IN VITRO EFFICACY OF AQUEOUS NEEM EXTRACT AND DELTAMETHRIN AGAINST SARCOPTES SCABIEI VAR. CUNICULI AND IN VIVO USING EXPERIMENTALLY INFESTED RABBITS

Document Type : Research article

Authors

1 Biochemistry, Toxicology and Nutritional Deficiency Diseases Department. Animal Health Research Institute, Benha-Branch. Agriculture Research Center (ARC)

2 Avian Diseases Department

3 Biochemistry, Toxicology and Nutritional Deficiency Diseases Department

4 Parasitology Department Animal Health Research Institute, Benha-Branch. Agriculture Research Center (ARC).

Abstract

Sarcoptes scabiei var. cuniculi is an important ectoparasites in rabbits. The acaricidal activity of aqueous extract of neem (AEN) and deltamethrin (DMT) were evaluated. Rabbits were classified into four equal groups. The first group represented the negative control group. Each rabbit of the other groups was experimentally infested with 50 mites. One month post-infestation, the second group considered as the positive control group. The third group was treated topically with DMT 0.005 % solution. Finally, the fourth group was treated topically with 25 % AEN. In vitro, AEN (40 %) was highly efficacious against larvae of S. scabiei var. cuniculi as 100 % mortality was reached 24 h post-treatment (PT). In vivo, Twenty-eight days PT, the reduction percentages of mites infesting rabbits were 93.07 and 92.81 % for DMT and AEN, respectively, while complete mite reduction was reached 42 days PT with AEN. All biochemical analyses & growth performance parameters returned to normal levels in AEN & DMT treated rabbits at 28 & 42 days PT. Our study indicated that AEN had in vitro and in rabbits acaricidal efficiency similar to that of DMT and improved the performance of rabbits without inducing adverse effects on treated rabbits.

Keywords


IN VITRO EFFICACY OF AQUEOUS NEEM EXTRACT AND DELTAMETHRIN AGAINST SARCOPTES SCABIEI VAR. CUNICULI AND IN VIVO USING EXPERIMENTALLY INFESTED RABBITS

 

ALI M. ALI*; SHAKER A. SEDDIEK**; MAI O. NADA* and SAMEH A. EL-ALFY***

 

*Biochemistry, Toxicology and Nutritional Deficiency Diseases Department

**Avian Diseases Department

***Parasitology Department

 Animal Health Research Institute, Benha-Branch. AgricultureResearchCenter (ARC).

 

Email: alimohamed312@yahoo.com                                                      AssiutUniversity web-site: www.aun.edu.eg

 

 

 

ABSTRACT

 

 

Received at: 11/3/2015

 

Accepted: 15/4/2015

 

Sarcoptes scabiei var. cuniculi is an important ectoparasites in rabbits. The acaricidal activity of aqueous extract of neem (AEN) and deltamethrin (DMT) were evaluated. Rabbits were classified into four equal groups. The first group represented the negative control group. Each rabbit of the other groups was experimentally infested with 50 mites. One month post-infestation, the second group considered as the positive control group. The third group was treated topically with DMT 0.005 % solution. Finally, the fourth group was treated topically with 25 % AEN. In vitro, AEN (40 %) was highly efficacious against larvae of S. scabiei var. cuniculi as 100 % mortality was reached 24 h post-treatment (PT). In vivo, Twenty-eight days PT, the reduction percentages of mites infesting rabbits were 93.07 and 92.81 % for DMT and AEN, respectively, while complete mite reduction was reached 42 days PT with AEN. All biochemical analyses & growth performance parameters returned to normal levels in AEN & DMT treated rabbits at 28 & 42 days PT. Our study indicated that AEN had in vitro and in rabbits acaricidal efficiency similar to that of DMT and improved the performance of rabbits without inducing adverse effects on treated rabbits.

 

 

Key words: In vitro, Aoueous neem extract, Deltamethrin against, Sarcoptes scabiei var. cuniculi.

 

 


INTRODUCTION

 

Sarcoptic mange belongs to the family sarcoptidae and it’s a highly contagious and burrowing parasite (Walton and Currie, 2007). Sarcoptes scabiei is an important rabbit ectoparasite because of the possibility of zoonotic infection (Harrenstien et al., 1995) and considerable losses in weight, productivity, wool, and fiber quality.

 

In Egypt, mange (Sarcoptes and Psorptic) in rabbits is considered to be second to coccidiosis importance, with high losses. Sarcoptes scabiei var. cuniculi causes mange infestation in rabbits, affecting their nose, feet, and areas around the genitalia, resulting in hypertensive reaction, body weight loss, and death (Saha and Mukherjee 1998). S. scabiei can be difficult to eliminate in rabbits compared to other domestic animals (Aiello et al., 1998).

