Research Article

 

Castor and Propolis Extracts as Antibiotic Alternatives to Enhance Broiler Performance, Intestinal Microbiota and Humoral Immunity

 

Hany M.R.Elsherif1, Ahmed Orabi2, Abdallah S. Ali3, Ahmed Samy4*

1Animal Production Department, Faculty of Agriculture, Cairo University, Giza, Egypt; 2Microbiology Department, Faculty of Veterinary Medicine, Cairo University, Giza, Egypt; 3Agricultural Microbiology Department, Faculty of Agriculture, Cairo University, Giza, Egypt; 4Animal Production Department, National Research Centre, 12622, Dokki, Cairo, Egypt.

 

Received | January 09, 2021; Accepted | January 28, 2021; Published | March 30, 2021

*Correspondence | Ahmed Samy, Animal Production Department, National Research Centre, 12622, Dokki, Cairo, Egypt; Email: Asamy1@yahoo.com

Citation | Elsherif HMR, Orabi A, Ali A.S., Samy A (2021). Castor and propolis extracts as antibiotic alternatives to enhance broiler performance, intestinal microbiota and humoral immunity. Adv. Anim. Vet. Sci. 9(5): 734-742.

DOI | http://dx.doi.org/10.17582/journal.aavs/2021/9.5.734.742

ISSN (Online) | 2307-8316; ISSN (Print) | 2309-3331

Copyright © 2021 Samy et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

 

INTRODUCTION

 

The antibiotic used as growth promoter from the 1940s, when researchers found that animals eaten dried mycelia, which was containing chlortetracycline residues, enhanced their performance. This enhanced of the animal performance related to the effect of antibiotic on the intestinal microbiota. (Castanon 2007, Niewold, 2007). Nevertheless, it is dangerous to use antibiotic because it induce bacterial resistance in both animals and human consumers. Thus the European Union banned the uses of antibiotics as a growth promoter since January 1, 2006 also it was been banned except with a veterinary prescription by FDA in 2012 (Laxminarayan et al., 2016).

 

Therefore, these prompted researchers to search for a new trend for preventing the infection by pathogenic bacteria and act as a growth promoter. Thus, using a natural antimicrobials like plant extracts as an alternative to the traditional antimicrobial (Rampadarath and Puchooa, 2016).

 

Most of plant extracts still be studied to adding in animal nutrition instead of antibiotic as a growth promotion, especially after increase the restriction of using antibiotic in animal diets, which is induce resistance and persistence in addition to environmental contamination (Ventola, 2015).

 

Natural feed additives could be used as a growth promoter to enhance broilers performance instead of antibiotic (Hassan et al, 2016 and 2018).

 

Also some of plant extracts have highly effect to eliminate bacteria or stunt bacterial growth such as Salmonella when addition these to animal diets (Castillo-López et al., 2017). Castor bean (Ricinus communis L.), growing extensively in both tropical and subtropical regions of the world (Zarai et al., 2012). It has an importance crop because it has highly active compounds like castor oil, which reach in ricinoleic acid and mixtures of volatile secondary metabolites, that support uses of it as antimicrobial (Kiran and Prasad, 2017; Salih et al., 2019). Castor extract showed the highly antimicrobial activity against most pathogenic bacteria included both gram positive and negative bacteria for example E. coli, Bacillus cereus, P. aeruginosa, and Listeria innocua (Rampadarath and Puchooa, 2016). In addition, it has approximately 75% antifungal activities (Das and Satyaprakash, 2018). Bess et al. (2012) found that the addition of castor oil-CNSL mixture (0.15%) to the broiler diets from 1-21 d of age lead to enhanced the broiler performance, which might caused by the antimicrobial effect of these functional oil. Using of castor oil and cashew shell extract in the diet of coccidiosis challenged broilers resulted in enhanced body weight gain and feed conversion ratio (Murakami et al., 2014).

 

Monensin (conventional antibiotic) could be replaced with essential oils of castor bean in beef cattle diets without influencing feed intake, digestibility, ruminal fermentation or microbial proteins synthesis. (Coneglian et al., 2019). Valero et al. (2016) concluded that castor oil could be used instead of antibiotic in diets of cattle to improve performance and feed efficiency.

 

Moraes et al. (2019a) reported that adding of the castor and cashew extracts to the broiler diets (0.15%) improved the BWG in the first week, but BWG did not significantly change compared to the other treatment groups in the second week after infection with Eimeria spp. The castor and cashew extracts groups exhibited increased gene expression of interferon (IFN), interleukin 6 (IL-6) and tumor necrosis factor (TNF), while the control group exhibited increased expression of cyclooxygenase (COX) and IL-1. Which these modulated the inflammatory response against Eimeria spp., thus the functional oil is an effective tool in specifically modulating the immune system of birds afflicted with coccidiosis.

