Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-22T05:31:45.420Z Has data issue: false hasContentIssue false
  • English
  • Français

Comparative efficacy of ivermectin and Nigella sativa against helminths in Aseel chickens (Gallus gallus domesticus)

Published online by Cambridge University Press:  28 August 2018

C. Angel ,
N. Akhter ,
A. Arijo ,
T.A. Qureshi ,
J.A. Gandahi  and
I.H. Qazi Open the ORCID record for I.H. Qazi [Opens in a new window]
C. Angel
Affiliation:
Department of Veterinary Parasitology, College of Veterinary Medicine, Sichuan Agricultural University, Chengdu, China Department of Veterinary Parasitology, Faculty of Veterinary Sciences, Shaheed Benazir Bhutto University of Veterinary and Animal Sciences, Sindh, Pakistan
N. Akhter
Affiliation:
Department of Veterinary Parasitology, Faculty of Animal Husbandry and Veterinary Sciences, Sindh Agriculture University, Sindh, Pakistan
A. Arijo
Affiliation:
Department of Veterinary Parasitology, Faculty of Animal Husbandry and Veterinary Sciences, Sindh Agriculture University, Sindh, Pakistan
T.A. Qureshi
Affiliation:
Shaheed Benazir Bhutto University of Veterinary and Animal Sciences, Sindh, Pakistan
J.A. Gandahi
Affiliation:
Department of Veterinary Anatomy & Histology, Faculty of Animal Husbandry and Veterinary Sciences, Sindh Agriculture University, Sindh, Pakistan
I.H. Qazi*
Affiliation:
Farm Animal Genetic Resources Exploration and Innovation Key Laboratory of Sichuan Province, College of Animal Science and Technology, Sichuan Agricultural University, Chengdu, China Department of Veterinary Anatomy & Histology, Faculty of Bio-Sciences, Shaheed Benazir Bhutto University of Veterinary and Animal Sciences, Sindh, Pakistan
*
Author for correspondence: I.H. Qazi, E-mail: vetdr_izhar@yahoo.com
Rights & Permissions [Opens in a new window]

Abstract

In this study, we evaluated the in vivo comparative efficacy of ivermectin and Nigella sativa extract against helminths in Aseel chickens, and the effects of helminths on blood parameters before and after treatment in Aseel chickens. Forty naturally infected adult Aseel chickens were randomly divided into four groups (n = 10 each): group A (ivermectin at 300 μg/kg); group B (N. sativa extract at 200 mg/kg); group C (ivermectin at 300 μg/kg + N. sativa extract at 200 mg/kg); group D was kept as a positive control to monitor time-related changes. On day 28 post treatment, the mean percentages of faecal egg-count reduction (FECR %) in groups A, B and C were recorded as 93.58, 88.09 and 100.00%, respectively. Further data analysis showed significantly higher efficacy in group C (100 ± 0.00%) than in groups A and B (P < 0.001). Highly significant (P < 0.001) improvements in mean percentage values of packed cell volume (PCV %) were recorded in groups A and C on days 14 and 28 post treatment. Meanwhile, the improvements in mean values of haemoglobin (Hb) concentration in groups A, B and C were highly significant (P < 0.001) when compared to that of group D on day 28 post treatment. The synergistic combination of ivermectin and N. sativa extract possessed greater efficacy than either ivermectin or N. sativa extract used alone. Furthermore, both PCV % and Hb concentration values gradually increased in the treated groups compared to the control group, in which PCV % and Hb concentration gradually decreased throughout the trial.

Keywords

Aseel chickenefficacyhelminthsivermectinnematodeNigella sativa
Type
Research Paper
Information
Journal of Helminthology , Volume 93 , Issue 5 , September 2019 , pp. 533 - 538
Copyright
Copyright © Cambridge University Press 2018 

Introduction

The Aseel (Gallus gallus domesticus) is the native, tallest and largest chicken breed of Pakistan, and is found especially in Punjab and Sindh provinces (Babar et al., Reference Babar2012). Amid the indigenous chicken breeds of the Indo-Pak subcontinent, the Aseel is the most popular and significant breed, and is a major source of income for rural people. The Aseel is an excellent meat producer and is the ancestor of the White Cornish and Plymouth Rock breeds, both of which are parents of the present-day commercial broiler (Platt, Reference Platt1925; Dohner, Reference Dohner2001; Jatoi et al., Reference Jatoi2015). However, in spite of its enormous production potential and significance, the Aseel breed has been overlooked by researchers.

