COMPARISON OF EFFICACIES OF FOSFOMYCIN, THIAMPHENICOL, NIGELLA SATIVA OIL AND ITS COMBINATION AGAINST ESCHERICHIA COLI INFECTION IN CHICKENS

Document Type : Research article

Authors

1 Department of Pharmacology, Faculty of Veterinary Medicine, Beni-Suef University

2 Department of Bacteriology, Mycology and Immunology, Faculty of Veterinary Medicine, Beni-Suef University

Abstract

The efficacies of fosfomycin, thiampheicol and Nigella sativa oil were compared against experimentally infected chickens with E.coli O111. One hundred and twenty six 12-day old broiler chickens were divided into seven groups:1st group was control non infected non medicated , 2nd group was infected with E.coli and non medicated, the 3rd group was infected with E.coli and treated with disodium fosfomycin (40mg/kg b.wt), the 4th group was infected with E.coli and treated with thiamphenicol (30mg/kg b.wt), the 5th group was infected with E.coli and orally administrated with Nigella sativa oil  (0.025 ml/bird), the 6th group was infected with E.coli and treated with disodium fosfomycin (40mg/kg b.wt), in addition to orally administration with Nigella sativa oil (0.025 ml/bird) and the 7th group was infected with E.coli and treated with thiamphenicol (30mg/kg b.wt) in addition to Nigella sativa oil (0.025 ml/bird). The performance, clinical signs, E. coli reisolation, antibacterial activity and the effect on immune response of chickens were compared. The treated groups showed fewer symptoms and gross lesions than those of infected group. The body weight and average daily gain were highly improved in the 6th, 7th and 5th group respectively. The combination of Nigella sativa oil with fosfomycin and thiamphenicol increase their antibacterial activity. The specific antibody titers against the E.coli O111 were significantly increased in the groups which received Nigella sativa oil. The results indicate that addition of Nigella sativa oil with fosfomycin or thiamphenicol increases their efficacy, antibacterial activity and immune response against E. coli O111.

Keywords


COMPARISON OF EFFICACIES OF FOSFOMYCIN, THIAMPHENICOL, NIGELLA SATIVA OIL AND ITS COMBINATION AGAINST ESCHERICHIA COLI INFECTION IN CHICKENS

 

ABEER M. RADI* and NESREEN A. IBRAHEEM**

* Department of Pharmacology, Faculty of Veterinary Medicine, Beni-Suef University

**Department of Bacteriology, Mycology and Immunology, Faculty of Veterinary Medicine, Beni-Suef University

Email:rouqaa2007@yahoo.com

 

 

 

ABSTRACT

 

 

Received at:14/12/2014

 

Accepted: 15/1/2015

 

The efficacies of fosfomycin, thiampheicol and Nigella sativa oil were compared against experimentally infected chickens with E.coli O111. One hundred and twenty six 12-day old broiler chickens were divided into seven groups:1st group was control non infected non medicated , 2nd group was infected with E.coli and non medicated, the 3rd group was infected with E.coli and treated with disodium fosfomycin (40mg/kg b.wt), the 4th group was infected with E.coli and treated with thiamphenicol (30mg/kg b.wt), the 5th group was infected with E.coli and orally administrated with Nigella sativa oil  (0.025 ml/bird), the 6th group was infected with E.coli and treated with disodium fosfomycin (40mg/kg b.wt), in addition to orally administration with Nigella sativa oil (0.025 ml/bird) and the 7th group was infected with E.coli and treated with thiamphenicol (30mg/kg b.wt) in addition to Nigella sativa oil (0.025 ml/bird). The performance, clinical signs, E. coli reisolation, antibacterial activity and the effect on immune response of chickens were compared. The treated groups showed fewer symptoms and gross lesions than those of infected group. The body weight and average daily gain were highly improved in the 6th, 7th and 5th group respectively. The combination of Nigella sativa oil with fosfomycin and thiamphenicol increase their antibacterial activity. The specific antibody titers against the E.coli O111 were significantly increased in the groups which received Nigella sativa oil. The results indicate that addition of Nigella sativa oil with fosfomycin or thiamphenicol increases their efficacy, antibacterial activity and immune response against E. coli O111.

 

 

Key words: E. coli O111, fosfomycin, thiamphenicol, Nigella sativa oil, ELISA.

 

 


INTRODUCTION

 

Escherichia coli is one of the most important and frequently encountered bacterial avian pathogens causing a wide variety of disease syndrome in birds causing up to 30% of poultry mortality (Geornaras    et al., 2001), also it is responsible for severe economic losses for the world's poultry industries (Barnes et al., 2008).

 

Avian pathogenic Escherichia coli induces different syndromes in poultry including systemic and localized infections such as  respiratory colibacillosis, acute colisepticemia with characteristics fibrinous lesions (air saculitis, perihepatitis, and pericarditis), salpengitis, yolk sac infection, and swollen-head syndrome (Dho-Moulin and Fairbrother, 1999). The infection is generally initiated or enhanced by predisposing agents, such as mycoplasmal or viral infections, and environmental factors. Chickens of all ages are susceptible to collibacillosis (Barnes et al., 2003).

 

Fosfomycin is a broad-spectrum bactericidal agent that attacks bacteria by inhibiting cell wall synthesis (Dàmaso, 1990). This antibiotic posses high activity in vitro against a wide range of Gram- positive bacteria such as Streptococcus sp., S. aureus and some Gram- negative bacteria such as Pseudomonas aerugenosa and E.coli (Tessier& Quentin, 1997; Grif et al., 2001). It is used in chickens for the treatment of infection caused by E.coli and Salmonella sp. (Prescott, 2000). Pharmacokinetics studies in broiler chickens have shown that fosfomycin sodium salt is a product very soluble in water, with low protein binding, and low molecular weight, which hinders its diffusion within tissues such as muscle or fat, reaching a high concentration in the kidney (Aramayona et al., 1997).

 

Thiamphenicol is a broad-spectrum bacteriostatic antibiotic, inhibiting the bacterial protein synthesis at the ribosome (Cannon et al., 1990). It is a structural analogues of chloramphenicol with lower toxicity, in addition to it has a greater in vivo activity against pathogenic bacteria than other structural analogues and it's also active against some bacteria that are resistant to chloramphenicol. It has been approved in European Union for use in cattle, sheep, pigs and chickens (Giorgi et al., 2000).

 

The antimicrobial agents of plant origin such as essential oils, plants extracts and complete plant substances, have gathered significant consciousness as alternatives to the traditional antibacterial feed additives. Extracts of Nigella sativa oil have shown promising effects against bacteria, fungi, viruses, parasitics and worms. Seed extracts of Nigella sativa were found to inhibit the growth of Escherichia coli, Bacillus subtilis and streptococcus faecalis (Hala      et al., 2006).