 

Moraes et al. (2019b) concluded that the use of functional oil (castor and cashew shell extracts) in broiler diets (0.15% inclusion) from 1-28 days improved the performance in similar to those receiving the ionophore monensin. The castor and cashew shell extracts acting as a modulator of the intestinal microbiota, with antimicrobial action against gram-positive bacteria, mainly C. perfringens and S. aureus.

 

Propolis (bee glue) is a dark resinous material that honey bees (Apis mellifera L.) collect from tree buds and the exudates of plants and then chew and digest through oral enzymes (Seven et al., 2010).

 

Propolis is a dim resinous material that bees gather from tree buds and the plants exudates and afterward digest it by enzymes of oral (Seven et al., 2010). Propolis could improve the poultry performance, via enhancing nutrient digestibility and absorption; which stimulating saccharase, amylase and phosphatase activities (Marieke et al., 2005).

 

Kacaniova et al. (2013) and Krocko et al. (2012) found that increased of the beneficial bacteria count (such as Enterococci (8.65 cfu/g) and Lactobacilli (8.83 cfu/g)) while decreased the pathogenic bacteria count in the intestine of the broilers fed a diet containing propolis (0.2 or 0.6 g/kg feed). concluded that the addition of propolis and bee pollen to the broiler diets enhanced this intestinal microbiota. Kleczek et al. (2014); Hascik et al. (2016); Khan, (2017) and Zafarnejad et al. (2017) found that the broiler fed diets supplemented with propolis was enhanced the performance comparable to those supplemented these diet with antibiotic. Shaddel-Tili et al. (2016) and Shreif and El-Saadany (2017) found that weight gain is directly proportional to the increase in the percentage of propolis addition to the broiler diets.

 

Therefore, this study was conducted to investigate the influence of Castor extract, propolis extract and the mixture of them as antibiotic alternatives for growth promoter in broiler diets on performance, intestinal parameters, intestinal microbiota and the immune response.

 

MATERIALS AND METHODS

 

Birds, housing and management

The experiment was conducted at Poultry Nutrition Research Unit (PNRU), Agriculture College, Cairo University, Giza, Egypt. A total 250 one day old male Arbor acres broiler chicks with initial weight about 40 g were randomly allocated at semi close house in clean three deck batteries and divided into 5 groups, 50 chicks each with 5 replicates. The cages diameter was 0.50*1.0m with nipple drinkers. Birds were raised in a heated house during starter (1-14 day) and the temperature was decreased gradually to meet grower (14-28 day) and finisher (28-35 day) period’s needs. Light was given 23 h every day all through the experimental period. Feed and water were given ad libitum. An immunization program against avian influenza, New Castle, IB and IBD was carefully embraced all through the experimental period.

 

Experimental Materials

I) Castor extract (CE): Extraction of castor beans method were, heat reflux extraction by 70% ethanol for 3h with vigorous stirring after that separation of the extract by rotary evaporator at 40°C.

II) Ethanolic propolis extract (PE) was purchased from the Economic Entomology Department, Faculty of Agriculture, Cairo Cairo University, Egypt.

III) Antibiotic: Terramycin (oxytetracycline 40%) IM® from local market.

 

Experimental design and diets

A total 250 one day old male Arbor acres broiler chicks were partitioned into five gatherings, five replicates of ten chicks each. The group one (control) was received the basal starter, grower and finisher diets according to Arbor acres recommended levels (Table 1). The groups from 2 to 5 were control diets supplemented with 1g antibiotic/Kg diet, 1.5 g CE/Kg diet, 1.5 g PE/Kg diet and mixture of 0.75 g CE and 0.75 g PE/Kg diet, respectively. Addition levels of castor and propolis extracts according to Bess et al. (2012); Murakami et al. (2014) and Moraes et al. (2019a,b).

 

Measured Parameters

(I) Growth performance parameters: At the end of different stages (starter,14d; grower,28d and finisher,35d) all chicks were weighted and recorded the feed consumption (g/chick), then calculate the average weight gain and feed conversion ratios (g feed/g weight).

 

(II) Slaughter test:

At the 35th day old, five birds with weight near to the gathering average for every treatment were chosen to examine the carcass, weight of immune organs, intestinal parameters, intestinal microbiota and immune response. After birds overnight fasting, the life body weights were recorded, also the carcass weight, liver, spleen, heart, thymus, bursa and gizzard were recorded after slaughtered and feathered. Calculated the percentages of live body weight for liver, gizzard and heart for each bird individually (Mohamed et al., 2016). Immune organs index were calculated by the equation (weight of organ /body weight) ×1000.

