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Effect of ground Prosopis juliflora pods in layers’ diets on feed intake, laying performance and egg quality

Kidane Hintsa, Mebrahtom Niguse, Mehari Gidey1, Gebremedhn Beyene, Tetemke Kidane, Tikabo Gebremariam, Mulubrhan Balehegn and Solomon Abera

Mekelle University, Department of Animal, Rangeland and Wildlife Sciences, P O Box 231, Mekelle, Ethiopia
kidanehintsa@gmail.com
1 Maichew Agricultural Technical Vocational and Educational Training College, Tigray, Ethiopia

Abstract

An experiment was carried out to study the effects of raw and roasted Prosopis juliflora pod (PJP) at different inclusion levels on egg laying performance. Bovans Brown layers (n=168), aged 24-weeks were used in a completely randomized design with seven treatments, each replicated three times with 8 birds per replicate. In the control treatment (CTL), chickens were fed 100% concentrate while on the other treatments, ground Prosopis juliflora pods were included at different levels i.e. roasted at levels of 10% (PJR10), 20% (PJR20), 30% (PJR30), and raw pods at 10 % ( PJ10), 20% (PJ20) and 30% (PJ30). Data on feed intake, Hen Day Egg Production (HDEP), egg weight and egg mass were recorded. Egg quality parameters were determined every week on 2 eggs per replicate.

There were no differences in feed intake, body weight gain, egg weight and egg quality parameters among treatments of raw and roasted PJP. The results suggest that raw and roasted Prosopis juliflora pods can be included in layer diets up to 30% without negative effect on health and performance.

Key words: legume trees, local feed resources, processing, roasting


Introduction

Poultry production as part of the livestock sector plays a vital role of socio-economic importance in Ethiopia (Metaferia et al 2011; Tadelle and Ogle 2001). Almost every household owns chickens that are used as a source of income, nutrition and spending of time in rearing especially children and elders (Tadelle et al 2003). The chicken population in the country is estimated to be 59.5 million, with 91, 5 and 4 percent reported as indigenous, hybrid and exotic, respectively (CSA 2017). However, the economic contribution of the sector is low as compared to the huge number of chickens. This is due mainly to shortage of feed in addition to other management constraints (Fisseha et al 2010).

The use of agricultural and agro-industrial byproducts for livestock feed formulation results in fluctuation in quantity, quality and prices of the manufactured feed (Anyanwu et al 2008). There has been much interest over recent years to explore alternative feedstuffs because of rising costs for conventional feed ingredients. Therefore, using non-conventional feedstuffs as an alternative feed resource is vital (Gebregiorgis et al 2012). Utilization of Prosopis juliflora pods in livestock feeding is one possibility (Hinsa et al 2015; Admasu 2008).

Prosopis juliflora is known for invading millions of hectares of land which were under different land use systems in Africa, Asia, Australia and South America (Pasiecznik 1999; Mehari 2008). Regardless of its invasiveness, it is a potential resource for providing feed of small ruminants in the pastoral areas (Abdelnoor et al 2010). Similarly, Meseret et al (2011) indicated that Prosopis juliflora pods (PJP) can be included up to 20% in layers’ ration, but when the inclusion level reached 30% the egg mass, weight and feed to egg mass ratio were reduced (Silva et al 2002). Little is known about the effect of treatment such as roasting on nutritional and chemical properties of the pods. This study was therefore conducted to investigate the effect of raw and roasted PJP inclusion in layers’ rations on feed intake, laying performance and egg quality.


Materials and methods

Research site

The research was conducted at Mekelle University poultry farm. The University is located at 13o 27 N 39o 01E, and at an altitude range of 2000 to 2200 masl. The area has a semi-arid climate with annual rainfall range of 500 - 700 mm. Annual temperature ranges from 20 to 40oC.

Birds, design and treatments

Bovan’s brown pullets (n=168), aged 24 weeks, were allocated to seven dietary treatments in a completely randomized design with 24 hens in each treatment, which were further divided into three replicates, each with 8 birds. The birds were adapted to the experimental diets for 7 days before data collection over 90 days.