 

Supplementing broiler diets with Nigella sativa seed, oil or meal improve growth performance, biochemical and hematological response and mortality rate (Nofal et al., 2006). Feeding different forms and levels of NS has been reported to possess anti stress activity (Tolba and Hassan, 2003), antimicrobial activity (Nasir and Grashorn, 2006) and has a stimulatory effect on the immune system (Tolba et al., 2005).

 

This present study was designed to compare the efficacy of fosfomycin and thiamphenicol as antibacterial agents and their effects in combination with Nigella sativa oil for treatment of experimental infections with E. coli O111. Also, the effect of Nigella sativa oil on the immune response was investigated.

 

MATERIALS and METHODS

 

Birds

A total of 126 Hubbard broiler chicks, one-day old were floor reared under suitable conditions of husbandry. Commercial diets (antibacterial free) and water were provided ad libitum. The chicks were allowed a 5 days acclimatization period prior to the study.

 

Bacteria

The E. coli strain O111 was kindly supplied by Dokki animal health research institute. The bacteria were grown in BHI broth (Oxoid) for 24 hours at 37˚C and then on BHI agar (Oxoid) for 24 hours at 37˚C. To prepare the inoculums, the colonies were suspended in sterile saline and compared with McFarland 0.5 to obtain a concentration of 1.8 ×108CFU/ml.

 

Drugs:

Disodium fosfomycin, Thiamphenicol and its solvent (dimethylacetamide) were provided as pure powdered from (Pharma Swede Company, Egypt) and Nigella sativa oil was obtained from (Royal herbs, ltd company, Egypt).

 

Experimental design:

The 126 one-day old chicks were divided into seven groups (18 chicks each). At the 5th day of age the birds in 5th, 6th, 7th groups were orally administered with Nigella sativa oil daily till the end of the experiment (35 day of age). At the 12th day of age the chicks were experimentally infected with E. coli O111 (1ml of 1.8×108 CFU/ bird) and the treatment by fosfomycin and thiamphenicol began after 6 hours from infection and lasted for 5 successive days (Rawiwet et al., 2010) as the following.

 

The 1st group was left as control (non infected, non medicated), the 2nd group was infected with E. coli O111 and not medicated, the 3rd group was infected with E. coli O111 and treated with disodium fosfomycin in a dose of 40mg/kg b.wt (Gutierrez      et al., 2010) in drinking water, the 4th group was infected with E. coli O111 and treated with thiamphenicol in a dose of 30mg/kg b.wt (Switala     et al., 2007) in drinking water.

 

While the 5th group was infected with E. coli O111 and orally administrated with Nigella sativa oil in a dose of 0.025 ml/bird (by using plastic tube directly into the crop) (Hodžic et al., 2012). The 6th group was infected with E. coli O111 and treated with disodium fosfomycin in a dose of 40mg/kg b.wt in drinking water and orally administered with Nigella sativa oil in a dose of 0.025 ml/bird. The 7th group was infected with E. coli O111 and treated with thiamphenicol in a dose of 30mg/kg b.wt in drinking water and orally treated with Nigella sativa oil in a dose of 0.025 ml/bird.

 

The chicks were examined daily for clinical signs of the disease and mortality. The body weight of all chicken were determined at the beginning of the experiment and daily for 5 days during administration of the tested drugs then weekly till the end of experiment (35 day), also feed and water consumption were determined during the 5 days of medication to determine the feed conversion rate (FCR=feed intake (g)/ average weight gain (g) ) and also Average daily gain (ADG) was determined and calculated from the formula (ADG= weight gain (g)/ days).

 

Blood sample were taken from 5 birds from each group (from wing vein) in the first day of infection and medication and after 2 hour from administration of the drugs and/or oils and daily during the 5 days of medication for determination of the antibacterial activity of tested drugs  as diameter zone of inhibition against E coli O111. Also, the blood samples were collected from chicken of each group at 0, 7th, 15th and 21st day of infection for detection of the immune response against E. coli O111. The blood samples allowed to clot at room temperature for 30min., after which the sample were centrifuged at 3000 rpm for 15 min. The separated serum was decanted and immediately frozen at -20˚C until use.

 

Efficacy criteria:

The air sac, pericardial and perihepatic lesions of colisepticemia in each of the three sacrificed birds from each group at the 2nd, 5th, 8th and 10th day of the infection were scored. According to Charleston et al., 1998, the air sac lesions of colisepticemia were scored as follows: 0: no lesions, 1: cloudness of air sacs, 2: air sac membranes are thickened, 3: "meaty" appearance of membranes with large accumulation of cheesy exudates confined to one air sac and 4: lesions with the same score as score 3 but with lesion in two or more air sacs while the pericardial lesions were scored as follows: 0: no lesions, 1: excessive clear or cloudy fluid in the pericardium, 2: extensive fibrination in pericardial cavity. For perihepatic lesions, 0: no visible lesion, 1: definite fibrination on the surface of the liver, 2: extensive fibrination, adhesions, liver swelling and necrosis.

 

To re-isolate the challenge E.coli O111, swabs from the liver, spleen and heart were cultured on MacConkey agar (Oxoid) at 37˚Cfor 24 hours.

 

Antibacterial activity of the tested drugs on E.coli O111:

In vitro antibacterial activity was determined by the agar well-diffusion method (Mukherjee et al., 1995). The E. coli O111 was cultured on Muller Hinton agar for 24h at 37˚C then the bacterial cells were harvested and re-suspended in saline to make a suspension of 105 CFU/ ml and used for assay. The bacterial suspension (105 CFU/ ml) was mixed with Muller Hinton agar medium then the media was transferred to sterile Petri-plates (25ml/plate) and allowed to solidify. About 100µl of serum sample (which collected from chicken after 2h from administration of drugs) was placed in the wells and allowed to diffuse, then the plates were incubated at 37˚C for 24h. The antibacterial activity of the tested drugs was determined by measuring the diameter of the inhibition zones. The assay was performed in triplicate.

 

Immune-responsiveness against E. coli O111:

The antibody titers against E. coli serotype O111 were determined in serum samples collected from each group on 0, 7, 15 and 21 days post infection by using Enzyme linked Immnosorbent Assay (ELISA) according to Briggs and Skeeles (1984).

 

Statistical analysis

ANOVA, student –t test was used for statistical comparison of the body weight, food conversion rate and average daily gain. The lesion scores were analyzed by Mann-Whitney U-test. The ELISA data were analyzed by using the General Linear Models. SPSS for windows was used for statistical analysis.