 

(III) Intestinal parameters:

Length and diameter: Measured the length of intestine (duodenum, jejunum and ileum) and diameter in the center of the ileum on five birds from each treatment, at 35th day of age (Dahiya et al., 2005).

 

Intestinal lesion score: opened and scored the small intestine from a five birds of each treatment on a scale from zero to four, Zero is a normal intestinal appearance with no lesion, One half is severely congested serosa and mesentery engorged with blood, One is a thin walled and friable intestines with small red petechiae (>5), Two is a focal necrotic lesions, Three is patches of necrosis (1 to 2 cm-long), and Four refer to diffused necrosis typical of field cases (Dahiya et al., 2005).

 

(IV) Intestinal microbiota:

Enumeration of Lactic acid bacteria: Transferred one gram of fresh digesta samples from the ileum and caecum to 9ml MRS broth and serially diluted in 10-fold increments. Plated 0.1 ml from the last three diluted samples individually on MRS agar (Oxoid, CM0361) then incubated at 39oC for 48 h (Micro aerobic). (Dahiya et al., 2005).

 

:Intestinal colonization of C. perfringens

Taken 0.2 g of intestinal contents from five birds of each treatments individually the make a serial dilution in sterile PBS to 1:100, 1:1000, and 1:10000 after that 0.1 ml of each dilution was poured on the surface of sheep blood agar plates and tryptose sulfite-cycloserine (TSC) agar (supplemented by D-cycloserine) with egg yolk emulsion. After 24h of anaerobic incubation at 37°C, typical C. perfringens colonies (black colonies) on TSC agar or large dome-shaped colonies with a double zone of hemolysis on blood agar plates were counted as CFU (colony-forming units) per gram. (Carrido et al., 2004).

 

(V) Immune status assessment:

For determination of the effect on immunity. The blood serum samples used in hemagglutination inhibition (HI) test for determining antibody titers against ND and H5 vaccine. Expressed all titers as log of the reciprocal of highest dilution indicating hemagglutination (Swayne et al., 1998).

 

(VI) Statistical analysis:

General Liner Model of SAS (one-way analysis of variance) was used to statistical analyzed of data (SAS, 2004). Duncan’s new multiple range test at (P<0.05) was used to separate the significant differences among treatment means (Duncan, 1955).

 

Table 1: Formulation and nutrients composition of the starter, growr and finisher diets.

 

Ingredients %	Starter (1-14 days)	Grower (14-28 days)	Finisher (28-35 days)
Yellow corn Soybean meal (44%) Corn gluten meal (60%) Soybean oil Mono calcium phosphate Limestone Vitamin & Mineral mix(1) Nacl L-lysine HCl DL-methionine Threonine NaHCO3 Choline chloride Phytase Energy enzymes	55.60 34.00 4.50 1.50 1.00 1.80 0.30 0.30 0.30 0.26 0.15 0.17 0.10 0.01 0.01	58.73 30.00 4.40 2.80 0.90 1.57 0.30 0.30 0.33 0.26 0.12 0.17 0.1 0.01 0.01	62.80 25.86 4.50 3.00 0.85 1.46 0.30 0.30 0.33 0.20 0.11 0.17 0.1 0.01 0.01
Total	100	100	100
Calculated composition (2) Crude protein % ME (Kcal/Kg) Ether extract% Crude fiber% Lysine % Methionine % Methionine + Cystine % Threonine % Calcium % Nonphytate P % Sodium% Chlorine%	23.02 2949 3.99 3.66 1.34 0.64 1.01 0.97 0.98 0.38 0.18 0.22	21.47 3076 5.38 3.45 1.26 0.61 0.97 0.88 1.00 0.35 0.18 0.22	20.01 3138 5.71 3.25 1.16 0.54 0.87 0.81 0.81 0.33 0.18 0.22

(1) Vitamin - mineral mixture supplied per Kg of diet: Vit A, 12000 IU; Vit D3, 2200 IU; Vit E, 10 mg; Vit K3, 2 mg; Vit B1, 1mg; Vit B2, 4mg; Vit B6, 1.5mg; Vit B12, 10g; Niacin, 20 mg; Pantothenic acid, 10 mg; Folic acid, 1 mg; Biotin, 50 g; Choline chloride, 500 mg; Copper, 10 mg; Iodine, 1mg; Iron, 30 mg; Manganese, 55 mg; Zinc, 50 mg and Selenium, 0.1 mg.

(2) According to NRC 1994.

 

Results

 

Growth performance: Results of growth performance of birds fed different dietary treatments (Control, Antibiotic, Castor extract (CE), Propolis extract (PE) and Castor and Propolis extracts mix (CE+PE)) during different stages and overall period are shown in Table 2.