Helminthiasis has been regarded as an important factor related to the poor production of rural chickens. Parasites are a problem wherever poultry are raised, whether in large commercial systems or in rural backyard farming, and can result in huge economic losses (Ruff, Reference Ruff1999). In backyard poultry farming, indigenous chickens are reared in a free-range scavenging system, which poses a relatively higher risk of parasitic infections, in particular gastrointestinal helminth infections, occurring (Aini, Reference Aini1990).

Ivermectin (a semi-synthetic anthelmintic) belongs to the family of drugs known as avermectins (Fisher et al., Reference Fisher, Mrozik, Campbell and Campbell1989). These compounds are reported to have at least 25 times more potency compared to the preceding generation of anthelmintics, and exhibit a broad spectrum of activity against nematodes and arthropod parasites of domestic animals (Shoop et al., Reference Shoop1995). To date, very few studies have been conducted to elucidate the efficacy of ivermectin against helminths in various avian species (Okaeme, Reference Okaeme1988; Shahadat et al., Reference Shahadat2008; Ibarra-Velarde et al., Reference Ibarra-Velarde2011; Khayatnouri et al., Reference Khayatnouri2011; Mirhadi et al., Reference Mirhadi2011; Islam et al., Reference Islam2012; Zia-ur-Rehman et al., Reference Zia-ur-Rehman2014), and evidence of resistance of gastrointestinal helminths against ivermectin in poultry has not been reported. However, due to the mounting development of anthelmintic resistance, limited availability and high cost of commercial anthelmintics, there is increasing interest in the ethno-veterinary approach to screening the anthelmintic properties of traditionally used medicinal plants (Kaplan, Reference Kaplan2004; Mali and Mehta, Reference Mali and Mehta2008), giving impetus to the search for new compounds from plant origin as alternative methods of helminth control (Veerakumari, Reference Veerakumari2015). Nigella sativa (Linn.) is an indigenous herbaceous plant that is commonly known as the fennel flower plant and belongs to the buttercup or Ranunculaceae family (Ahmad et al., Reference Ahmad2013). Nigella sativa seeds are reported to contain many chemical compounds and active ingredients, including nigellone, thymoquinone and essential oil (Akhtar, Reference Akhtar1988). The anthelmintic efficacy of N. sativa has been reported in some earlier studies (Akhtar and Javed, Reference Akhtar and Javed1991; Kailani et al., Reference Kailani, Akhtar and Ashraf1995; Al-Shaibani et al., Reference Al-Shaibani2008).

Considering the need for efficient and cost-effective treatment of helminth infections that are causing significant production losses in backyard poultry (Ruff, Reference Ruff1999; Katoch et al., Reference Katoch2012), and the increasing anthelmintic resistance worldwide (Waller et al., Reference Waller1996; Jabbar et al., Reference Jabbar2006), it would be of great value to scrutinize the synergistic efficacy of modern and safer anthelmintic drugs and important medicinal plants possessing broad-spectrum anthelmintic properties. The current study was therefore conducted to (1) evaluate the comparative efficacy of ivermectin and N. sativa in adult Aseel chickens, and (2) assess the effects of helminths on percentage of packed cell volume (PCV %) and haemoglobin (Hb) concentration (g/dl) in naturally infected adult Aseel chickens before and after treatment with ivermectin and N. sativa extract.

Materials and methods

Study animals

In order to obtain a pool of naturally infected birds, a total of 228 adult Aseel chickens (irrespective of sex) were randomly subjected to coprological examination. The chickens were obtained from local farmers in our vicinity. Backyard poultry are usually reared in free-range or semi-intensive rearing systems, and poultry farmers keep small flocks of 5 to 15–20 birds.

From these 228 Aseel chickens, forty adults were randomly selected and divided into four groups, A, B, C and D (n = 10 each). Birds in all four groups were naturally infected with various helminth species: Ascaridia galli, Heterakis gallinarum and Syngamus trachea (pure or mixed infection).