The dietary treatments were raw PJP at rates of 0, 10, 20 and 30% and roasted PJP at 10, 20 and 30% levels described as PJR10, PJR20 and PJR30. Dietary treatments were formulated to be iso-caloric and iso-nitrogenous.

Feed preparation

Roasted and raw Prosopis juliflora pods, soybean meal, wheat bran, noug seedcake (Guizotiaa byssinica), limestone, salt and vitamin premix were used. Prosopis juliflora pods were collected from Alamata district, Tigray. The pods for PJR treatments were roasted at 80 oC for 30 minutes using a locally made steel plate and heated by wood flame. The pods were ground in a hammer mill with a sieve size of 2mm. The other ingredients were purchased from Mekelle local market.

Management

Birds were vaccinated against Newcastle Disease, infectious bronchitis, infectious bursal disease, fowl pox and fowl typhoid. They were housed in experimental pens partitioned using wire-mesh. The concrete floor was covered with 6-10 cm depth of wheat straw as litter. Water was provided ad libitum throughout the experiment period. Individual laying nests, covered with wheat straw, were placed in each pen and artificial light used for 16 hours per day throughout the experiment. Feed was offered twice a day at 0800 and 1500h


Chemical analysis

Feed samples were analyzed for dry matter, ether extract (EE), crude fiber (CF), crude protein (CP), Ca, P and ash following the proximate analysis procedures (AOAC 1990).

Feed intake and body weight

Feed offered and refused was recorded daily. Body weights were taken at the commencement of the experiment and at weekly intervals throughout the study. Daily weight gains and feed conversion ratio (FCR) were calculated based on the standard procedures.

Egg production

Eggs were collected three times a day. Egg production was calculated on a hen-day basis (Hunton 1995) as.

Egg weight and mass

Eggs collected daily were weighed immediately and average egg weight was calculated.

Egg mass (g/hen/day) = Number of egges x average weight/ Number of hens

Egg shell quality

After breaking the eggs on a flat tray, the weights of shells were measured. Shell thickness was measured using electronic digital calipers after removing the membrane from the egg shell. The egg shell thickness was the mean of the three measurements at blunt, middle and sharp points of the egg.

Albumen weight, height and Haugh Unit

Albumen height was measured immediately after breaking the eggs using electronic digital caliphers and the weight was computed by deducting the yolk weight and shell weight from egg weight. Haugh unit was calculated from albumin height and egg weight using the formula of Haugh (1937).

HU = 100 log (AH +7.6–1.7 EW0.37); Where HU = Haugh unit

AH = Albumen height, EW = Egg weight

Yolk quality

Yolk diameter and height were measured using electronic digital calipers after separation of the yolk from the albumen. The weight of the yolk was measured by sensitive balance. Yolk index was estimated in percentage, taking the ratio of their respective heights to the average diameter (breadth and length) using the following formula.

Where: YI=Yolk index, YH=Yolk height, YD= Yolk diameter

The yolk color was compared with the Roche color fan. After removal of the yolk membrane, the whole yolk was thoroughly mixed and a sample was taken on a piece of white paper and compared with Roche fan measurement strips.

Data analysis methods

Except yolk color, which was analyzed by logistic regression, all other parameters were subjected to analysis of variance (ANOVA) using the General Linear Model procedures of the Statistical Analysis System (SAS 2004). Differences between treatment means were separated using Tukey Test at 5% probability level. Regression analysis was made to see the response of DM intake and egg shell weight to the inclusion level of Prosopis juliflora pod in the diet.


Results

Chemical composition of feeds (Table 1).