 

At starter period data showed that no significant differences in birds performance were detected among all treatments compared to the control.

 

While in the grower period, only body weight gain (BWG) is significantly (P<0.05) improved in chicks fed diets containing CE and CE+PE compared to the control. While no significant differences were recorded in both, feed intake (FI) and feed conversion ratio (FCR).

 

At finisher period, Birds fed diet containing CE+PE showed significantly (p<0.05) enhanced BWG compared to the control. While significantly (P<0.05) improvement in FCR recorded in all treatments compared to control.

 

At overall period (1-35 days of age), the best BWG significantly (P<0.05) recorded from the chicks fed diets containing CE and CE+PE. In addition, the similarity of improvement of BWG recorded between the birds fed diets containing PE and antibiotic compared to the control. Also, significantly (P<0.05) improvements in FCR for birds fed diets containing CE, CE+PE or PE compared to control. No significant differences in FI was detected among all treatments compared to the control.

 

Carcass characteristics

Effect of dietary treatments on dressing percent, giblets and weight of the immune organs at 35-day of age are shown in Table 3.

 

Table 2: Effect of dietary treatments on growth performance {Weight gain, g (WG); Feed intake, g (FI) and feed conversion ratio, FI g/ WG g (FCR)} of broiler chicks during starter, grower, finisher and overall periods.

 

Item

Starter (1-14)*

Grower (14-28)

Finisher (28-35)

Overall period (1-35)

WG

FI

FCR

WG

FI

FCR

WG

FI

FCR

WG

FI

FCR

Control

309

389

1.26

894b

1149

1.27

469b

981

2.10a

1672c

2541

1.52a

Antibiotic

312

368

1.18

945ab

1155

1.23

505ab

963

1.92b

1762b

2520

1.43ab

Castor extract

335

382

1.14

961a

1162

1.21

506ab

945

1.87b

1807a

2512

1.39b

Propolis extract

317

355

1.12

945ab

1131

1.20

502ab

932

1.87b

1764b

2417

1.37b

Castor+Propolis

318

369

1.16

981a

1169

1.19

546a

957

1.76b

1845a

2528

1.37b

SE of means

±3.79

±3.74

±0.02

±9.31

±11.51

±0.01

±8.75

±10.82

±0.03

±14.33

±23.24

±0.02

Significances

NS

NS

NS

**

NS

NS

**

NS

***

***

NS

**

Means designated with the same letter within the same column are not significantly different at 0.05 level of probability, **p<0.01), ***P<0.001, NS: Not significant (P>0.05). * The beginning weight is 40g.

 

Table 3: Effect of dietary treatments on dressing percent, giblets (as percent of live body weight) and immune organs at 35-day of age.

 

Item	Carcass weight (g)	Dressing %	Giblets % (of LBW)				Immune organs index
			Liver	Heart	Gizzard		Spleen	Bursa	Thymus
Control	1305c	72.85	2.27	0.60	2.11		1.01	1.66	1.76
Antibiotic	1352bc	72.39	2.13	0.55	2.16		0.95	1.55	1.65
Castor extract	1393ab	73.73	2.12	0.56	1.98		0.97	1.63	1.96
Propolis extract	1363bc	72.78	2.10	0.58	2.28		1.06	1.63	1.83
Castor+Propolis	1426a	74.81	2.07	0.52	2.27		0.98	1.64	1.73
SE of means	±14.42	±0.47	±0.09	±0.01	±0.07		±0.06	±0.04	±0.07
Significances	***	NS	NS	NS	NS		NS	NS	NS

Means designated with the same letter within the same column are not significantly different at 0.05 level of probability, ***P<0.001, NS: Not significant (P>0.05).

 

Table 4: Effect of dietary treatments on intestinal length, diameter and lesion score of broiler chicks at 35 day of age.

 

Item	Intestinal length	Intestinal diameter	Intestinal lesion score
Control	145c cm	0.3c cm	1a
Antibiotic	152c cm	0.4c cm	1a
Castor extract	188a cm	1.2a cm	0b
Propolis extract	165b cm	0.4c cm	1a
Castor+Propolis extracts	192a cm	0.9b cm	0b
SE of means	±5.12	±0.09	±0.13
Significances	***	***	***

Means designated with the same letter within the same column are not significantly different at 0.05 level of probability, ***P<0.001.

 

 

No significant differences in dressing, giblets and immune organs weight were detected among all treatments compared to the control.

 

Carcass weight significantly (P<0.05) to be improved in birds fed CE and CE+PE compared to the control. The results indicated that no adverse effect of the CE or/and PE extracts on dressing %, giblets and immune organs index.

 

Effect of dietary treatments on the Intestinal length, diameter and lesion score of broiler chicks at 35 day of age.