 

There is extensive evidence of the activity of the pyrethroids, such as deltamethrin, pyrethin, cypermethrin and tetramethrin, when they are used as topical pesticides. Deltamethrin is a pyrethroid with strong insecticidal activity and photo-stability and low mammalian toxicity and acts on the insect’s central nervous system to give a rapid knockdown. It brings acaricidal and repellent effects against ticks, mites and biting insects, thus providing protection from the transmission of diseases (Mehlhorn et al., 2011).

 

In general, many of the chemical acaracides have limitations such as resistance (Currie et al., 2004) and toxicity (O’Brien 1999), environmental contamination, and persistence (Halley et al., 1993; O’Brien 1999). Such side effects of chemical acaricides have prompted a search for new alternatives (Khater et al., 2013a, b).

 

Medicinal plants have been used as a source of remedies since ancient times. The ancient Egyptians were familiar with many medicinal herbs and were aware of their usefulness in the treatment of various diseases. Egypt possesses an enormous diversity of plant resources that is used for herbal remedies for humans and animals (Mohamed et al., 2010; Seddiek et al., 2011; Khater et al., 2013a, b).

 

Botanicals have been in nature for millions of years without any adversative effects on the ecosystem. Botanical extracts kill and repel pests (Khater et al., 2009), affect insect growth and development (Shalaby and Khater 2005; Khater and Shalaby 2008), and have anti-feedant and arrestant effects. As a consequence, botanical acaricides have become research hot spots because of their environmental safety and efficacy (Khater 2011, 2012, 2013).

 

Neem (Azadirachta indica A. Juss) has multipurpose medicinal properties, including antibacterial (El-Mahmood et al., 2010), antifungal, immune-stimulant, antipyretic (Biswas et al., 2002), and acaricidal activities (Mulla and Su 1999). Neem was found to have biocidal activity against nearly 200 medical and veterinary arthropods, without any adverse effects toward most non-target organisms. As an acaricide, neem oil is effective against S. scabiei (Du et al., 2007), ticks (Abdel-Shafy and Zayed 2002), and poultry red mites (Lundh et al., 2005).

 

The aims of this work were to evaluate the acaricidal efficacy (in vitro and in vivo) of the crude aqueous extract of neem (AEN) and deltamethrin (DMN) against S. scabiei var. cuniculi and their effects on some biochemical parameters and growth performance of rabbits experimentally infested with sarcoptic mite.

 

MATERIALS and METHODS

 

Collection of mites

S. scabiei var. cuniculi larvae were collected from naturally infested rabbits in Qalyubia governorate, Egypt. The scabs containing mites were placed in Petri dishes, which were incubated at 35 °C for 30 min. Under a stereomicroscope, the motile larvae were used in the experiments. Larvae have six legs, which makes them easily distinguishable from nymphs and adults, which have eight legs. Mites were identified according to Soulsby (1982).

 

Chemical acaricide

Deltamethrin (Butox® 50 EC) was purchased from the Intervet Company, Cairo, Egypt. Each milliliter of (Butox® 50 EC) contains 50 mg deltamethrin (DMT). We prepared DMT topical solution by adding 1 ml of Butox® 50 EC to 1 liter distilled water (DW) to obtain DMT topical solution with concentration of 0.005% (50 mg DMT/Liter DW), according to the producer.

 

Plant material and extraction

Fresh leaves of Neem, Azadirachta indica A. Juss (A. indica), were collected from Giza, Egypt, in May 2014. The crude aqueous leaf extract of neem (AEN) was prepared according to Haussain (2002), with some modifi­cations. Leaves of A. indica were dried indoors and then ground and weighed (5, 10, 20, 25, 30, and 40 g). Ground leaves were soaked in 100 ml distilled water for 24 hours (h) and then homogenized in an electric blender. The homogenate was altered through a sterilized triple-folded piece of gauze. The filtrates (5, 10, 20, 30, and 40 %) were used for in vitro bioassays while; the filtrate 25% was used for in vivo experiment.

 

Acaricidal activity in vitro

Regarding the concentration response bioassay, studying the acaricidal property was done according to Khater and Ramadan (2007). Five doses of AEN with four replications for each concentration were used in vitro. Twenty larvae per replicate were placed in a clean dry Petri dish with a filter paper, disc of Whatman no. 1 filter paper with surface areas measuring 62.63 cm2, and impregnated uniformly with the used concentration of AEN on the bottom. The bioassay trails were carried out with increasing concentrations of AEN (5, 10, 20, 30, and 40 %) and contact time (24, 48, and 72 h). Two other groups were used: the first one (control) was treated with distilled water and the second group was treated with DMT 0.005%. Bioassays were done at 27±2 °C and 75±5 % relative humidity (RH). Immobility of the larval mites, even when stimulated with a needle, the lack of a response, and persistent immobility were considered indicative of death (Khater and Ramadan 2007; Khater et al., 2013b).