 

RESULT

 

Efficacy of fosfomycin, thiamphenicol and Nigella sativa oil against E. coli O111 infection:

Clinical signs were absent from control (non infected non medicated) group. The chicken infected with      E. coli O111and not treated were depressed, ruffled feathers, showed signs of anorexia, diarrhea and respiratory signs without mortalities. The chicken infected with E. coli and treated with fosfomycin, thiamphenicol and Nigella sativa oil showed less signs than infected group.

 

The post mortem pathology of the sacrificed chickens revealed that the infected non treated group individuals had severe lesions airsacculitis of, perihepatitis, pericarditis, while the lesions were less severe in chicken of the treated groups. The results of the lesion scores were recorded in table (1), which showed that there was significant decrease (p<0.05) in lesion scores of treated group.


 

 

Table 1: Mean macroscopic lesion scores in sacrificed chicken in infected non- treated and treated groups.

 

Group

Liver

Heart

Air sacs

2nd day of infection

5th day of infection

2nd day of infection

5th day  of infection

2nd day of infection

5th day  of infection

1st group

2nd  group

3rd group

4th  group

5th group

6th  group

7th  group

0.0

2±0.00٭٭٭a

1±0.58

0.67±0.33٭٭a,b

0.33±0.33٭٭a,b

0.67±0.33٭٭a,b

0.67±0.33٭٭a,b

0.0

1±0.0٭٭٭a

0.0٭٭٭b

0.33±0.33٭٭b

0.33±0.33٭٭b

0.0٭٭٭b

0.0٭٭٭b

0.0

1.67±0.33٭٭٭a

0.33±0.33٭٭a,b

0.67±0.33٭٭a,b

0.0٭٭٭b

0.0٭٭٭b

0.33±0.33٭٭a,b

0.0

1±0.0٭٭٭a

0.0٭٭٭b

0.33±0.33٭٭a,b

1±0.0

0.0٭٭٭b

0.0٭٭٭b

0.0

2±0.00٭٭٭a

0.33±0.33٭٭٭b

0.67±0.33٭٭a,b

1±0.58

0.33±0.33٭٭a,b

0.67±0.33٭٭a,b

0.0

1±0.0٭٭٭a

0.0٭٭٭b

0.33±0.33٭٭a,b

0.67±0.33٭٭a,b

0.0٭٭٭b

0.0٭٭٭b

 

1st group was Control group, 2nd group was Infected group, 3rd group was Fosfomycin treated group, 4th  group was thiamphenicol treated group, 5th group was Nigella sativa oil treated group, 6th group was Fosfomycin + Nigella sativa oil treated group and 7th  group was Thiamphenicol + Nigella sativa oil treated group

a Group that significantly different (P < 0.05) from the 1st group

b Group that significantly different (P < 0.05) from the 2nd  group

 

 

The E. coli O111was re-isolated in pure culture from sacrificed chicken of infected non treated group until the 10th day of infection while in the treated groups the re-isolation of the E. coli O111was negative from the 8th day of infection.

 

Performance:

The mean body weight and feed conversion rate at the treatment period were determined in all groups (table, 2). Also the mean body weight and the average daily gain were determined at the end of experiment, and illustrated in (table, 3). The results showed that the groups infected with E. coli O111and treated with fosfomycin, thiamphenicol and/or Nigella sativa oil showed improvement in body weight than infected non treated group, also chickens infected with E. coli O111and non medicated showed a decrease in food consumption and feed conversion ratio (FCR) when compared with control group, while infected chicken medicated with fosfomycin, thiamphenicol and/or Nigella sativa oil showed significant increase in FCR when compared with infected group.

 

The ADG were significantly increased in all infected treated groups, especially groups treated with fosfomycin and thiamphenicol in combination with Nigella sativa oil than infected non treated group.


 

Table 2: The mean body weight (MBW; g/chick) and feed conversion rate (FCR) at the treatment period in all groups.

 

Group

The mean body weight at the treatment period (g/chick)

FCR  %

1st day

2nd  day

3rd day

4th day

5th day

1st group

2nd  group

3rd group

4th  group

5th group

6th  group

7th  group

269.75±13.7

253±4.43

249.0±5.0

248±12.0

255±11.59

260.25±4.6

261.32±6.9

298.75 ± 6.4

280.0±3.26

277±5.97

281±4.43

253.3±6.67

296.82±7.3

287.5±8.81

336±12.35

313±8.88

341.3±11.18

324.91±1.74

308±2.38

358.66±7.42

338.66±18.6

386±6.87

346.66±8.11

379.3±9.68

362.66±12.79

348.66±7.33

406.66±9.61

376±8.33

412±6.11

390.66±8.74

421.33±12.7

396±8.326

393.3±10.41

458.66±14.8

426±12.05

1.976±0.079

2.227±0.0905

1.617±0.076٭٭٭

1.826±0.074٭

1.762±000٭٭

1.666±0.071٭٭٭

1.934±0.22

 

Groups that significantly different from the 2nd group,          ٭p <0.05                  ٭٭ p <0.01             ٭٭٭p <0.001

 

Table 3: The mean body weight and the average daily gain at the start of experiment and at the end of experiment in all groups.

 

Group

MBW(g) at the start of  experiment

(12 day of old)

MBW(g) at the end of experiment

(35 day of old)

ADG

1st group

2nd  group

3rd group

4th  group

5th group

6th  group

7th  group

216.84±7.76

207.5±5.93

206.5±8.9

220.5±5.54

181.66±6.919

196.66±5.72

201.1±6.75

1445±24.4

1417±41.9

1542±31.50

1442±32.9

1580±24.4

1692±38.6

1651±40.6

56.76±0.99

54.65±1.72

59.66±1.33

54.43±1.43

62.61±1.07٭

69.60±1.47٭٭

66.39±0.76٭٭

 

Groups that significantly different from the 2nd group,          ٭p <0.05                 ٭٭ p <0.01                       

 


Antibacterial activity of the tested drugs against E coli O111:

Antibacterial activity of fosfomycin, thiamphenicol and Nigella sativa oil against E coli O111 measured as diameter zone of inhibition (mm) and illustrated in table (4). The result showed that the administration of Nigella sativa oil with fosfomycin or thiamphenicol increase their antimicrobial activity, the serum samples of the group treated with fosfomycin and Nigella sativa oil showed the highest zone of inhibition than other groups.


Table 4: Antibacterial activity of fosfomycin, thiamphenicol and Nigella sativa oil against E. coli O111.

 

Group

Zone of inhibition (mm)

Days of medication

1st day

2nd day

3rd day

4th day

5th day

3rd  group

4th  group

5th group

6th  group

7th  group

10.8±0.116

10.5±0.577

10±0.57

11.83±0.60

11.25±0.5

11±0.001

10.66±0.44

10±0.28

11.5±0.288

11±0.726

10.5±0.166

9.8±0.288

9.5±0.28

11.33±0.166

10.63±0.33

10.8±0.16

10.33±0.166

10±0.288

11.5±0.166

11.00±0.166

11.16±0.33

9.66±0.166

9.83±0.44

11.33±0.33

10.33±0.33

 


Immune-responsiveness against E. coli O111:

The data showed significantly increase in antibody titer (p < 0.05) for E. coli O111 after two weeks of infection in all chicken groups which infected or infected and received antibacterials alone or in combination with Nigella Sativa oil  than those of the control group (Table, 5).