Intestinal length and diameter: The effect of different dietary treatments on intestinal length (duodenum + jejunum + ileum) and diameter (in the middle of ileum) of broiler chicken at 35 day of age are shown in Table 4.

 

The results showed the significantly (P<0.05) improvement of the intestinal length in the birds fed diets containing CE, PE and PE+CE are being 188 cm, 165 cm, and 192 cm respectively compared to the 152 cm for antibiotic treatment and 145 cm for the control. In addition, the enhanced intestinal diameter recorded for the birds fed diets containing CE, and CE+PE 1.2 cm and 0.9 cm respectively. While the similar intestinal diameter recorded for the birds fed diets containing PE and antibiotic 0.4 cm compared to the control 0.3 cm.

 

Intestinal lesion score: The results of the intestinal lesion score showed in Table 4. The birds fed diets containing CE and CE+PE recorded zero on the scale of intestinal lesion score, which mean that the intestinal is normal appearance with no lesion. While the treatments for PE, antibiotic and control recorded one on the scale which mean that the intestinal is thin walled and friable intestines with small red petechiae (>5).

 

Effect of dietary treatments on the intestinal microbiota of broiler chicks at 35 day of age.

The results of the enumeration of lactic acid bacteria and intestinal colonization of C. perfringens are shown in Table 5. The results showed that the significantly (P<0.05) increased of the number of beneficial intestinal bacteria (lactic acid bacteria) in the birds fed diets containing CE and CE+PE are being 4X108 and 3X107, respectively. While the similarity of beneficial intestinal bacteria count in birds fed diets containing PE and control are being 4X104 and 5X104, respectively. However, the worst lactic acid bacteria count recorded for birds fed diets containing antibiotic 5X103. On the other hand the number of the intestinal colonization of C. perfringens (Pathogenic intestinal bacteria) recorded nil for the birds fed diets containing CE and CE+PE. Whereas birds fed diets containing PE and antibiotic recorded the pathogenic bacteria number similar to the control.

 

Table 5: Effect of dietary treatments on the Enumeration of Lactic acid bacteria and intestinal colonization of C. perfringens of broiler chicks at 35 day of age.

 

Item	Lactic acid bacteria	Colonization of C. perfringens
Control	5X104 c	2X102 c
Antibiotic	5X103 e	5X102 a
Castor extract	4X108 a	Nil d
Propolis extract	4X104 d	3X102 b
Castor+Propolis extracts	3X107 b	Nild
SE of means	±4X107	±51.35
Significances	***	***

Means designated with the same letter within the same column are not significantly different at 0.05 level of probability, ***P<0.001.

 

 

Effect of dietary treatments on the humoral immunity of broiler chicks at 35 day of age

The immune status assessment; the serum samples were subjected to haemagglutination inhibition (HI) test for determining antibody titers against Newcastle (ND) and avian flu (H5) vaccine are shown in Table 6.

 

Table 6: Effect of dietary treatments on the immune status assessment of broiler chicks at 35 day of age.

 

Item	Haemagglutination inhibition test
	Newcastle (ND)	Avian flu (H5)
Control	3.8c	4.3b
Antibiotic	4.1c	4.8a
Castor extract	5.5a	5.2a
Propolis extract	4.6b	3.8b
Castor+Propolis extracts	5.3a	4.9a
SE of means	±0.19	±0.18
Significances	***	*

Means designated with the same letter within the same column are not significantly different at 0.05 level of probability, *p<0.05), ***P<0.001, NS: Not significant (P>0.05).

 

The results showed the significantly (P<0.05) improvement in the immune status against both of ND and H5 vaccine in the birds fed diets containing CE and CE+PE. While the addition of PE to diets have a good immune response against ND but gave the similar immune response against H5 to the control. Also, Birds fed diets containing antibiotic gave a good immune response against H5 but have the similar immune response against ND to the control.

 

Discussion

 

These results clearly showed that the addition of CE and CE+PE to the broiler diets recorded the best improvements in growth performance; intestinal length; diameter and lesion also gave the best values in intestinal beneficial and pathogenic bacteria counts and finally determined the best immune response against the ND and H5 vaccine. On the other hand, these results showed that addition of PE gave the similar results to the addition of antibiotic to the diet. The enhanced occurred in the broiler performance could be due to the improvements in the intestinal length, diameter and microbiota which increase nutrient digestibility and absorption.

 

The intestinal development (length and diameter) is relative to the changes in growth performance, therefore, addition of the castor extract or the mixture of castor and propolis extracts may have positively influenced the growth performance by enhanced the development of the small intestine. The changes in the intestinal development were in accordance with the changes in the growth performance (Yin et al., 2017).