 

Experimental animals

Forty New Zealand male rabbits (mean weight, 757.23 ± 5.46 g) were purchased from the Faculty of Agriculture, Benha University, Egypt. All rabbits were healthy and fed on balanced rations and a clean source of water ad libitum. These rabbits had not been treated with any anti-acariasis drug. The sampling procedures adhered to institutional ethical and animal care guidelines, and all methods were conducted in accordance with the Guide for the Care and Use of Laboratory Animals, according to Nong   et al. (2013).

 

Experimental design and treatment strategy

Forty rabbits were classified into four equal groups (ten rabbits each). The first group was designated as the healthy or negative control group (non-infested and non-treated). Each rabbit in the other groups was experimentally infested with 50 mites (Larvae). The infestation was carried out on the dorsal area (4X2 cm) after scratching the fur. One month post-infestaotion, the second group was not treated and taken into account as the positive control group. The third group was treated topically with deltamethrin (DMT) 0.005 % solution, once every three days for three consecutive weeks. Finally, the fourth group was treated topically with 25 % AEN (the concentration which showed lethal concentration 99 (LC99) value 48 h post-treatment, PT) every 3 days for three consecutive weeks, according to Haussain (2002).

 

Clinical score value descriptions

Index scoring of lesions was described weekly according Jensen et al. (2002) as follows: 0=no lesion; 1=mild lesion-small visible mange body lesion (diameter, 0-4 cm), no bloody skin injuries, good overall body condition, only occasional ebbing; 2=moderate lesion-medium-sized visible mange body lesion (diameter, 4-8 cm), no bloody skin injuries, good overall body condition, more sequent rubbing; 3=severe lesion-severe body mange skin lesion, bloody skin injuries due to rubbing, reduced overall body condition; 4=chronic lesion-thick asbestos-like scab in the body, bloody skin injuries due to rubbing, marked reduced overall body condition. Skin scrapings were taken from the part of the lesions bordering healthy tissue by scraping the infested areas. The number of live mites (larvae, nymphs, and adults) on each rabbit was counted on the 14th, 28th, and 42th day PT.

 

Biochemical analyses

Blood samples were taken from the ear veins of five rabbits per group two times, 28 and 42 days PT, to separate the serum, which was stored at -20 °C until used for estimating the activity of serum alanine aminotransferase (ALT) and aspartate aminotransferase (AST) (Varliy, 1974), cholesterol (Flegg, 1973), creatinine (Henry, 1974), total protein (Domas, 1975), albumin (Dogmas, 1971), and globulin.

 

Rabbit performance

The body weight and cumulative body weight gain of rabbits were recoded 14, 28, and 42 days PT.

 

Statistical analysis

In bioassay tests, probit analysis was done on mortality data (Finney, 1971) using a computer program (Biostat, 2009) to calculate the lethal concentration (LC) and lethal time (LT) values. The biological data were subjected to analysis of variance (ANOVA) with Duncan’s multiple range test (Duncan, 1955) using SPSS, a computer software (SPSS, 2009).

 

RESULTS

 

AEN (40 %) was highly efficacious against S. scabiei var. cuniculi larvae as 100 % mortality was reached 24 h PT. On the other hand, all mites treated with AEN (20 %) and DMT (0.005 %) died 48 h PT (Table 1). The lethal values of AEN (LC50, LC90, LC95, and LC99) were 7.65, 14.97, 18.11, and 25.88 %, respectively, 48 h PT (Table 2). Lesion scoring in DMT (0.005%) and AEN (25%) treated groups were significantly decreased (P < 0.05), reaching 0.21 and 0.41, respectively, when compared with that of positive control group (4.08), 42 days PT (Table 3).

 

Rabbits infested with S. scabiei var. cuniculi adult and not treated (positive control group) showed sarcoptic mange on the nose. The affected regions showed scales, alopecia, and scale formation. Rabbits showed pruritis and were intermittently scratching the area with front paws. Later, hemorrhagic crusts with Assures developed, even becoming eroded in places. Rabbits showed minor signs of recovery. In contrast, rabbits treated with AEN exhibited improvement of clinical signs during the experiment, no inflammation was observed, and showed absence of macroscopic lesions on the nose, and legs after 42 days PT. Similar results had been reported for the DMT-treated group.

 

Twenty-eight days PT, the reduction percentages of mites infesting rabbits were 93.07 % and 92.81 % for DMT and AEN, respectively. However, complete mite reduction was reached at 42 days PT (Table 4). Rabbits treated with AEN did not show signs of restlessness or irritation, respiratory signs, or inflammation on the eye and/or skin at the time of application or afterwards.

 

Regarding biochemical analyses at 42 days PT, the levels of AST and total cholesterol of rabbits infested with S. scabiei var. cuniculi and not treated (positive control group) were significantly increased (P < 0.05) than those of rabbits of the negative control group and those treated with DMT (0.005%) or AEN (25%) (Table 5). On the other hand, the levels of total protein, albumin, and globulin of positive control group were significantly decreased (P < 0.05) when compared with the corresponding values of other groups (Table 6). The body weight and cumulative body weight gain of rabbits treated with AEN were significantly increased (P < 0.05) when compared with such values of positive control group & those treated with DMT (0.005%), on 28 and 42 days PT (Table 7).