 

The 3rd, 5th group, 6th group and 7th group revealed significant increase (P < 0.05) in antibody titer against E. coli O111 in comparison with infected group after two weeks of infection. The important comparison for antibody titer in groups which received Nigella Sativa oil either with fosfomycin or thiamphenicol showed that the level of antibody production significantly elevated after 15 days and continued after the 21 days of infection.


 

Table 5:Mean log10 antibody titer against E. coli serotype O111 in all groups at 0, 1st, 2nd and 3rd week post infection.

 

Group

Mean log10 antibody titer

 X ± SE

0

1st week

2nd week

3rd week

1st group

2nd  group

3rd group

4th  group

5th group

6th  group

7th  group

3.86 ± 0.042

3.93 ± 0.15

3.91 ± 0.042

3.99 ± 0.030

3.97 ±0.14

3.91 ±0.032

3. 83 ± 0.040

3.87±0.05

4.15±0.049

4.23±0.041a

4.06±0.035

4.05±0.030

4.12±0.018

3.89 ± 0.014

4.05±0.089

4.30±0.072 a

4.48±0.049 ab

4.29±0.064 a

4.45±0.07 ab

4.59±0.056 ab

4.43±0.075 ab

3.99±0.040

4.43±0.090 a

4.51±0.040 ab

4.17±0.045 a

4.39±0.047 a

4.63±0.089 ab

4.31±0.034 ab

 

a Group that significantly different (p < 0.05) from the 1st group

b Group that significantly different (p < 0.05) from the 2nd  group

 

 

 

Figure 1:Mean log10 antibody titer against E.coli serotype O111 in all groups at 0, 1st, 2nd and 3rd week post infection.

 


DISCUSSION

 

A major problem in antimicrobial chemotherapy is the increasing occurrence of resistance to antibiotics, which lead to insufficiency of antimicrobial treatment (Schelz et al., 2006), so combination of different antimicrobials may result in a predictable therapeutic result as to increase the therapeutic efficacy or decrease the toxicity among the administrated drugs (Hurry et al., 1998). Therefore the aim of this work is to compare the efficacy of fosfomycin, thiamphenicol alone or in combination with Nigella Sativa oil against experimental infection of broiler chickens with E. coli O111 and study their effect on immune response.

 

In the present study, the experimental infection of broiler chickens with E. coli O111 cause severe clinical signs (depression, decrease food intake, respiratory sings and diarrhea) with gross lesions (airsacculitis and pericarditis) in non medicated group, this was similar to those reported by (Nakamura et al., 1992; Mogenet et al., 1997). The clinical signs and lesion scores were less in chicken treated with fosfomycin, thiamphenicol alone or in combination with Nigella sativa oil, these results were similar to those reported by (Fernandez et al., 2002) who proved that the treatment with calcium fosfomycin in the drinking water controlled the adverse effects of experimental colibacillosis., also agreed with (Kowalski, 2007) who reported that thiamphenicol has the potential to become available antibiotic in the treatment and control of a wide range of respiratory and alimentary tract infection of bacterial origin in live stock of mammals, poultry and fish, and (Erener et al., 2010) who reported that Nigella sativa seed was effective against total coliform count in the intestine of broilers.

 

The mean body weight, Feed conversion rate (FCR) and Average daily gain were significantly improved in chicken treated with fosfomycin, thiamphenicol and Nigella sativa oil when compared with infected non treated group, the best significant performance parameters were demonstrated in groups treated with fosfomicin and thiamphenicol in combination of  Nigella sativa oil  rather than groups treated with each compound separately, our result was similar to findings reported in chicken treated with fosfomycin (Fernandez et al., 1998, 2002), also (Halle et al., 1999; Erener et al., 2010; Shewita and Taha, 2011) showed that dietary black cumin (Nigella sativa) and its oil extract improved feed intake, body weight and FCR in the broilers even at low dose.

 

Treatment of E. coli O111 infected chickens by fosfomycin, thiamphenicol alone or in combination with Nigella sativa oil reduce E.coli reisolation rate from liver, heart and air sac when compared with those data recorded in infected non treated chickens. These findings were supported by previous report (Shaheen and El-Far, 2013) who recorded that combination of the therapeutic doses of pefloxacin and florfenicol reduce E.coli reisolation rate from liver and heart. Also agreed with the result obtained by (Fernandez et al., 1998, 2002) who demonstrated that fosfomycin reduced the numbers of birds from which bacteria were reisolated and it was effective for treatment of E.coli infection in chickens.

 

The result of antibacterial activity of fosfomycin, thiamphenicol and Nigella sativa oil against E coli O111 which measured as diameter of zone of inhibition (mm) showed that the administration of Nigella sativa oil with fosfomycin or thiamphenicol increase their antimicrobial activity. Our result agreed with that obtained by (Hanafy and Hatem, 1991) who recorded that the extract of Nigella sativa showed antibacterial synergism with streptomycin and gentamycin and showed additive antibacterial action with some antibiotics such as spectinomycin, erythromycin, tobramycin and chloramphenicol.

 

The effect of Nigella Sativa on the immune- response has been investigated by several researches. Many studies have reported that the oil of N.Sativa and its component produce an increase in the T- helper cells and enhance natural killer cell activity, also they had a stimulatory effect on macrophages (El- Kadi and Kandil, 1986 and Haq et al., 1995). The ability of the most abundant component of Nigella Sativa oil; Thymoquinone (TQ) to modulate cytokines and enhance the immune system has been implicated as the main reason for its protective effect against schistosoma egg infection in the liver (Mahmoud      et al., 2002). Dorucu et al. (2009) proved that serum proteins and total immunoglobulin levels were significantly increased in rainbow trout fish.

 

In this study, the specific antibody titers against the   E. coli O111 detected by ELISA in serum were significantly increased after two weeks of infection in 5th, 6th and 7th groups which received the Nigella Sativa oil in comparison to other groups. These results agreed with those of Durrani et al., 2007; Al-Beitawi et al., 2009; Shewita and Taha (2011) and Al-Mufarrej, (2013) who reported significant improvement in antibody titer. Using Nigella Sativa as feed supplementation enhanced antibody production in laying hens (Yalçin et al., 2012). Moreover, using Nigella Sativa oil significantly enhanced the immune system through increased lymphocyte production, and inhibited development of advanced dysplastic changes after topical application of DMBA (7,12- Dimethylbenz(a) anthracene) in hamsters to induce immune-suppression (Al-Jawfi    et al., 2008). The results of this study disagreed with the finding of (Jang, 2011) who recorded no significant effects on immunity parameters except in lymphocyte ratio. In conclusion, the use of Nigella Sativa oil has beneficial effects on the performance, feed intake, body weight and immunological response in the broilers. Future researches should focus on the mechanisms by which the Nigella Sativa oil exerts their effects.