 

Therefore, the use of antibiotic as a growth promoter in broiler diets could be replaced with the highly safety materials such as CE, PE or the mixture of them which have the superior effect on the growth performance, intestinal parameters, intestinal microbiota and immune response compared to the antibiotic effect.

 

The results of enhanced performance observed in the present study by replacement of antibiotic by natural and safety extracts such as CE, PE and CE+PE are in accordance with many of previous studies. Mpraes et al. (2019 a,b) concluded that the use of functional oil (castor and cashew shell extracts) in broiler diets (0.15% inclusion) from 1-28 days improved the performance in similar to those receiving the ionophore monensin. The castor and cashew shell extracts acting as a modulator of the intestinal microbiota, with antimicrobial action against gram-positive bacteria, mainly C. perfringens and S. aureus. Valero et al. (2016) suggested that castor oil could be used instead of antibiotic in diets of cattle to improve performance and feed efficiency.

 

Propolis could improve the poultry performance, via enhancing nutrient digestibility and absorption; which stimulating saccharase, amylase and phosphatase activities (Marieke et al., 2005). The addition of propolis (0.05 g/Kg feed) to the broilers diets gave comparable performance to the other group, which fed a diet with antibiotic (Kleczek et al., 2014; Hascik et al., 2016). Shaddel-Tili et al. (2016) found that weight gain is directly proportional to the increase in dose of propolis in broiler diets.

 

Shreif and El-Saadany (2017) observed that gain of body weight increased with the increase in propolis level in diet on Bandarah chicks during the experimental periods. Khan, (2017) suggested that added of propolis in diets of broiler enhanced the growth. Zafarnejad et al. (2017) found that the body weight, average daily weight gain, feed intake, carcass characteristics were significantly higher in broilers fed diets with propolis compared to the control group.

 

Bess et al. (2012) found that the addition of castor oil-CNSL mixture (0.15%) to the broiler diets from 1-21 d of age lead to enhanced the broiler performance, which might caused by the antimicrobial effect of these functional oil. Using of castor oil and cashew shell extracts (0.15% inclusion) in the diet of coccidiosis challenged broilers resulted in enhanced body weight gain and feed conversion ratio (Murakami et al., 2014).

 

Coneglian et al. (2019) who found that monensin (conventional antibiotic) could be replaced with essential oils of castor bean in beef cattle diets without influencing feed intake, digestibility, ruminal fermentation or microbial proteins synthesis.

 

As well, the present results of the effect of dietary treatments on the intestinal length, diameter, lesion, the Enumeration of Lactic acid bacteria, intestinal colonization of C. perfringens and the immune status assessment of broiler chicks are in agreement with many of the previous studies. Some of plant extracts have highly effect to eliminate bacteria or stunt bacterial growth (e.g. Salmonella enterica serovar Typhimurium) when added to animal diets such as Castor extract (Castillo-López et al., 2017). Castor bean (Ricinus communis L.) has an importance crop because it has highly active compounds like castor oil, which reach in ricinoleic acid and mixtures of volatile secondary metabolites, that support uses of it is extract as antimicrobial (Kiran and Prasad, 2017; Salih et al., 2019). Castor extract showed the highly antimicrobial activity against most pathogenic bacteria included both positive and negative gram for example E. coli, P. aeruginosa, Bacillus cereus and Listeria innocua (Rampadarath and Puchooa, 2016). In addition, it has antifungal activities about 75% (Das and Satyaprakash, 2018). The changes in the intestinal development were in accordance with the changes in the growth performance (Yin et al., 2017).

 

Krocko et al. (2012) found that the supplemented of propolis and bee pollen to the broiler diets enhanced this intestinal microbiota. Kacaniova et al. (2013) reported that increased the beneficial bacteria count (Enterococci and Lactobacilli) while decreased the pathogenic bacteria count in the intestine of the broilers fed a diet containing propolis (0.2 or 0.6 g/kg feed).

 

Conclusion

 

The addition of either castor extract or castor and propolis extracts mix to the bird’s diets gave superior in all measurements than the addition of antibiotic. Furthermore, using of propolis extract gave the comparable results to the antibiotic treatment. Therefore, this more effective and safety materials have to use instead of using antibiotic as growth promoter in broiler diets.

 

acknowledgements

 

We gratefully thanks to:

1- Prof.dr. Osama Elhousiny, animal production deparment,Faculty of Agriculture, Cairo University.

2- The Poultry Nutrition Research Unit (PNRU), Faculty of Agriculture, Cairo University.

3- Animal Production department of National Research centre.

 

Conflict of Interest

 

The authors declare that there is no conflict of interest.

 

authors contribution

 

All authors contributed equally to study design methodology, interpretation of ressults, and writing of the manuscript.