 

 


Table 1: In vitro mortality percentage of S. scabiei var. cuniculi larvae after treatment with different concentrations of aqueous extract of neem and the recommended dose of deltamethrin.

 

Concentrations

Time post-treatment (hours)

24

48

72

D

L

M%

D

L

M%

D

L

M%

Control

2

78

2.50

5

75

6.25

8

72

10.00

DMT (0.005%)

74

6

92.50

80

0

100.00

80

0

100.00

AEN (5%)

13

67

16.25

13

67

16.25

25

55

31.25

AEN (10%)

33

47

41.25

33

47

41.25

62

18

77.50

AEN (20%)

55

25

68.75

80

0

100.00

80

0

100.00

AEN (30%)

67

13

83.75

80

0

100.00

80

0

100.00

AEN (40%)

80

0

100.00

80

0

100.00

80

0

100.00

D= Dead larvae. L=Live larvae. M % = Mortality percentage. DMT= Deltamethrin. AEN= Aqueous extract of neem.

 

Table 2: In vitro sensitivity of S. scabiei var. cuniculi larvae to aqueous extract of neem with determination of its effective lethal time against the mites. (Mean ±SEM).

 

 

Time post-treatment (hours)

24

48

72

LC50

11.91 ±0.82

7.65 ±0.24

6.52 ±0.18

LC90

32.80 ±1.04

14.97 ±1.03

12.78 ±1.06

LC95

43.71 ±2.52

18.11 ±1.16

15.47 ±1.14

LC99

74.89 ±2.74

25.88 ±1.22

22.14 ±1.17

Slope1

2.97 ±0.12

4.48 ±0.25

4.47 ±0.02

 

SEM=stander error of mean. LC= lethal concentration. LT= lethal time.

1Slope of the regression lines.

LT50 values for 5% and 10% of aqueous extract of neem were 160.100 ±13.257 and 33.973 ±2.451, respectively.

 

Table 3: Index scoring of S. scabiei var. cuniculi adult infested rabbits after treatment with aqueous extract of neem and deltamethrin. (Mean ±SEM).

 

 

Days post-treatment

7

14

21

28

35

42

-ve control

0.00 ±0.00 b

0.00 ±0.00 c

0.00 ±0.00 c

0.00 ±0.00 c

0.00±0.00 b

0.00 ±0.00 b

+ve control

2.04 ±0.01a

2.65 ±0.12 a

3.47 ±0.21 a

3.67 ±0.24 a

3.88 ±0.24 a

4.08 ±0.24 a

DMT

1.65 ±0.02 a

1.65 ±0.03 b

1.44 ±0.05 b

1.24 ±0.07 b

0.41 ±0.24 b

0.21 ±0.24 b

AEN

1.71 ±0.04 a

1.85 ±0.07 b

1.65 ±0.06 b

1.44 ±0.08 b

0.62 ±0.24 b

0.41 ±0.24 b

 

SEM=stander error of mean. -ve control: negative control (not infested & not treated); +ve control: positive control (Infested & not treated); DMT: infested and treated with deltamethrin locally (0.005%); AEN= infested and treated with aqueous extract of neem locally (25%). a-c Mean values within a column followed by different lowercase letters were significantly different (P ≤ 0.05). Index scores according to Jensen et al. (2002).

 

Table 4: Reduction percentage of live mite on the infested rabbits after treatment with aqueous extract of neem and deltamethrin.

 

 

Days post-treatment

14

28

42

 

M±SEM

R%

M±SEM

R%

M±SEM

R%

-ve control

0.00 ±0.00 c

­­__

0.00 ±0.00 c

__

0.00 ±0.00 b

__

+ve control

98.70 ±1.04a

0.00

137.00 ±1.03 a

0.00

182.11 ±4.36 a

0.00

DMT

35.35 ±2.32b

64.18

9.50 ±1.06 b

93.07

0.00 ±1.03 b

100.00

AEN

39.55 ±2.24b

59.93

9.85 ±1.02 b

92.81

1.56 ±1.07 b

99.14

 

M= mean number of live mites (larvae, nymphs & adults). SEM=stander error of mean. R% = Reduction percentage. -ve control: negative control (not infested & not treated); +ve control: positive control (Infested & not treated); DMT: infested and treated with deltamethrin locally (0.005%); AEN= infested and treated with aqueous extract of neem locally (25%).

a-c Mean values within a column followed by different lowercase letters were significantly different (P ≤ 0.05).

 

Table 5: Some serum biochemical parameters in rabbits treated with crude aqueous extract of neem or deltamethrin. (Mean ± SEM).