 

ACKNOWLEDGEMENT

 

The authors gratefully acknowledge the help and cooperation of Dr. Selim Selim Salama Senior Researcher, Central Laboratory for Evaluation of Veterinary Biologics, Abbasia, Cairo and Dr. Hosni Awaad El-Banna professor of pharmacology, Faculty of Veterinary Medicine, Cairo University for their help and cooperation in this study.

 

REFERENCES

 

AL-Beitawi, N.A.; El-Ghousein, S.S. and Nofal, A.H. (2009): Replacing bacitracin methylene disalicylate by crushed Nigella sativa seeds in broiler rations and its effects on growth, blood constituents and immunity. Livest. Sci., 125, pp. 304–307.

AL-Jawfi, K.A.M.; Hassan, M.M.A. and El-Gohary, A.M. (2008): Effect of Nigella sativa oil on the Hamster lymphocytes secondary to DMBA-induced carcinogenesis. Suez Canal Univ. Med. J., 11 (1): pp. 75–80.

Al-Mufarrej, S.I. (2013): Immune-responsiveness and performance of broiler chickens fed black cumin (Nigella Sativa L.) powder. J. Saudi Soci. Agricult. Sci., 13 (1): 75–80.

Aramayona, J.; Bregante, M.; Solans, C.; Rueda, S.; Fraile, L.J. and Garcia, M.A. (1997): Pharmacokinetics of Fosfomycine in chickens after a single intravenous dose and tissue levels following chronic oral administration. Vet. Res., 28, 581-588.

Barnes, H.J.; Vaillancourt, J.P. and Gross, W.B. (2003): Diseases of poultry. Iowa State Univ. Press, Ames, IA. p. 631-652.

Barnes, J.; Nolan, L.K. and Vaillancourt, J.P. (2008): Colibacillosis. In: Diseases of poultry, 12th ed. Blackwell publishing, Ames, IA. pp. 691-732.

Briggs, D.J. and Skeeles J.K. (1984): An enzyme linked immunosorbent assay for detecting antibodies to Pasturella multocida in chickens. Avian Dis. 28 (1): 208 -215.

Cannon, M.; Horfard, S. and Davies, J. (1990): A comparative study on the inhibitory actions of Chloramphenicol, Thiamphenicol and some fluorinated analogs.  J. Antimicrob. Chemoth. 26, 307-317.

Charleston, B.; Gate, J.J.; Aitken, I.A.; Stephan, B. and Froyman, R. (1998): Comparison of the efficacies of three fluoroquinolone antimicrobial agents, given as continuous or pulsed-water medication, against Escherichia coli infection in chickens. Antimicrob. Agents Chemother.; 42(1): 83-7.

Dàmaso, L.D. (1990): Fosfomicina en Antibacterianos, (Marketing pharm, S. A., Madrid), 435-452

Dho-Moulin, M. and Fairbrother, J.M. (1999):  Avian pathogenic Escherichia coli (APEC). Vet. Res., 30, 299-316.

Dorucu, M.; Ozesen Colak, S.; Ispir, U.; Altinterim, B. and Celayir, Y. (2009): The effect of black cumin seeds, Nigella sativa, on the immune response of rainbow trout, Oncorhynchus mykiss. Mediterr. Aquacult. J., 2 (1), pp.     27–33.

Durrani, F.R.; Chand, N.; Zaka, K.; Sultan, A.; Khattak, F.M. and Durrani, Z. (2007): Effect of different levels of feed added black seed (Nigella sativa L) on the performance of broiler chicks. Pakistan J. Biol. Sci., 10, pp. 4164–4167.

Erener, G.; Altop, N.; Ocak, H.; Aksoy, S. and Ozturk, E. (2010): Influence of black cumin seed (Nigella sativa L) and seed extract on broilers performance and total coliform bacteria count. Asian J. Anim. Vet. Adv., 5, pp. 128–135.

El-Kadi, A. and Kandil, O. (1986): Effect of Nigella sativa (the black seed) on immunity, Proceeding of the 4th International Conference on Islamic Medicine, Kuwait. Bull Islamic Med., 4: 344–348.

Fernàndez, A.; Lara, C.; Puyuelo, R.; Gomez J.; Ramos J.J.; Loste, A.; Marca, M.C. and Verde M.T. (1998): Efficacy of phosphomycin in the control of Escherichia coli infection of broiler chickens. Res. Vet. Sci.; 65(3): 201-204.

Fernàndez, A.; Lara, C.; Loste, A. and Marca, M.C. (2002): Efficacy of calcium fosfomycin for the treatment of experimental infection of broiler chickens with Escherichia coli O78:K80. Vet. Res. Commun., 26, 427-436.

Geornaras, I.; Hastings, J.W. and Von Holy, A. (2001): Genotypic analysis E.coli strains from poultry carcasses and their susceptibilities to antimicrobial agents. Appl. Environ. Microbial. 67: 1940-1944.

Giorgi, M.; Romani, M.; Bagliacca, M. and Mengozzi, G. (2000): Determination of thiamphenicol residues in albumin and yolk of hen eggs. J. Vet. Pharmacol. Therap. 23,     397-399.

Grif, K.; Dierich, M.; Pfaller, K.; Miglioli, P. and Allerberger, F. (2001): In vitro activity of fosfomycin in combinations with varies antistaphylococcal substances. J. Antimicrob. Chemoth., 48, 209-217.

Gutierrez, L.; Ocampo, L.; Rosario, C. and Sumano, H. (2010): Pharmacokinetics of disodium fosfomycin in broilers and dose strategies to comply with its pharmacodynamics versus Escherichia coli. Poult Sci., 89(10):           2106-2115.

Hala G. Muhtasib; Nahed El. Najjar and Regine S. Stock (2006): The medicinal potential of black seed (Nigella sativa). Advances in phytomedicine, 2, 133-153.

Halle, I.; Thomann, R.; Flachowsky, G.; Schubert, R.; Flachowsky, G.; Bitsch, R. and Jahreis, G. (1999): Effect of ethereal (essential) oil and oil seed on the growth of broilers. Vitamin and Zusatzstoffe in der Ernaehrung, Von Mensch undTier: 7, symposium Jena, Thuringen, Germany.

Hanafy, M.S. and Hatem M.E. (1991): Studies on the antimicrobial activity of Nigella sativa seed (black cumin). J Ethnopharmacol., 34:        278-280.