 

References

 

• Bess F, Favero A, Vieira SL, Torrent J (2012). The effects of functional oils on broiler diets of varying energy levels. J. Appl. Poult. Res. 21(3): 567-578. https://doi.org/10.3382/japr.2011-00481

• Carrido MN, Skjerheim M, Oppegaard H, Sqrum H (2004). Acidified litter benefits the intestinal flora balance of broiler chickens. Appl. Environ. Microbiol. 70: 52085215. https://doi.org/10.1128/AEM.70.9.5208-5213.2004

• Castanon JIR (2007). History of the use of antibiotic as growth promoters in European poultry feeds. Poult. Sci. 86(11): 2466-2471. https://doi.org/10.3382/ps.2007-00249

• Castillo-López RJ, Gutiérrez-Grijalva EP, Leyva-López N, López- Martínez LX, Heredia JB (2017). Natural alternatives to growth-promoting antibiotics (GPA) in animal production. J. Anim. Plant Sci. 27(2): 349-359.

• Coneglian SM, Serrano RDC, Cruz OTB, Branco AF (2019). Effects of essential oils of Cashew and Castor on intake, digestibility, ruminal fermentation and purine derivatives in beef cattle fed high grain diets. Semina: Ciências Agrárias. 40(5): 2057-2070. https://doi.org/10.5433/1679-0359.2019v40n5p2057

• Dahiya JP, Hoehler D, Wilkie DC, Van Kessel AG, Drew MD. Dietary glycineconcentration affects intestinal Clostridium perfringens and Lactobacilli populations in broiler chickens. Poult. Sci. 2005;84:1875–85. https://doi.org/10.1093/ps/84.12.1875

• Das A, Satyaprakash K (2018). Antimicrobial properties of natural products: A review. Pharma. Innovat. J. 7(6): 532-537.

• Duncan DB (1955). Multiple range and multiple F tests. Biometrics. 11: 1-42. https://doi.org/10.2307/3001478

• Hascik P, Trembecká L, Bobko M, Kacaniova M, Čuboň J, Kunová S, Bučko O (2016). Effect of diet supplemented with propolis extract and probiotic additives on performance, carcass characteristic sand meat composition of broiler chickens. Potravinarstvo. 10: 223-231. https://doi.org/10.5219/581

• Hassan HMA, Samy A, El-Sherbiny AE, Mohamed MA, Abd-Elsamee MO. (2016). Application of nano-dicalcium phosphate in broiler nutrition: performance and excreted calcium and phosphorus. Asian J. Anim. Vet. Adv. 11(8): 477-483. https://doi.org/10.3923/ajava.2016.477.483

• Hassan HMA, Samy A, Youssef AW, Mohamed MA (2018). Using different feed additives as alternative to antibiotic growth promoter to improve growth performance and carcass traits of broilers. Inter. J. Poult. Sci. 17(6): 255-261. https://doi.org/10.3923/ijps.2018.255.261

• Kacaniova M, Haščík P, Arpášová H, Pavelková A, Petrová J, Hleba L, Rovná K (2013). Enterococcus genus identification isolated from gastrointestinal tract of chickens after bees products application using MALDI TOF MS Biotyper. Scientific Papers Anim. Sci. Biotechnol. 46(2): 114-118.

• Khan SH (2017). Recent advances in role of propolis as natural additive in poultry nutrition. J. Apic. Sci. 61(2): 167-183. https://doi.org/10.1515/jas-2017-0020

• Kiran BR, Prasad MNV (2017). Ricinus communis L.(Castor bean), a potential multi-purpose environmental crop for improved and integrated phytoremediation. EuroBiotech. J. 1(2): 101-116. https://doi.org/10.24190/ISSN2564-615X/2017/02.01

• Kleczek K, Wilkiewicz-Wawro E, Wawro K, Makowski W, Murawska D, Wawro M (2014). The effect of dietary propolis supplementation on the growth performance of broiler chickens. Polish J. Natural Sci. 29(2): 105-117.

• Krocko M, Čanigová M, Bezeková J, Lavová M, Haščík P, Ducková V (2012). Effect of nutrition with propolis and bee pollen supplements on bacteria colonization pattern in gastrointestinal tract of broiler chickens. Scient. Papers Anim. Sci. Biotechnol. 45(1): 63-67.

• Laxminarayan R, Matsoso P, Pant S, Brower C, Røttingen JA, Klugman K, Davies S (2016). Access to effective antimicrobials: a worldwide challenge. The Lancet, 387(10014): 168-175. https://doi.org/10.1016/S0140-6736(15)00474-2

• Marieke M, Blitterswijk H, Leven L, Kerkvliet J, Waerd J (2005). Bee products (properties, processing and marketing). Agrodok 42, NECTAR, Netherlands Expertise Centre for (sub) Trop. Apic. Resour. Pp: 33-35.