 

 

AST (U/L)

ALT (U/L)

Creatinine (mg/dL)

Total cholesterol (mg/dL)

28

42

28

42

28

42

28

42

-ve control

   40.23 ±2.81 b

39.55 ±2.15 b

35.61 ±2.47 a

36.57 ±2.17 a

1.25 ±0.01 a

1.37 ±0.04 a

58.43 ±3.72 b

60.32 ±3.63 b

+ve control

  63.12 ±3.22 a

72.45 ±4.52 a

40.12 ±1.72 a

40.83 ±2.84 a

0.96 ±0.02 a

1.18 ±0.01 a

72.62 ±4.83 a

76.54 ±3.77 a

DMT

   41.28 ±1.72 b

38.73 ±1.88 b

38.48 ±2.64 a

38.96 ±1.46 a

1.15 ±0.01 a

1.31 ±0.06 a

59.46 ±3.44 b

61.45 ±4.14 b

AEN

42.19 ±2.52 b

37.85 ±2.62 b

39.53 ±1.42 a

40.11 ±1.89 a

0.98 ±0.06 a

1.22 ±0.05 a

60.24 ±3.64 b

58.78 ±3.43 b

 

AST: Aspartate aminotransferase; ALT: Alanine transaminase; SEM: stander error of mean; -ve control: negative control (not infested & not treated); +ve control: positive control (Infested & not treated); DMT: infested and treated with deltamethrin locally (0.005%); AEN= infested and treated with aqueous extract of neem locally (25%).

a-b Mean values within a column followed by different lowercase letters were significantly different (P ≤ 0.05).

 

Table 6: Serum total protein, albumin, and globulin in rabbits treated with crude aqueous extract of neem or deltamethrin. (Mean ± SEM).

 

 

Total protein (g/dL)

Albumin (g/dL)

Globulin (g/dL)

28

42

28

42

28

42

-ve control

5.82 ±0.08 a

5.94 ±0.12 a

3.12 ±0.12 a

3.32 ±0.06 a

2.70 ±0.08 a

2.62 ±0.11 a

+ve control

4.46 ±0.14 c

4.16 ±0.25 b

2.31 ±0.07 c

2.12 ±0.03 b

2.15 ±0.17 c

2.04 ±0.08 b

DMT

5.24 ±0.26 b

5.73 ±0.17 a

2.87 ±0.02 b

3.43 ±0.02 a

2.37 ±0.13 b

2.30 ±0.07 a

AEN

5.55 ±0.31 a

5.89 ±0.27 a

2.98 ±0.10 a

3.36 ±0.05 a

2.57 ±0.07 a

2.53 ±0.13 a

 

SEM: stander error of mean; -ve control: negative control (not infested & not treated); +ve control: positive control (Infested & not treated); DMT: infested and treated with deltamethrin locally (0.005%); AEN= infested and treated with aqueous extract of neem locally (25%). a-c Mean values within a column followed by different lowercase letters were significantly different (P ≤ 0.05).

Table 7: Body weight and body weight gain in rabbits treated with aqueous extract of neem or deltamethrin. (Mean ± SEM).

 

 

Initial body weight

 

Days post-treatment

28

42

14

Body weight

cBody gain

Body weight

cBody gain

Body weight

cBody gain

-ve control

761.5 ±25.2 a

1062.6 ±21.7 a

301.1 ±14.2 a

1350.4 ±26.4 a

588.9 ±10.4 a

1660.7 ±32.4 a

899.2 ±13.3 a

+ve control

755.7 ±17.3 a

965.0 ±15.2 b

209.3 ±13.5 b

1160.3 ±23.8 d

404.6 ±8.7 d

1375.4 ±43.3 d

619.7 ±16.4 c

DMT

755.4 ±16.3 a

970.4 ±24.5 b

215.0 ±17.7 b

1255.7 ±43.2 c

500.0 ±11.5 c

1570.3 ±26.5 c

814.9 ±24.7 b

AEN

756.3 ±28.5 a

967.2 ±28.3 b

210.9 ±14.3 b

1262.5 ±31.4 b

506.0 ±13.2 b

1632.2 ±33.7 b

875.9 ±17.9 a

 

SEM: stander error of mean; cBody gain: Cumulative body gain; -ve control: negative control (not infested & not treated); +ve control: positive control (Infested & not treated); DMT: infested and treated with deltamethrin locally (0.005%); AEN= infested and treated with aqueous extract of neem locally (25%). a-d Mean values within a column followed by different lowercase letters were significantly different (P ≤ 0.05).

