of Energy Values for Poultry Feedstuffs. 3rd ed. Beekbergen, Netherlands. SpelderholtCenter for Poultry Research and Information Services.

Kaplan, L.A. and Pesce, A.J. (1996): “Clinical Chemistry”, Mosby Ed.

Marshall, W.J. (1989): Illustrated Textbook of Clinical Chemistry, 3rd ed.  London, Gower Medical Publishing, 207-218.

Momtaz, M. and Abidur, R. (1990): Effect of partial replacement of calorie and protein in the rations of ducklings with poultry droppings. Bangladesh Journal of Animal Science, 19 (1&2): 45-52.

Mosaad, G.M.; Abdel-Raheem, H.A. and Sayed, A.N. (2005): Dried poultry droppings as a non conventional feed ingredient in broiler diets. Assuit Vet. Med. J., 51(106): 67-83.

Nambi, J.; Mbugua, P.N. and Mitaru, B.N. (1992): The nutritive evaluation of dried poultry excreta as a feed ingredient for broiler chickens. Animal Feed Sci. and Technology, 37 (1-22): 99-109.

N.R.C. (1994): Nutrient requirements of poultry. 9th ed NationalAcademy press, Washington, D.C., USA.

Olorede, B.R.; Ajagbonna, O.P. and Babatunde, G.M. (1995): Comparison of air-dried and oven-dried poultry droppings in broiler rations. Effect of performance, organ weights and hematological parameters. International Journal of Animal Science, 10: 289-293.

Onimisi, P.A. (2005): Evaluation of ginger waste meal as energy source in the diets of broiler chicken. M. Sci. Thesis submitted to the Department of Animal Science, AhmaduBelloUniversity, Zaria, Nigeria.

Panda, A.K.; Rao, S.V.R. and Raju, M.V.L.N. (2007): Dietary incorporation of sun dried cage layer manure on performance of broiler chickens. Indian Journal of Animal Science, 77(12): 1326-1329.

Patton, C.J. and Crouch, S.R. (1977): Anal. Chem., 49: 464-469.

Saikia, B.N.; Saikia, A.; Baruah, K.K.; Das, P.C. and Saikia, G.K. (1988): Dried poultry manure and dried cow dung manure in combination as feed substitutes in broiler rations. Poultry Adviser, 21 (5): 21-25.

Smith, L.W. (1981): Research needs on the utilization aspects of the feeding of animal waste. Journal of Animal Science, 52:     902-905.

SPSS 11 (2001): Statistical Software Package Program Social Science. Spss. Inc. USAS

Udedibie, A.B.I. and Omekam, V.N. (2001): Nutritional and health implications of dietary inclusion of dried poultry waste (DPW) for broilers. Agro-Science - Journal of Tropical Agriculture, Food, Environment and Extension, 2 (1): 24-29.

Vander Zijipp, A.J. (1997): Animal Food Production. The perspective of human consumption, production, trade and disease control. Livestock Production Science. 58: 199-206.

Young, D.S. (2001): Effects of disease on Clinical Lab. Tests. 4th ed. AACC.

 

 

 

 

 

 

 

 

 

 

 

 

 