Haq, A.; Abdullatif, M.; Lobo, P.I.; Khabar, K.S.; Sheth, K.V. and Al-Sedairy, S.T. (1995): Nigella sativa: effect on human lymphocytes and polymorphonuclear leukocyte phagocytic activity. Immunopharmacol., 30(2): 147-55.

Hurry, W.; Lampiris, M.D. and Aniel, S.M. (1998): Clinical use of antimicrobial agents in, Basic and clinical pharmacol. 7th edn., Katzung, B.G.(ed) Stanford, Appleton and lange, New York, 812-826.

Hodžic, A.; Hrković, P.A.; Gagić, A.; Hamamdžić, M.; Kavazović, A.; Pašić Juhas, E.; Kustura, A. and Goletic, T. (2012): Dietary Black cumin (Nigella sativa) seed oil affects serum lipids in chicken broilers. Veterinaria, 61(1-2), 23-33.

Jang, J.P. (2011): The evaluation of different levels of Nigella Sativa seed on performance, and blood parameters of broilers. Ann. Biol. Res., 2 (5): pp. 567–572.

Kowalski, P. (2007): Capillary electrophoretic determination of thiamphenicol in turkeys' serum and its pharmacokinetic application. J. pharmaceut. Biomed. Analy. 43, 222-227.

Mahmoud, M.R.; El-Abhar, H.S. and Saleh, S. (2002): The effect of Nigella sativa oil against the liver damage induced by Schistosoma mansoni infection in mice. J. Ethnopharmacol., 79(1): 1-11.

Mogenet, L.; Bezille, P.; Guyonett, J. and Karembe, H. (1997): Comparison de la fluméquine (Flumisol) à l'amoxicilline (Vetrimoxin poudre orale) dans deux modes d'administration par voie orale, en traitement de la colibacillose du poulet: approche pharmacodynamique et Clinique. Revue Médecine Vétérinaire, 148, 793-804.

Mukherjee, P.K.; Balasubramanian, R.; Saha, K.; Saha, B.P. and Pal, M. (1995): Antibacterial efficiency of Nelumbo nucifera (Nymphaeaceae) rhizomes extract; Indian Drugs, 32, 274-276.

Nakamura, K.; Cook, J.K.A.; Frazier, J.A. and Narita, M. (1992): Escherichia coli multiplication and lesion in the respiratory tract of chickens inoculated with infectious bronchitis virus and/or E.coli .Avian Dis., 36, 881-890.

Nasir, Z. and Grashorn, M.A. (2006): Use of Black cumin (Nigella sativa linn.) as alternative to antibiotics in poultry diets. 9 Tagung. Schweine und Geflugelernahrung, Martin Luther Universitat Halle Wittenberg Halle, Germany, 28-30 November, 210-213.

Nofal, M.E.; Abo-Etta, E.M. and Salem, A.A. (2006): Some productive and physiological responses to dietary Nigella Sativa seeds supplementation of Mamourah laying hens. Egypt poult. Sci., 26: 455-476.

Prescott, J.F. (2000): Peptide antibiotics: polymixins, glycopeptides, streptogramins and bacitracin.in antimicrobial therapy in Veterinary Medicine, 3rd edn. Eds Prescott, J., Baggot, D. and Walter, R., pp.190. Iowa State University Press, Ames, IA.

Rawiwet, V.; Chansiripornchai, P. and Chansiripornchai, N. (2010): Comparison of the Efficacy of Enrofloxacin against Escherichia coli or Pasteurella multocida Infection in Chickens. Thai J. Vet. Med. 40(3): 297-301.

Schelz, Z.; Moniar, J. and Hohmann, J. (2006): Antimicrobial and antiplasmid activities of essential oils. Fitoterapia 77; 279-285.

Shaheen, H.M. and El-Far, A.H. (2013): Evaluation of the therapeutic efficacy of pefloxacin and florfenicol combination in broilers experimentally challenged by Escherichia coli. Int. J. Pharm. Sci. Rev. Res., 23(2), 396-404.

Shewita, R.S. and Taha, A.E. (2011): Effect of dietary supplementation of different levels of black seed (Nigella Sativa L.) on growth, performance, immunological, hematological and carcass parameters of broiler chicks.  World Acad. Sci. Eng. Technol., 77, pp.     788–794.

Switala, M.; Hrynyk, R.; Smutkiewicz. A.; Jaworski, K.; Pawlowski, P.; Okoniewski, P.; Grabowski, T. and Debowy, J. (2007): pharmacokinetics of florfenicol, thiamphenicol, and chloramphenicol in turkeys. J. Vet. Pharmacol. Therap. 30,      145-150.

Tessier, F. and Quentin, C. (1997): In vitro activity of fosfomycin combined with ceftazidine, imipem, amikacin and ciprofloxacin against pseudomonas aerugenosa. Clin. Microbiol.  Infec. 16, 159-162.

Tolba, A.A.H. and Hassan, M.S.H. (2003): Using some natural additives to improve physiological and productive performance of broiler chicks under high temperature conditions. 2-Black cumin (Nigella Sativa) or garlic (Allium sativum). Egypt poult. Sci., 23: 327-340.

Tolba, A.A.H.; Abd El-Galyl, M.A. and Abd El-Samad, M.H. (2005): The effect of using some herbal additives on physiological and productive performance of two Egyptian chicken strains winter and summer seasons. Egypt poult. Sci., 25: 107-123.

Yalçin, S.; Yalçin, S.; Uzunoğlu, K.; Duyum, H.M. and Eltan, Ö. (2012): Effects of dietary yeast autolysate (Saccharomyces cerevisiae) and black cumin seed (Nigella sativa L.) on performance, egg traits, some blood characteristics and antibody production of laying hens. Livest. Sci., 145, (1-3): 13–20.