For further experimental procedures, the selected birds were maintained at the poultry demonstration farm of the Shaheed Benazir Bhutto University of Veterinary and Animal Sciences (SBBUVAS), Sakrand, Pakistan under semi-intensive rearing conditions, i.e. birds were provided with sheds and a large fenced area for ranging. At night they were usually shut in the sheds. Moreover, all birds were offered ad libitum water and feed of broken wheat, rice and barley grains. Birds in all four groups were separated from each other by chicken mesh wire partitions. The night before faecal sample collection, birds of each group were individually confined to a specified floor area covered with brown chick paper in order to minimize the chances of mixing of faeces.

Collection of faecal samples

Fresh faecal samples were collected early in the morning (pre-feeding) and transferred to wide-mouth screw-capped plastic jars containing 10% formalin solution for preservation. Then the samples were brought to the Department of Veterinary Parasitology, SBBUVAS, for coprological examination.

Coprological examination

Faecal samples were processed for qualitative and quantitative examinations. Qualitative examination of faecal samples was performed by direct smear and flotation methods, and the McMaster technique was used for quantitative examination (Urquhart et al., Reference Urquhart1996). Samples found to be negative using the direct smear method were subjected to the flotation method for confirmation. The McMaster technique was performed to quantify eggs per gram (EPG) in positive samples (Whitlock, Reference Whitlock1948; Urquhart et al., Reference Urquhart1996). Helminth species were identified using the standard key as described by Thienpont et al. (Reference Thienpont, Rochette and Vanparijs1979) and Soulsby (Reference Soulsby1982).

Preparation of Nigella sativa extract

Authenticated dried seeds of N. sativa were purchased from a local market in Sakrand, Pakistan. The extract was prepared as described by Shalaby et al. (Reference Shalaby2012) and Jamila and Al-Malki (Reference Jamila and Al-Malki2013). The condensed N. sativa extract was preserved in a tightly corked, labelled bottle and stored in a refrigerator at 4°C for further use in experiments (Beshay, Reference Beshay2018).

Experimental design

On the basis of faecal egg count (FEC), 40 naturally infected adult Aseel chickens were used for the evaluation of anthelmintic activity of ivermectin (Ivomec®, 1% sterile solution, by Merial) and N. sativa extract alone and in combination. The dose of N. sativa extract was adopted from a previous study published by the researchers from our group (Al-Shaibani et al., Reference Al-Shaibani2008), and the dose of ivermectin was adopted from Sharma and Bhat (Reference Sharma and Bhat1990). However, bearing in mind the scavenging behaviour of backyard poultry and the high chance of continuous re-infection, we used a booster dose in all the treatment groups. At the time of treatment, a number of parasitic larvae may be passing through the histotrophic stage and are therefore not well exposed to the anthelmintics. The histotrophic phase of many nematode species in birds ranges from 3 to 54 days before final maturation (Herd and McNaught, Reference Herd and McNaught1975).

Forty naturally infected adult Aseel chickens were randomly divided into groups A, B, C and D (n = 10 each). Group A was treated with ivermectin at 300 μg/kg by subcutaneous route on day 1, followed by a booster dose on day 15. Group B was treated with N. sativa extract at 200 mg/kg by oral route on days 1 and 2, followed by a booster dose on days 15 and 16. Group C was treated with ivermectin at 300 μg/kg by subcutaneous route on day 1, followed by a booster dose on day 15, along with N. sativa extract at 200 mg/kg by oral route on days 1 and 2, followed by a booster dose on days 15 and 16. Group D was kept as a positive control to monitor time-related changes.

Throughout the experiment, fresh faecal and blood samples were collected from each bird on days 0 (pre-treatment), 7, 14 and 28 (post-treatment). Furthermore, EPG values were recorded by the McMaster technique, as described previously. Haematological indices, namely PCV % and Hb concentration (g/dl), were determined by the Microhematocrit method and Sahli's hemoglobinometer method, respectively (Coles, Reference Coles1986). For haematological studies, c. 0.5 ml of venous blood was collected from wing vein in a vial containing EDTA.

Estimation of anthelmintic efficacy

Estimation of anthelmintic efficacy of ivermectin and N. sativa extract was carried out according to the field controlled faecal egg count reduction test (FECRT) (Coles and Roush, Reference Coles and Roush1992; Taylor et al., Reference Taylor, Hunt and Goodyear2002).