• Mohamed MA, Hassan HMA, Samy A, Abd-Elsamee MO, El-Sherbiny AE (2016). Carcass Characteristics and Bone Measurements of Broilers Fed Nano Dicalcium Phosphate Containing Diets. J. Anim. Vet. Adv. 11(8):484-490. https://doi.org/10.3923/ajava.2016.484.490

• Moraes PO, Andretta I, Cardinal KM, Ceron M, Vilella L, Borille R, Ribeiro AML (2019a). Effect of functional oils on the immune response of broilers challenged with Eimeria spp. Animal. 13(10): 2190-2198. https://doi.org/10.1017/S1751731119000600

• Moraes PO, Cardinal KM, Gouvêa FL, Schroeder B, Ceron MS, Lunedo R, Ribeiro AML (2019b). Comparison between a commercial blend of functional oils and monensin on the performance and microbiota of coccidiosis-challenged broilers. Poult. Sci. 98(11): 5456-5464. https://doi.org/10.3382/ps/pez345

• Murakami AE, C Eyng, J Torrent (2014). Effects of functional oils on coccidiosis and apparent metabolizable energy in broiler chickens. Asian Australas. J. Anim. Sci. 27:981–989 https://doi.org/10.5713/ajas.2013.13449

• Niewold TA (2007). The nonantibiotic anti-inflammatory effect of antimicrobial growth promoters, the real mode of action? A hypothesis. Poult. Sci. 86(4): 605-609. https://doi.org/10.1093/ps/86.4.605

• Rampadarath S, Puchooa D (2016). In vitro antimicrobial and larvicidal properties of wild Ricinus communis L. in Mauritius. Asian Pacific J. Trop. Biomed. 6(2): 100-107. https://doi.org/10.1016/j.apjtb.2015.10.011

• Salih TFM, Abdullah SA, Ali SI, Khder DK (2019). Antibacterial Effect of Fixed and Volatile Oils against Gram-positive and Gram-negative Bacteria. Kurdistan J. Appl. Res. 74-87.

• SAS (2004). SAS/STAT User’s Guide. Release 8.1, SAS Institute Inc., Cary, NC. USA., pp: 554.

• Seven I, Aksu T, Tatli SP (2010). The effects of propolis on biochemical parameters and activity of antioxidant enzymes in broiler exposed to lead induced oxidative stress. Asian-Australasian J. Anim. Sci. 23(11): 1482-1489. https://doi.org/10.5713/ajas.2010.10009

• Shaddel-Tili A, Eshratkhah B, Kouzehgari H, Ghasemi- Sadabadi M (2016). The effect of different levels of propolis in diets on performance, gastrointestinal morphology and some blood parameters in broiler chickens. Bulgarian J. Vet. Med. https://doi.org/10.15547/bjvm.986

• Shreif EY, El-Saadany AS (2017). Effect Of Supplementing Diet With Propolis On Bandarah Chicks’performance. Egypt. Poult. Sci. J. 37(1).

• Swayne DE, Glisson JR, Jackwood MW, Pearson JE, Reed WM (1998). A laboratory manual for the isolationand identification of avian pathogens.4 Ed, AmericanAssociation of Avian Pathologist Inc., Kennett Square, Pennsylvania. USA.p156-163.

• Valero MV, Farias MS, Zawadzki F, Prado RM, Fugita CA, Rivaroli DC, Prado IN (2016). Feeding propolis or essential oils (cashew and castor) to bulls: performance, digestibility, and blood cell counts. Revista Colombiana de Ciencias Pecuarias. 29(1): 33-42. https://doi.org/10.17533/udea.rccp.v29n1a04

• Ventola CL (2015). the Antibiotic Resistance Crisis Part 1: Causes and Threats. P T 40(4): 277-283.

• Yin LY, Wang ZY, Yang HM, Xu L, Zhang J, Xing H (2017). Effects of stocking density on growth performance, feather growth, intestinal development, and serum parameters of geese. Poult. Sci. 96(9): 3163-3168. https://doi.org/10.3382/ps/pex136

• Zafarnejad K, Afzali N, Rajabzadeh M (2017). Effect of bee glue on growth performance and immune response of broiler chickens. J. Appl. Anim. Res. 45(1): 280-284. https://doi.org/10.1080/09712119.2016.1174130

• Zarai Z, Ben Chobba I, Ben Mansour R, B´ekir A, Gharsallah N, Kadri A (2012). Essential oil of the leaves of Ricinus communis L.: in vitro cytotoxicity and antimicrobial properties. Lipids Health Dis. 11: 102. https://doi.org/10.1186/1476-511X-11-102