 


DISCUSSION

 

In vitro, the present study observed that, DMT (0.005 %) caused 92.5 and 100 % mortality 24 and 48 h PT, respectively. DMT completely reduced mite infestation 42 days PT of rabbits with 0.005% solution, topically. In spite of the applied dose for treating rabbits, such efficacy of DMT was in har­mony with the reports of other researches. A similar prolonged acaricidal effect was recorded after using a higher dose of DMT (0.05%) (Ramadan 2009). Dipping of whole chickens in DMT caused prolonged and complete reduction (100 %) in the number of ticks till the end of the third week PT (Ramadan 2009). As sunlight does not break pyrethroids down, they stick to surfaces for weeks, killing any bypassing insect, which explains the prolonged effect of DMT (Dubey et al., 2011). Concerning the side effects of DMT, it induced neurotoxicity in rats (Gilmore         et al., 2006), and the use of DMT has deleterious effects on male (Ben Slima et al.,2012) and female (Lemos et al., 2012) fertility  in rats. In addition, DMT showed malformation, decrease in body weight and incomplete ossification in fetuses of rats (Kandil, 2006). Ecologically, treatment of sarcoptic mange with various acaricides like diazinon, fenvalerate, deltamethrin, and avermectin (Campbell 1989; Merck 2005) has been attempted with different grades of success, insecticides pollute the environment around animals (Gassner et al., 1997) and their side effects (Ahmad et al., 2012) overweigh their benefits. Consequently, healthcare providers now face a serious lack of new commercial acaricides, and new alternatives are urgently needed.

 

Botanicals could be an environment-friendly solution (Khater, 2013; Seddiek et al., 2013). Our in vitro study signposted that 20 % AEN generated 68.75 and 100.00 % mortality of S. scabiei var. cuniculi larvae after 24 and 48 h, respectively. AEN comprised good effect against sarcoptic mite larvae in vitro as the LC50 values were 11.91, 7.65, and 6.52 %, respectively, after treatment for 24, 48, and 72 h, respectively. The LT values were 160.00 and 33.97 h after treatment with 5 and 10% AEN, respectively. Similar efficacies of neem against S. scabiei var. cuniculi had been reported in vitro. The LC50 value of neem oil was 2.908 mL/L at 24 h PT, and the LT50 values of 500, 250, and 125 mL/L were 1, 2, and 5 h, respectively (Du et al., 2007). Chloroform extract of neem oil induced 100 % mortality after 4.5 h of exposure at a concentration of 200 mg/mL in vitro, with an LC50 value of 0.1 mg/mL at 24 h PT and LT50 of 15.3 h at a concentration of 7.5 mg/mL (Du et al., 2009). The LT50 values for neem oil
(10 %) microemulsion and aqueous emulsion were 81.74 and 95.55 min, respectively (Xu et al., 2010). The LC50 value of the petroleum ether extract of neem (1.3 µL/mL) was about three times that of the chloroform extract (4.1 µL/mL) at 24 h PT. At a concentration of 500.0 µL/mL, the LT50 values of the petroleum ether extract and the chloroform extract were 8.4 and 9.6 h, respectively (Du et al., 2008). Petroleum ether extract of neem oil and its four fractions (F1-F4) possess useful acaricidal activity in vitro as the LC50 value was 70.9 mL/L 24h after treatment. At concentrations of 500.0, 250.0, 125.0, 62.5, and 31.2 mL/L, the LT50 values of the petroleum ether extract were 8.7, 8.8, 10.8, 11.5, and 13.1 h, respectively. Acaricidal activities of 68.3 and 100.0 % in F2 and F4 were confirmed (Deng et al., 2012). In contrast to our results and the previous Endings, Walton et al. (2000) reported that neem showed little acaricidal activity against S. scabiei var. hominis.

 

Our in vivo trial indicated that rabbits infested with S. scabiei var. cuniculi adult and not treated showed mange infestations on the nose, and legs with minor signs of recovery. On the contrary, rabbits treated with DMT and AEN exhibited improvement of clinical signs during the experiment. The reduction percentage of S. scabiei mites on rabbits was 100 and 99 % after treatment with DMT and AEN for 42 days PT, respectively, which was represented clinically by the absence of macroscopic lesions. Likewise, neem oil had been reported to induce recovery of mange affecting other animals, such as sheep (Hirudkar       et al., 1997; Tabassam et al., 2008) and dog (Abdel-Ghaffar et al., 2008a). Neem ointment (5 %) was effective against ear canker of rabbits, psoroptes cuniculi (Joshi et al., 2000). Moreover, neem induced an effective in vivo control of the poultry mite, Dermanyssus gallinae (Lundh et al., 2005; Abdel-Ghaffar et al., 2008b; Locher et al., 2010a, b).

 

Similar to DMT, our in vivo data indicated that neem extract completely cured mange in rabbits. Similarly, the undiluted neem oil killed all S. scabiei var. cuniculi larvae and was significantly higher than pyrethrins, but not significantly different from avermectin (Du et al., 2007). Crude aqueous methanol extract of neem seed kernel (20 %) was found as effective as ivermectin against sarcoptic mange infesting sheep under field conditions (Tabassam et al., 2008).

 

Regarding index scoring, the index scores of rabbits infested with S. scabiei var. cuniculi and treated with DMT or AEN were significantly decreased when compared with those of the infested and non-treated ones (positive control group). Equivalent improvement of lesion scoring was reported for neem as an acaricide against mange in dog (Abdel-Ghaffar et al., 2008a) and sheep (Tabassam et al., 2008).