 

 

مقارنة کفاءة الفوسفومايسن، الثيامفينيکول وزيت حبة البرکة وخليط مع کلاهما

فى علاج الدجاج المصاب بميکروب القولون الإشريکى

 

عبير محمد راضى ، نسرين عبدالرحمن إبراهيم

Email:rouqaa2007@yahoo.com

 

تهدف هذة الدراسة الى مقارنة کفاءة کلا من الفوسفومايسن، الثيامفينيکول وزيت حبة البرکة فى علاج الدجاج المصاب بميکروب القولون الإشريکى (O111). تمت الدراسة على 126 دجاجة عمر 12 يوم حيث تم تقسيمهم الى سبع مجموعات: المجموعة الاولى هى الضابطة والمجموعة الثانية تم اصابتها بميکروب القولون الإشريکى (O111) ولم يتم علاجها أما المجموعة الثالثة تمت اصابتها بالميکروب وعولجت بالفوسفومايسن بجرعة 40 مجم/کجم من وزن الجسم فى مياة الشرب والمجموعة الرابعة تمت اصابتها بالميکروب وعولجت بالثيامفينيکول بجرعة 30 مجم/کجم من وزن الجسم فى مياة الشرب والمجموعة الخامسة تم اصابتها بالميکروب وتم تجريعها زيت حبة البرکة بجرعة 0.025 ملى / کجم من وزن الجسم عن طريق الفم اما المجموعة السادسة تم اصابتها بالميکروب وعولجت بالفوسفومايسن بالاضافة الى زيت حبة البرکة اما المجموعة السابعة تمت اصابتها بالميکروب وعولجت بالثيامفينيکول بالاضافة الى زيت حبة البرکة بنفس الجرعات السابقة. ثم تم دراسة تاثير هذة الادوية على معدل التحويل الغذائى وملاحظة الاعراض المرضية التى تظهر على الدجاج وتم عزل الميکروب من الانسجة الداخلية ودراسة نشاطهما المضاد لهذا الميکروب وتاثيرهما على الجهاز المناعى. ومن هذة الدراسة تبين ان الاعراض المرضية والتشريحية ظهرت بصورة اقل فى الدجاج المعالج بهذة الادوية وکان هناک زيادة فى وزن الجسم والنشاط المضاد البکتيرى وأيضا زيادة فى الأجسام المناعية المتخصصة لميکروب القولون الإشريکى (O111) خاصة فى المجموعات التى عولجت بالفوسفومايسن والثايمفينيکول بالاضافة الى زيت حبة البرکة. ومن هذة الدراسة نستنتج ان اضافة زيت حبة البرکة مع کلا من الفوسفومايسن والثيامفينيکول زاد من کفائتهما العلاجية.

 

 

REFERENCES
 
AL-Beitawi, N.A.; El-Ghousein, S.S. and Nofal, A.H. (2009): Replacing bacitracin methylene disalicylate by crushed Nigella sativa seeds in broiler rations and its effects on growth, blood constituents and immunity. Livest. Sci., 125, pp. 304–307.
AL-Jawfi, K.A.M.; Hassan, M.M.A. and El-Gohary, A.M. (2008): Effect of Nigella sativa oil on the Hamster lymphocytes secondary to DMBA-induced carcinogenesis. Suez Canal Univ. Med. J., 11 (1): pp. 75–80.
Al-Mufarrej, S.I. (2013): Immune-responsiveness and performance of broiler chickens fed black cumin (Nigella Sativa L.) powder. J. Saudi Soci. Agricult. Sci., 13 (1): 75–80.
Aramayona, J.; Bregante, M.; Solans, C.; Rueda, S.; Fraile, L.J. and Garcia, M.A. (1997): Pharmacokinetics of Fosfomycine in chickens after a single intravenous dose and tissue levels following chronic oral administration. Vet. Res., 28, 581-588.
Barnes, H.J.; Vaillancourt, J.P. and Gross, W.B. (2003): Diseases of poultry. Iowa State Univ. Press, Ames, IA. p. 631-652.
Barnes, J.; Nolan, L.K. and Vaillancourt, J.P. (2008): Colibacillosis. In: Diseases of poultry, 12th ed. Blackwell publishing, Ames, IA. pp. 691-732.
Briggs, D.J. and Skeeles J.K. (1984): An enzyme linked immunosorbent assay for detecting antibodies to Pasturella multocida in chickens. Avian Dis. 28 (1): 208 -215.
Cannon, M.; Horfard, S. and Davies, J. (1990): A comparative study on the inhibitory actions of Chloramphenicol, Thiamphenicol and some fluorinated analogs.  J. Antimicrob. Chemoth. 26, 307-317.
Charleston, B.; Gate, J.J.; Aitken, I.A.; Stephan, B. and Froyman, R. (1998): Comparison of the efficacies of three fluoroquinolone antimicrobial agents, given as continuous or pulsed-water medication, against Escherichia coli infection in chickens. Antimicrob. Agents Chemother.; 42(1): 83-7.
Dàmaso, L.D. (1990): Fosfomicina en Antibacterianos, (Marketing pharm, S. A., Madrid), 435-452
Dho-Moulin, M. and Fairbrother, J.M. (1999):  Avian pathogenic Escherichia coli (APEC). Vet. Res., 30, 299-316.
Dorucu, M.; Ozesen Colak, S.; Ispir, U.; Altinterim, B. and Celayir, Y. (2009): The effect of black cumin seeds, Nigella sativa, on the immune response of rainbow trout, Oncorhynchus mykiss. Mediterr. Aquacult. J., 2 (1), pp.     27–33.
Durrani, F.R.; Chand, N.; Zaka, K.; Sultan, A.; Khattak, F.M. and Durrani, Z. (2007): Effect of different levels of feed added black seed (Nigella sativa L) on the performance of broiler chicks. Pakistan J. Biol. Sci., 10, pp. 4164–4167.
Erener, G.; Altop, N.; Ocak, H.; Aksoy, S. and Ozturk, E. (2010): Influence of black cumin seed (Nigella sativa L) and seed extract on broilers performance and total coliform bacteria count. Asian J. Anim. Vet. Adv., 5, pp. 128–135.
El-Kadi, A. and Kandil, O. (1986): Effect of Nigella sativa (the black seed) on immunity, Proceeding of the 4th International Conference on Islamic Medicine, Kuwait. Bull Islamic Med., 4: 344–348.
Fernàndez, A.; Lara, C.; Puyuelo, R.; Gomez J.; Ramos J.J.; Loste, A.; Marca, M.C. and Verde M.T. (1998): Efficacy of phosphomycin in the control of Escherichia coli infection of broiler chickens. Res. Vet. Sci.; 65(3): 201-204.
Fernàndez, A.; Lara, C.; Loste, A. and Marca, M.C. (2002): Efficacy of calcium fosfomycin for the treatment of experimental infection of broiler chickens with Escherichia coli O78:K80. Vet. Res. Commun., 26, 427-436.
Geornaras, I.; Hastings, J.W. and Von Holy, A. (2001): Genotypic analysis E.coli strains from poultry carcasses and their susceptibilities to antimicrobial agents. Appl. Environ. Microbial. 67: 1940-1944.
Giorgi, M.; Romani, M.; Bagliacca, M. and Mengozzi, G. (2000): Determination of thiamphenicol residues in albumin and yolk of hen eggs. J. Vet. Pharmacol. Therap. 23,     397-399.
Grif, K.; Dierich, M.; Pfaller, K.; Miglioli, P. and Allerberger, F. (2001): In vitro activity of fosfomycin in combinations with varies antistaphylococcal substances. J. Antimicrob. Chemoth., 48, 209-217.
Gutierrez, L.; Ocampo, L.; Rosario, C. and Sumano, H. (2010): Pharmacokinetics of disodium fosfomycin in broilers and dose strategies to comply with its pharmacodynamics versus Escherichia coli. Poult Sci., 89(10):           2106-2115.
Hala G. Muhtasib; Nahed El. Najjar and Regine S. Stock (2006): The medicinal potential of black seed (Nigella sativa). Advances in phytomedicine, 2, 133-153.
Halle, I.; Thomann, R.; Flachowsky, G.; Schubert, R.; Flachowsky, G.; Bitsch, R. and Jahreis, G. (1999): Effect of ethereal (essential) oil and oil seed on the growth of broilers. Vitamin and Zusatzstoffe in der Ernaehrung, Von Mensch undTier: 7, symposium Jena, Thuringen, Germany.
Hanafy, M.S. and Hatem M.E. (1991): Studies on the antimicrobial activity of Nigella sativa seed (black cumin). J Ethnopharmacol., 34:        278-280.