Table 1. Composition of ingredients and diets (DM basis except for DM which is on air-dry basis)

DM

CP

EE

Ash

CF

Ca

P

ME #

Maize grain

90

8

4.5

2.2

2.4

0.04

0.29

3893

WS

86

15.6

3.6

6.2

9.2

0.011

0.02

3077

NSC

92.9

36.8

8.16

5

16

0.144

0

2771

PJP

88.3

18

1.91

1.92

1.92

0.33

0.44

3806

SBM

88.8

39.6

21.3

6.7

6.3

0.32

0.61

4277

Treatments

PJ0

90.2

17

2.6

5.7

6.7

0.17

3.27

2816

PJR10

90.38

17

2.6

5.43

5.98

0.21

3.3

2800

PJR20

90.27

16.89

2.7

5.17

5.18

0.25

3.33

2800

PJR30

89.86

16.31

2.5

4.71

4.38

0.28

3.35

2721

PJ10

90.38

17

2.6

5.43

5.98

0.21

3.3

2800

PJ20

90.27

16.89

2.7

5.17

5.18

0.25

3.33

2800

PJ30

89.86

16.31

2.5

4.71

4.38

0.28

3.35

2721

DM = % dry matter; CP = crude protein; EE = ether extract; CF = crude fiber; Ca= calcium; P= phosphorus; ME# = metabolizable energy; PJP= Prosopis juliflora pod; PJR = Prosopis juliflora roasted; NSC=noug seed cake; MG=maize grain; WS=wheat short; SBM=soybean meal

Dry matter intake, egg production and quality

There was a decreasing tendency for DMI in both raw and roasted treatments (Table 2). Hen day egg production (HDEP), egg mass and feed conversion also showed a descending pattern as the inclusion of PJP increased.

Egg shell weight showed ascending pattern with increment of PJP (Table 3). Egg weight, egg shell thickness, Haugh unit values, albumen and yolk quality traits did not show variation across treatment diets (Table 3).

The effect of Prosopis juliflora on DM intake and egg shell weight is presented in Figures 1 and 2. The egg shell weight increased with the increased level of Prosopis juliflora pod in the diet. In contrast, the DM intake decreased slightly with the increased level of Prospis juliflora pod across the treatments.

Figure 1. Response of egg shell weight to inclusion level of Prosopis juliflora pod in the diet


Figure 2. Response of DM intake to inclusion level of Prosopis juliflora pod in the diet 


Table 2. Dry matter intake, body weight gain and egg laying performance of Bovans Brown hens fed different levels of raw and roasted PJP

Parameters

PJ0

PJR10

PJR20

PJR30

PJ10

PJ20

PJ30

SEM

p

Initial BW (g)

1430

1453

1462

1416

1454

1458

1404

3.9

0.98

Final BW (g)

1918

1930

1980

1917

1957

1937

1961

3.5

0.91

BW gain (g/)

487

477

517

501

503

479

556

3.6

0.89

DMI (g)

90.9

91.5

90.7

89.8

90.6

89.6

88.9

0.63

0.67

EM (g/hen/d)

37.0

34.6

34.0

33.5

33.1

32.1

32.6

2.73

0.44

Egg wt (g)

55

54.8

54.6

54.5

54.4

54.3

54.2

0.28

0.51

HDEP (%)

42.5

41.05

40.83

40

41.16

39.50

40.3

1.36

0.25

FCR (g feed /gegg)

2.68

2.66

2.53

2.53

2.53

2.56

2.50

0.09

0.15



Table 3. External and internal egg quality traits of laying hens fed different levels of raw and processed PJP

PJ0

PJR10

PJR20

PJR30

PJ10

PJ20

PJ30

SEM

p

Egg weight (g)

55

54.8

54.65

54.52

54.47

54.35

54.25

0.28

0.5120

Shell weight (g)

5.36b

5.46ab

5.56ab

5.65ab

5.75ab

5.85a

5.86a

0.16

0.0070

Shell thickness (mm)

0.32

0.33

0.33

0.33

0.34

0.35

0.35

0.04

0.290

Albumen height (mm)

8.28

8.06

8.02

8.05

8.08

7.98

7.94

0.3

0.992

Albumen weight (g)