Data analysis

Data were analysed using GraphPad Instat software (version 3.05). Variations among weekly intervals and groups under study were analysed through one-way analysis of variance (ANOVA) and Tukey's test. A P value < 0.05 was considered to be statistically significant. Data are presented as mean ± standard deviation (SD).

Results

The mean values of EPG (pre- and post-treatment) and faecal egg count-reduction percentage (FECR %) in groups A, B, C and D are shown in table 1. Briefly, the mean values of EPG were significantly reduced in groups A, B and C on days 7, 14 and 28 post treatment. Reduction in EPG was highly significant (P < 0.001) in groups A and C throughout the post-treatment period. However, the difference in mean values of EPG in group B was very significant (P < 0.01) on day 7 and highly significant (P < 0.001) on days 14 and 28 post treatment. Meanwhile, no reductions were observed in mean values of EPG in group D; instead a gradual increase (P > 0.05) was recorded on days 7, 14 and 28.

Table 1. Mean values of eggs per gram (EPG) and percentage faecal egg count reduction (FECR %, in parentheses) of helminth species in Aseel chickens before and after different treatments: group A, ivermectin at 300 μg/kg (2 doses) by subcutaneous route; group B, Nigella sativa oil extract at 200 mg/kg (4 doses) by oral route; group C, ivermectin combined with Nigella sativa oil extract at 300 μg/kg (2 doses) by subcutaneous route and 200 mg/kg dose rate (4 doses) by oral route, respectively; group D, control without treatment.

a Values with same letters in same rows have highly significant difference (P < 0.001).

b Values with same letters in same rows have very significant difference (P < 0.01).

c Values with same letters in same row have non-significant difference (P > 0.05).

Values with same superscripts in same column have highly significant difference (P < 0.001).

* Values with same superscripts in same column have significant difference (P < 0.05).

˄ Values with same superscripts in same column have non-significant difference (P > 0.05).

Moreover, a rapid increase in FECR % was recorded in group C compared to groups A and B on days 7, 14 and 28 post treatment. On day 28 post treatment, the mean percentages of faecal egg count reduction (FECR %) in groups A, B and C were recorded as 93.58, 88.09 and 100.00%, respectively. Further data analysis showed significantly higher efficacy (P < 0.001) in group C (100 ± 0.00%) than in groups A and B (table 1).

The mean values of PCV % in groups A, B, C and D are shown in table 2. Briefly, the mean values of PCV % in group A were significantly (P < 0.05) improved on day 14 post treatment, however, highly significant (P < 0.001) improvements in PCV % were recorded on day 28 post treatment. The mean values of PCV % in group B were improved very significantly (P < 0.01) on day 28 post treatment. Meanwhile, the improvements in PCV % in group C were very significant (P < 0.01) and highly significant (P < 0.001) on days 14 and 28 post treatment, respectively. On day 28 post treatment, further data analysis showed that the variations in mean values of PCV % in groups A, B and C were non-significant (P > 0.05). However, the improvements in mean values of PCV % in groups B and C were highly significant (P < 0.001) compared to group D. Furthermore, the mean values of PCV % in group A were very significantly improved (P < 0.01) compared to that of group D on day 28 post treatment.

Table 2. Mean values of PCV (%) of Aseel chickens before and after different treatments: group A, ivermectin at 300 μg/kg (2 doses) by subcutaneous route; group B, Nigella sativa oil extract at 200 mg/kg (4 doses) by oral route; group C, ivermectin combined with Nigella sativa oil extract at 300 μg/kg (2 doses) by subcutaneous route and 200 mg/kg dose rate (4 doses) by oral route, respectively; group D, control without treatment.

a Values with same letters in same rows have very significant difference (P < 0.01).

b Values with same letters in same rows have highly significant difference (P < 0.001).

c Values with same letters in same rows have non-significant difference (P > 0.05).

* Values with same superscript in same column have non-significant difference (P > 0.05).

d Values with same letters in same column have very significant difference (P < 0.01).

Values with same superscript in same column have highly significant difference (P < 0.001).

Values with same superscript in same column have highly significant difference (P < 0.001).