References
 
Abdel-Azeem, F.; El-Bordeny, N.E. and Khorshed M.M. (2007): Efficacy of biogen in improving the utilization of dried poultry manure in rabbit diets. Egypt. J. of Rabbit Science, 17 (1):  119-138.
Adeyemo, A.I. and Oyejola, O. (2004): Performance of Guinea fowl Numida Meleagris fed varying levels of poultry droppings. International J. of Poultry Science, 3 (5): 357-360.
Ali, Y.; Saikia, A.; Baruah, K.K. and Saikia, B.N. (1995): Evaluation of dehydrated poultry manure as feed ingredients for broilers. J. of the Assam Veterinary Council, 5: 25-27.
A.O.A.C. (1990): Official Methods of Analysis. Association of Official Analytical Chemists, 15th Edition, Washington, D.C.USA.
Arndt, D.L.; Day, D.L. and Hotfield, E.E. (1979): Processing and handling of animal excreta for refeeding. Journal of Animal Science, 48 (1): 157-161.
Attia, F.M.; AL-Sobayel, A.A.; Bayoumi, M.S. and Haroun, I.Y. (1993): Body composition of two commercial strains subjected to early feed restriction or feeding with dried chick excreta. Anim. Sci and Tech. 44 (1-2): 85-91.
Biely, J. and Stapleton (1976): Recycled dried poultry manure in chick starter diets. Br. Poult. Sci.; 17: 5.
Carpenter, K.J. and Clegg, K.M. (1956): The metabolizable energy of poultry feedingstuffs in relation to their chemical composition. J. Sci. Food Agri., 7: 45-51.
Christopher, D.; Pierre, C. and Claude, C. (1997): The impact of livestock and fisheries on food availability and demand in 2020. American J. of Agriculture Economics, 79 (5):         1471-1475.
El-Boushy, A.R. and Vink, F.W.A (1977): The value of dried poultry waste as a feedstuff in broiler diets. Feedstuffs, 49 (51): 24-26.
El-Boushy, A.R.Y. and Van Der Poel, A.F.B. (2000): Hand book of poultry feed from waste: Processing and Use, 2nd edition, Kluwer Academic Publishers, Dordrecht.
El-Deek, A.A.; Attia, Y.A.; El-Samra, A.E.; Marfat Saleh, E. and Aser, M.A. (1995): Influence of feeding layer manure and rumen content on growing duckling performance. Egypt. Poult. Sci., 15: 169-203.
Elizabeth, V.K.; Venugopalan, C.K. and Unni, A.K.K. (1978):Utilisation of dried poultry manure in broiler rations. Kerala Journal of Veterinary Science, 9 (2): 235-240.
El-Kerdawy, D.M.A.; Ahmed, S.S. and Ibrahim, H. (1993): Effect of feeding layers manure on growth, slaughter traits, physiological aspects and nutrients digestibility in meat rabbits. Egyptian Journal Rabbit Science, 3 (1): 55-71.
Fontenot, J.P. And Webb, K.E. (1975): Health aspects of recycling animal wastes by feeding. J. Anim. Sci., 40: 1267.
Gahain, A.K.; Siakia, A.; Konwar, B.K. and Ahmed, H.F. (1993): Utilisation of sun-dried poultry litter waste in broiler ration. Poultry Adviser, 26 (6): 39-43.
Hady, Maha, M. (1989): Influence of feeding diets containing dried poultry manure on broiler performance. Zagazig. Vet. J. (7, 4): 116-125.
Henuk, Y.L. and Dingle, J.G. (2002): Poultry wastes: Current problems and solution. In: Global perspective in livestock waste managements: Proceeding of the 4th International Livestock Waste Management Symposium and Technology Expo, Penang, Malaysia, 19-23 May 2002, pp. 101-111.
Janssen, W.M.M.A. (1989): European Table of Energy Values for Poultry Feedstuffs. 3rd ed. Beekbergen, Netherlands. SpelderholtCenter for Poultry Research and Information Services.
Kaplan, L.A. and Pesce, A.J. (1996): “Clinical Chemistry”, Mosby Ed.
Marshall, W.J. (1989): Illustrated Textbook of Clinical Chemistry, 3rd ed.  London, Gower Medical Publishing, 207-218.
Momtaz, M. and Abidur, R. (1990): Effect of partial replacement of calorie and protein in the rations of ducklings with poultry droppings. Bangladesh Journal of Animal Science, 19 (1&2): 45-52.
Mosaad, G.M.; Abdel-Raheem, H.A. and Sayed, A.N. (2005): Dried poultry droppings as a non conventional feed ingredient in broiler diets. Assuit Vet. Med. J., 51(106): 67-83.
Nambi, J.; Mbugua, P.N. and Mitaru, B.N. (1992): The nutritive evaluation of dried poultry excreta as a feed ingredient for broiler chickens. Animal Feed Sci. and Technology, 37 (1-22): 99-109.
N.R.C. (1994): Nutrient requirements of poultry. 9th ed NationalAcademy press, Washington, D.C., USA.
Olorede, B.R.; Ajagbonna, O.P. and Babatunde, G.M. (1995): Comparison of air-dried and oven-dried poultry droppings in broiler rations. Effect of performance, organ weights and hematological parameters. International Journal of Animal Science, 10: 289-293.
Onimisi, P.A. (2005): Evaluation of ginger waste meal as energy source in the diets of broiler chicken. M. Sci. Thesis submitted to the Department of Animal Science, AhmaduBelloUniversity, Zaria, Nigeria.