33.83

33.64

33.51

33.38

33.31

33.2

33.17

0.35

0.905

Yolk height (mm)

15.52

15.45

15.48

15.43

15.44

15.36

15.35

0.21

0.988

Yolk weight (g)

15.81

15.69

15.58

15.48

15.4

15.3

15.21

0.29

0.807

Yolk color score

3.29

3.43

3.5

3.6

3.71

3.78

3.85

0.26

0.661

Yolk diameter (mm)

3.65

3.62

3.58

3.52

3.5

3.46

3.44

0.12

0.101

Yolk index

0.42

0.43

0.43

0.44

0.44

0.44

0.45

0.05

0.419

Haugh unit

92.42

92.23

92.1

91.83

91.67

91.42

91.22

0.44

0.839

abcd means within a row with different superscripts are different (p<0.05)


Discussion

The study showed that there was no variation in chemical composition of raw and roasted PJP. The CP content of PJP (18.5%) was within the range of 12.1-23.3% CP as reported by Himsa et al (2015) and comparable with the findings of Chaturvedi and Sahoo (2013) (18.3%) but higher than the value 9 – 17% reported by Shukla et al (1984). The 88.3 % DM of PJP is lower than the value 91.81% reported by Meseret et al (2011). The difference in nutrient contents of PJP across various studies could be attributed to the variation in plant variety, soil conditions, climatic factors, plant’s growing environment, harvesting stage, storage condition and processing.

There was a tendency for increase in DM intake and egg shell weight with the increase of Prosopis juliflora pod in the diet. This indicates that PJP can be included in layer diet up to 30% without negative effect on feed utilization and egg production. Similarly, Yusuf et al (2008) also found no effect on feed intake of broilers fed on prosopis seed meal in different levels and forms (raw and processed). In contrast, Meseret et al (2011)reported differences in DM intake of layers fed on diets with different ground PJP inclusion levels. This might be attributed to the pod processing method and fiber content of the diets. In the current study no sifference was observed in HDEP for layers fed on roasted and raw PJP. This indicates the concentration of anti-nutritive factors due to inclusion of PJP was within the tolerable range of the layers. There was no variation detected in egg weight due to different inclusion levels of PJP. Similarly, egg mass did not show variation due to PJP inclusion. In contrast to these findings, Silva et al (2002) reported reduced egg mass with a 30% inclusion level of PJP fed to layer hens. No difference was observed on feed conversion ratio of birds fed on processed and raw PJP. This result is in line with findings of Meseret et al (2011), from layers fed on different levels of ground PJP diets.

Egg shell thickness did not vary among the chickens fed on raw and processed PJP, but a difference was seen on egg shell weight (Table 3). An increment trend was observed in egg shell weight as the level of pod meal increased from 0% to 30% for both roasted and raw prosopis diets.  The lowest shell weight (5.36 g) was seen in eggs collected from the control birds (no pod meal).

Albumen weight, height and Haugh unit (HU) of the eggs did not vary with level of raw and processed PJP in the diet. Absence of difference in these parameters among the treatments indicates that inclusion of raw and processed PJP up to 30% does not affect HU values. Lower hen day egg production and egg mass at 30% GPJP inclusion level of roasted and raw PJP is consistent with the finding of Meseret et al (2011) who reported similar result in Bovans Brown commercial layers fed 30% ground Prosopis juliflora meal.

Except for egg yolk color, differences were not apparent in egg quality parameters in this study. The results were in line with the values reported for Bovans Brown breeds by Swiatkiewicz et al (2010). The result of egg quality of this study indicated that Prosopis juliflora pod can be included up to 30% in layers’ ration without negative effect on egg quality.


Conclusion


Acknowledgment

The authors would like to thank Mekelle University for financial and logistic provision to undertake this research. Mr. Amanuel Berhe is acknowledged for providing poultry farm facilities for the experiment.


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Received 16 September 2019; Accepted 14 December 2019; Published 2 January 2020

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