The mean values of Hb concentration in groups A, B, C and D are presented in table 3. Highly significant (P < 0.001) improvements were recorded in mean values of Hb concentration in groups A and C on days 14 and 28 post treatment. Meanwhile, the improvements in mean values of Hb concentration in group B were very significant (P < 0.01) on day 28 post treatment only. On day 28 post treatment, further data analysis indicated that the variations in mean values of Hb concentration in groups A and B were very significant (P < 0.01). Furthermore, the improvements in mean values of Hb concentration in groups A, B and C were highly significant (P < 0.001) compared to that of group D on day 28 post treatment. However, the improvements in mean values of Hb concentration were very significantly different (P < 0.01) in groups A and C on day 28 post treatment.

Table 3. Mean values of Hb concentration (g/dl) of Aseel chickens before and after different treatments: group A, ivermectin at 300 μg/kg (2 doses) by subcutaneous route; group B, Nigella sativa oil extract at 200 mg/kg (4 doses) by oral route; group C, ivermectin combined with Nigella sativa oil extract at 300 μg/kg (2 doses) by subcutaneous route and 200 mg/kg dose rate (4 doses) by oral route, respectively; group D, control without treatment.

a Values with same letters in same rows have non-significant difference (P > 0.05).

b Values with same letters in same rows have highly significant difference (P < 0.001).

c Values with same letters in same rows have very significant difference (P < 0.01).

* Values with same superscript in same column have very significant difference (P < 0.01).

Values with same superscript in same column have highly significant difference (P < 0.001).

˄ Values with same superscript in same column have very significant difference (P < 0.01).

Values with same superscript in same column have highly significant difference (P < 0.001).

Values with same superscript in same column have highly significant difference (P < 0.001).

Discussion

The findings of the present study provide evidence that ivermectin and N. sativa possess significant efficacy against helminths in backyard poultry. As for the efficacy of ivermectin, the results of our study are consistent with those of Zia-ur-Rehman et al. (Reference Zia-ur-Rehman2014) and Khayatnouri et al. (Reference Khayatnouri2011), who reported 94.11% and 99% efficacy of ivermectin against Ascaridia galli (in commercial layer birds) and Heterakis species (in native chicken), respectively. Similarly, Shahadat and colleagues also reported a comparable (90–100%) efficacy of ivermectin against Ascaridia galli in indigenous chickens (Shahadat et al., Reference Shahadat2008).

We also observed a significant anthelmintic efficacy of N. sativa extract against the helminth species infecting the Aseel chickens. However, despite the apparent lack of relevant studies available in the literature, the results of our study are consistent with findings of Kailani et al. (Reference Kailani, Akhtar and Ashraf1995) and Maqbool et al. (Reference Maqbool, Hayat and Tanveer2004), who evaluated the anthelmintic activity of N. sativa against Fasciola hepatica in buffaloes and reported 88.2% and 80.8% efficacy, respectively. Furthermore, the results of our study are also supported by a previous study reporting the significant anthelmintic activity of essential oils of N. sativa against earthworms, tapeworms and nodular worms (Agarwal et al., Reference Agarwal, Kharya and Shrivastava1979). Similarly, in a recent study, 100% efficacy of N. sativa oil has been observed against Hymenolepis nana in mice (Al-Megrin, Reference Al-Megrin2016). The anthelmintic efficacy of N. sativa has also been evaluated in other mammals, with varying degrees of effectiveness. Al-Shaibani et al. (Reference Al-Shaibani2008) reported 69.5% efficacy of ethanolic extracts of N. sativa against helminths in sheep. Similarly, Ayaz et al. (Reference Ayaz2007) reported 66.6% efficacy of N. sativa against Aspiculuris tetrapetra in mice. Discrepancy in the results may be due to the differences in dose quantity, nature of preparation used, study animal and parasite species and genetic variation of individual plants.

Among the bioactive constituents present in N. sativa seeds and oil, thymoquinone has been regarded as an important phytochemical anthelmintic arsenal. Thymoquinone has been reported to cause surface tegumental damage in a number of helminth species, including the tropical liver fluke, Fasciola gigantica (Shalaby et al., Reference Shalaby2012). However, at present, the mode of action of thymoquinone is largely unknown. Recently, Ullah and colleagues reported that the oxidative damage of parasite proteins as revealed by their carbonylation, which serves as a biomarker of protein damage, was significantly increased in F. gigantica worms following treatment with thymoquinone in a concentration-dependent mode. The recognition of carbonylated proteins may furnish the biomarkers for oxidative impairment induced by thymoquinone in helminths (Ullah et al., Reference Ullah2017). In addition to this, the anthelmintic activity of N. sativa may also be attributed to its other bioactive compounds, through improvement in nutritional status and boosting effects on host immunity. It has been reported that after ingestion of condensed tannins by adult worms, the intestinal mucosa is disturbed at varying levels and leads to the destruction of parasites (Athanasiadou et al., Reference Athanasiadou2001). Furthermore, N. sativa seeds are reported to inhibit egg-laying in adult female worms and exhibit active biocidal effects against miracidia, cercariae and adult worm stages of Schistosoma mansoni (Mohamed et al., Reference Mohamed, Metwally and Mahmoud2005).