Haq, A.; Abdullatif, M.; Lobo, P.I.; Khabar, K.S.; Sheth, K.V. and Al-Sedairy, S.T. (1995): Nigella sativa: effect on human lymphocytes and polymorphonuclear leukocyte phagocytic activity. Immunopharmacol., 30(2): 147-55.

Hurry, W.; Lampiris, M.D. and Aniel, S.M. (1998): Clinical use of antimicrobial agents in, Basic and clinical pharmacol. 7th edn., Katzung, B.G.(ed) Stanford, Appleton and lange, New York, 812-826.
Hodžic, A.; Hrković, P.A.; Gagić, A.; Hamamdžić, M.; Kavazović, A.; Pašić Juhas, E.; Kustura, A. and Goletic, T. (2012): Dietary Black cumin (Nigella sativa) seed oil affects serum lipids in chicken broilers. Veterinaria, 61(1-2), 23-33.
Jang, J.P. (2011): The evaluation of different levels of Nigella Sativa seed on performance, and blood parameters of broilers. Ann. Biol. Res., 2 (5): pp. 567–572.
Kowalski, P. (2007): Capillary electrophoretic determination of thiamphenicol in turkeys' serum and its pharmacokinetic application. J. pharmaceut. Biomed. Analy. 43, 222-227.
Mahmoud, M.R.; El-Abhar, H.S. and Saleh, S. (2002): The effect of Nigella sativa oil against the liver damage induced by Schistosoma mansoni infection in mice. J. Ethnopharmacol., 79(1): 1-11.
Mogenet, L.; Bezille, P.; Guyonett, J. and Karembe, H. (1997): Comparison de la fluméquine (Flumisol) à l'amoxicilline (Vetrimoxin poudre orale) dans deux modes d'administration par voie orale, en traitement de la colibacillose du poulet: approche pharmacodynamique et Clinique. Revue Médecine Vétérinaire, 148, 793-804.
Mukherjee, P.K.; Balasubramanian, R.; Saha, K.; Saha, B.P. and Pal, M. (1995): Antibacterial efficiency of Nelumbo nucifera (Nymphaeaceae) rhizomes extract; Indian Drugs, 32, 274-276.
Nakamura, K.; Cook, J.K.A.; Frazier, J.A. and Narita, M. (1992): Escherichia coli multiplication and lesion in the respiratory tract of chickens inoculated with infectious bronchitis virus and/or E.coli .Avian Dis., 36, 881-890.
Nasir, Z. and Grashorn, M.A. (2006): Use of Black cumin (Nigella sativa linn.) as alternative to antibiotics in poultry diets. 9 Tagung. Schweine und Geflugelernahrung, Martin Luther Universitat Halle Wittenberg Halle, Germany, 28-30 November, 210-213.
Nofal, M.E.; Abo-Etta, E.M. and Salem, A.A. (2006): Some productive and physiological responses to dietary Nigella Sativa seeds supplementation of Mamourah laying hens. Egypt poult. Sci., 26: 455-476.
Prescott, J.F. (2000): Peptide antibiotics: polymixins, glycopeptides, streptogramins and bacitracin.in antimicrobial therapy in Veterinary Medicine, 3rd edn. Eds Prescott, J., Baggot, D. and Walter, R., pp.190. Iowa State University Press, Ames, IA.
Rawiwet, V.; Chansiripornchai, P. and Chansiripornchai, N. (2010): Comparison of the Efficacy of Enrofloxacin against Escherichia coli or Pasteurella multocida Infection in Chickens. Thai J. Vet. Med. 40(3): 297-301.
Schelz, Z.; Moniar, J. and Hohmann, J. (2006): Antimicrobial and antiplasmid activities of essential oils. Fitoterapia 77; 279-285.
Shaheen, H.M. and El-Far, A.H. (2013): Evaluation of the therapeutic efficacy of pefloxacin and florfenicol combination in broilers experimentally challenged by Escherichia coli. Int. J. Pharm. Sci. Rev. Res., 23(2), 396-404.
Shewita, R.S. and Taha, A.E. (2011): Effect of dietary supplementation of different levels of black seed (Nigella Sativa L.) on growth, performance, immunological, hematological and carcass parameters of broiler chicks.  World Acad. Sci. Eng. Technol., 77, pp.     788–794.
Switala, M.; Hrynyk, R.; Smutkiewicz. A.; Jaworski, K.; Pawlowski, P.; Okoniewski, P.; Grabowski, T. and Debowy, J. (2007): pharmacokinetics of florfenicol, thiamphenicol, and chloramphenicol in turkeys. J. Vet. Pharmacol. Therap. 30,      145-150.
Tessier, F. and Quentin, C. (1997): In vitro activity of fosfomycin combined with ceftazidine, imipem, amikacin and ciprofloxacin against pseudomonas aerugenosa. Clin. Microbiol.  Infec. 16, 159-162.
Tolba, A.A.H. and Hassan, M.S.H. (2003): Using some natural additives to improve physiological and productive performance of broiler chicks under high temperature conditions. 2-Black cumin (Nigella Sativa) or garlic (Allium sativum). Egypt poult. Sci., 23: 327-340.
Tolba, A.A.H.; Abd El-Galyl, M.A. and Abd El-Samad, M.H. (2005): The effect of using some herbal additives on physiological and productive performance of two Egyptian chicken strains winter and summer seasons. Egypt poult. Sci., 25: 107-123.

Yalçin, S.; Yalçin, S.; Uzunoğlu, K.; Duyum, H.M. and Eltan, Ö. (2012): Effects of dietary yeast autolysate (Saccharomyces cerevisiae) and black cumin seed (Nigella sativa L.) on performance, egg traits, some blood characteristics and antibody production of laying hens. Livest. Sci., 145, (1-3): 13–20.