 

The pesticidal activity of neem oil is generally thought to be due to the tetranortriterpenoid and azadirachtin (Isman et al., 1990). Azadirachtin induces feeding and oviposition deterrence, growth inhibition, and fertility & fitness reductions (Schmutterer 1990). Azadirachtin is a natural plant defense chemical affecting feeding through chemoreception (primary anti-feedancy) that consists in the blockage of the input from receptors that normally respond to phagostimulants or from the stimulation of specific deterrent cells or both (Chapman 1974; Dethier 1982) and through a reduction in food intake due to toxic effects if consumed (secondary antifeedancy), where food intake is reduced after the application of azadirachtin in ways which bypass the mouth part chemoreceptors. In addition, Azadirachtin has growth regulatory effects on larval insects like disruption of molting, growth inhibition, and malformation, which may contribute to mortality. This is attributed to a disruption of endocrine events such as the down regulation of hemolymph ecdysteroid level through the blockage of release of the prothoracicotropic hormone from the brain-corpus cardiacum complex or to a delay in the appearance of the last ecdysteroid peak showing complete molt inhibition (Mordue and Blackwell 1993).

Biochemical analyses indicated that no significant difference of serum AST and total cholesterol in rabbits treated with DMT or AEN when compared with those values in negative control group (rabbits not infested and not treated). While, infested and not treated rabbits (positive control) showed a significant increase of serum AST and total cholesterol. Such results were in agreement with those mentioned for rabbits (Seddiek et al., 2013), layer chickens (Buim    et al., 2013) and cattle (Hussein et al., 2008). However, these results were in disagreement with those obtained for goat (Kumar et al., 2010). Ogbuewu et al., (2010a) reported that neem leaf meal-based diets decreased the serum cholesterol level in rabbit bucks. Serum ALT & creatinine showed no significant difference in all treated groups. Our study revealed that, AEN-treated group did not show any significant difference in serum total protein, albumin and globulin when compared with negative control group. These results were in disagreement with those obtained for rabbits (Seddiek et al., 2013). On the other hand, rabbits infested and not treated (positive control) showed a significant decreased in serum total protein, albumin, and globulin when compared with the corresponding values of other groups. This result similar to that obtained for rabbit (Seddiek et al., 2013) and cattle (Hussein et al., 2008).

 

In our study, AEN could be considered as safe because it had no side effect on the liver and kidney of the treated rabbits. Our data pointed out to the hepato- and renal- protective effects of the neem extract. Similar results were reported by Khalifa et al. (1998) as they found that water suspension of dried leaves of A. indica was hepatoprotective in rabbits infected with Eimeria stiedae, and also by Ezz- Din   et al. (2011) who found that the use of A. indica leaf extract was a promising renal and hepatoprotective agent in rats due to its antioxidant effect and normalization of impaired kidney and liver Unction activities.

 

Regarding growth performance of rabbits in the present study, the body weight and cumulative body weight gain of rabbits in the infested and non-treated group were significantly decreased compared to values of the treated groups. The body weight and cumulative body weight gain of rabbits treated with AEN were significantly increased when compared with such values of positive control group and those treated with DMT (0.005%), on 28 and 42 days PT.  Similar results were reported (Bawa et al., 2007; Ogbuewu et al., 2010a, b and Seddiek et al., 2013). While this result was in disagreement with that obtained for rabbits fed leaf meal (15 %) for 16 weeks. the rabbits did not show any deleterious effects on body weight gain (Ogbuewu et al., 2010b).

 

AEN was found safe for rabbits, as indicated by biochemical analyses in the present study. There are no skin irritations or restlessness during the time of application and afterwards. Similar results had been reported (Tabassam et al., 2008; Schmahl et al., 2010). Along with the economic benefits, additional advantages of using neem pesticides are that they have low environmental persistence (Sundaram and Curry 1994), do not induce resistance readily in insects (Feng and Isman 1995; Jacobson 1995), and are relatively nontoxic to mammals (Jacobson 1995; Larson 1989) and non-target organisms (Condor_Golec 2007).

 

It could be concluded that AEN had in vitro and in vivo acaricidal efficiency similar to that of DMT. It improved the growth performance (body weight and gain) of rabbits infested with S. scabiei var. cuniculi. No significant signs of side effects or adverse reactions were noticed throughout the study. These data provide a platform for the develop­ment of environment-friendly, non-toxic, non-accumulating medicines against acariasis, which could be carried out in a large scale in rabbit farms. Consequently, AEN could be suitable as a promising alternative acaricide for veterinary use. Botanicals could create an herbal remedy export market and thereby create more jobs in developing countries, which will improve our national economy.

 

ACKNOWLEDGMENT

 

The authors thank Prof. Dr. Hanem F. Khater, professor of parasitology, faculty of Vet. Medicine, Benha Univ.Egypt, for her support and advice.