In order to evaluate the synergistic effects, N. sativa has been used in combination with certain chemical anthelmintic agents in the past. Nigella sativa oil used in combination with praziquantel in mice produced better results (in terms of reduction in number of eggs produced by Schistosoma mansoni) compared to praziquantel used alone (Mahmoud et al., Reference Mahmoud, El-Abhar and Saleh2002). Furthermore, in the present study we observed that the synergistic combination of ivermectin and N. sativa extract possessed greater efficacy than either ivermectin or N. sativa extract used alone. Before this, no in vivo study investigated the synergistic combination of ivermectin and N. sativa in chickens. However, the results of our study are in conformity with previous studies reporting the synergistic effect of ivermectin and N. sativa against helminths in vitro. In 2012, Shalaby et al. tested the combination of ivermectin and N. sativa and reported that the combination of these two agents is far more efficacious than either ivermectin or N. sativa when used alone (Shalaby et al., Reference Shalaby2012). Jamila and Al-Malik (Reference Jamila and Al-Malki2013) used the same combination and reported a significant efficacy against Moniezia expansa. However, despite the enticing evidence from these two in vitro studies and the findings of our present in vivo study, further experimentation is required to fully elucidate the exact underlying mechanisms responsible for such synergistic anthelmintic effects of ivermectin or N. sativa extract.

Parasitic infections constantly affect the overall health and productivity of animals, and haematological studies may provide significant entropy regarding such damage (Hafeez, Reference Hafeez1996). The total blood Hb concentration is an indicator of the capacity of birds to meet their oxygen demands. In avian species, regenerative anaemias are usually induced by parasite-stimulated haemorrhages and haemolysis (Boyd, Reference Boyd1951). As such, Hb concentrations are hypothesized to serve as a strong indicator of physiological conditions in avian species (Bańbura et al., Reference Bańbura2007). Assessment of PCV % is a good indicator of developing anaemia and associated problems induced by helminths. The haematological observations of our study are consistent with the findings of Fatihu et al. (Reference Fatihu1991), Rehman (Reference Rehman1993), Khan et al. (Reference Khan2006), Mazur et al. (Reference Mazur, Pronin and Tolochko2007), Deka and Borah (Reference Deka and Borah2008), and Adang et al. (Reference Adang2012), who have all reported a decline in Hb concentrations in infected birds compared to treated birds. Similar findings have also been reported by Krivutenko (Reference Krivutenko1980), Matta and Ahluwalia (Reference Matta and Ahluwalia1982), and Kumar et al. (Reference Kumar2003), who reported lowered PCV % and Hb concentrations in infected birds. This may be attributed to the larval migration and accompanying disruption of mucus membrane of small intestines in penetrative infective stages and the resultant rupture of small blood vessels in the tissue phase of the life cycle of helminth parasites, which involves some blood loss. The decline in Hb concentrations may also be attributed to metabolic disturbance caused by the helminths, rather than direct blood loss (Kumar et al., Reference Kumar2003). Consistent with our findings, improvements in PCV % and Hb concentration have been observed in infected chickens following ivermectin treatment (Sufian et al., Reference Sufian2006; Shahadat et al., Reference Shahadat2008). Similarly, Hassan and colleagues observed significant improvements in PCV % and Hb concentration in Bengal goats following ivermectin treatment (Hassan et al., Reference Hassan2012). These gradual improvements in haematological indices may be ascribed to a gradual decrease in number of parasites in the treated groups compared to the control group. The post-treatment upswing in mean PCV % is most probably associated with the rising Hb concentration, as these are closely related.