 

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فعالية المستخلص المائي لنباتالنييموالدلتاميثرين ضدحُلمالجرب (سارکوبتسسکابياى فارکونيکولاي)

في الأرانبالمعديةمعملياً

 

علىمحمدمحمدأحمد  ،شاکرصديقعبدالرحمن ، مي عثمان محمد عبد الفتاح، سامح عبد المنعم محمد الألفي

 Email: alimohamed312@yahoo.com         Assiut University web-site: www.aun.edu.eg

 

تهدف هذه الدراسة لمعرفة تأثير المستخلص المائي لنبات النييم کمضاد لحُلــم الجــرب. أولاً: خــارج الجسم- علي أطبــاق بتــري (in-vitro) تم استخدام 5 ترکيزات من المستخلص المائي لنبات النييم (5، 10، 20، 30، 40)، وکذلک استخدم الدلتاميثرين بترکيز (0.005%)، والمجموعة الضابطة استخدم فيها الماء المقطر فقط. تم وضع عدد 20 يرقة (Larvae) في کل طبق بتري علي ورقة ترشيح وهذا لکل ترکيز مستخدم. تم حساب نسبة الوفيات والوقت اللازم للوفاه من کل ترکيز. ثانياً: على الأرانب المصابة معملياً بطفيل جرب السارکوبتس سکابياى فارکونيکولاي (in-vivo). أجريت هذه الدراسة على 40 أرنب نيوزيلاندي أبيض. وقسمت الأرانب إلى أربعة مجموعات متساوية بکل مجموعة 10 أرانب. المجموعة الأولي استخدمت کضابطة سالبة للتجربة، وباقي المجموعات تم إصابتها معملياً بطفيل جرب السارکوبتس سکابياى ڤارکونيکولاي بمعدل 50 طفيل کامل التطور علي مساحة 4 سم طول، و2 سم عرض علي ظهر الأرنب بعد إزالة الشعر من هذه المنطقة /أرنب، وتم معالجتها بعد شهر من الإصابة المعملية. المجموعة الثانية استخدمت کضابط موجب (مصابة معملياً بالجرب وغير معالجة). المجموعة الثالثة مصابة ومعالجة موضعياً بمحلول الدلتاميثرين (0.005%) (50 مليجرام دلتاميثرين/لتر ماء) مرة کل ثلاثة أيام لمدة 3 أسابيع متتالية. المجموعة الرابعة مصابة وتم معالجتها موضعياً بالمستخلص المائي لنبات النييم (20 %) مرة کل ثلاثة أيامً لمدة 3 أسابيع متتالية. تم فحص تأثير المستخلص المائي لنبات النييم خارج الجسم الحي (in-vitro) على طفيل الجرب (سارکوبتس سکابياى ڤارکونيکولاي). وکذلک تم فحص الجسم لتقييم درجة الإصابة (index scores) اسبوعياً بعد العلاج وحتى نهاية التجربة. تم تحديد عدد حلم الجرب على الأرانب المصابة والمعالجة عند 14, 28, 42 يوم بعد العلاج. کما تم تسجيل معايير النمو (وزن الجسم ووزن الجسم المکتسب) قبل العدوي مباشرة ثم کل 14 يوم حتى نهاية التجربة. وتم عمل الفحوص البيوکيميائية في اليوم 28 و 42 بعد العلاج متمثلة في قياس مستوى کل من  ,ALT, ASTالکوليستيرول, الکرياتينين, البروتين الکلى, الألبيومين والجلوبيلين في مصل الدم. وقد أظهرت نتائج الدراسة، أولاً: خارج الجسم الحي (in-vitro) أن المستخلص المائي لنبات النييم له کفاءة علاجية عالية بترکيز30,20, 40 % وذلک من خلال قتله لأکثر من 65 % من طفيل جرب السارکوبتس سکابياى خلال 24 ساعة. ثانياً: کما أظهرت النتائج بعد 42 يوم من العلاج أن المستخلص المائي لنبات النييم يقلل من درجة الإصابة (index scores)، وکذلک يقلل عدد حلم الجرب بعد العلاج بکفاءة 100 %. ثالثا التحليل البيوکيميائي: أظهرت نتائج التحاليل البيوکيميائية أن المستخلص المائي لنبات النييم قد اعاد کافة القياسات البيوکيميائة ((ALT, AST) ومستويات الکوليسترول، والکرياتينين، البروتين الکلي والألبومين، والجلوبيولين بمصل الدم) إلى معادلتها الطبيعية، عند اليوم 28، و42 بعد العلاج. أظهر المستخلص المائي لنبات النييم زيادة في وزن الجسم، ووزن الجسم المکتسب بمقارنة بالأرانب المصابة بحُلم الجرب. نستخلص من هذه الدراسة أن المستخلص المائي لنبات النييم له کفاءة علاجية في الحالات المصابة  بجرب السارکوبتس سکابياى في الأرانب، ويعد بديلاً فعالاً وأمناً عن الأدوية الکيماوية ذات الآثار الجانبية.

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