To sum up, our study is the first to demonstrate a synergistic anthelmintic effect of ivermectin and N. sativa in backyard poultry, particularly the Aseel chicken, and may serve as a foundation for future research focused on potential anthelmintic remedies in poultry. In general, the results of our study also support the hypothesis of using drug combinations against helminth infections in domestic birds, particularly backyard poultry. Moreover, in order to examine the broader anthelmintic potential of ivermectin and N. sativa, further controlled experimental studies involving other species of avian helminths (one parasite species being studied at a time) would be of great importance. However, for a comprehensive and multidirectional understanding of the anthelmintic potential of N. sativa and its active ingredients, detailed studies are warranted. Being cheaper and easily available in rural areas, further studies on the anthelmintic potential of N. sativa will greatly contribute to the design of practical and cost-effective solutions to reduce the ignored helminth infections in backyard poultry.

Acknowledgements

We thank the Shaheed Benazir Bhutto University of Veterinary and Animal Sciences, Sakrand, Pakistan for providing necessary facilities for the conduct of this study. We extend our sincere gratitude to Professor Dr Ahmed Sultan B. Jatoi (a renowned Professor of Poultry Sciences and Ex-Vice Chancellor of Shaheed Benazir Bhutto University of Veterinary and Animal Sciences, Sakrand, Pakistan) for critically reviewing the final version of this manuscript. All authors are equally thankful to Professor Dr Margaret Rayman, Co-Director Nutritional Medicine MSc Programme, Department of Nutritional Sciences, Faculty of Health and Medical Sciences, University of Surrey, UK, for her help (in part) in revising the final draft of this manuscript. We also extend our sincere regards to three anonymous reviewers for their constructive criticism and valuable inputs.

Financial support

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

Conflict of interest

None.

Ethical standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the animal ethics committee governed by Shaheed Benazir Bhutto University of Veterinary and Animal Sciences, Sakrand, Pakistan.

References

Adang, IK et al. (2012) Effects of Ascaridia galli infection on body weight and blood parameters of experimentally infected domestic pigeons (Columba livia domestica) in Zaria, Nigeria. Revista Científica UDO Agrícola 12, 960964.Google Scholar
Agarwal, R, Kharya, M and Shrivastava, R (1979) Antimicrobial & anthelmintic activities of the essential oil of Nigella sativa Linn. Indian Journal of Experimental Biology 17, 12641265.Google Scholar
Ahmad, A et al. (2013) A review on therapeutic potential of Nigella sativa: a miracle herb. Asian Pacific Journal of Tropical Biomedicine 3, 337352.Google Scholar
Aini, I (1990) Indigenous chicken production in South-east Asia. World's Poultry Science Journal 46, 5157.Google Scholar
Akhtar, M (1988) Anthelmintic evaluation of indigenous medicinal plants for veterinary usage. Final Report of the PARC Research Project (1985–86), University of Agriculture, Faisalabad, Pakistan.Google Scholar
Akhtar, M and Javed, I (1991) Efficacy of Nigella sativa Linn. seeds against Moniezia infection in sheep. Indian Veterinary Journal 68, 726729.Google Scholar
Al-Megrin, WA (2016) Efficacy of black seeds oil (Nigella sativa) against Hymenolepis nana in infected mice. European Journal of Medicinal Plants 13, 17.Google Scholar
Al-Shaibani, I et al. (2008) Anthelmintic activity of Nigella sativa Linn. seeds on gastrointestinal nematodes of sheep. Pakistan Journal of Nematology 26, 207218.Google Scholar
Athanasiadou, S et al. (2001) Direct anthelmintic effects of condensed tannins towards different gastrointestinal nematodes of sheep: in vitro and in vivo studies. Veterinary Parasitology 99, 205219.Google Scholar
Ayaz, E et al. (2007) The effect of Nigella sativa oil against Aspiculuris tetraptera and Hymenolepis nana in naturally infected mice. Saudi Medical Journal 28, 16541657.Google Scholar
Babar, ME et al. (2012) Microsatellite marker based genetic diversity among four varieties of Pakistani Aseel chicken. Pakistan Veterinary Journal 32, 237241.Google Scholar
Bańbura, J et al. (2007) Habitat and year-to-year variation in haemoglobin concentration in nestling blue tits Cyanistes caeruleus. Comparative Biochemistry and Physiology Molecular & Integrative Physiology 148, 572577.Google Scholar
Beshay, E (2018) Therapeutic efficacy of Artemisia absinthium against Hymenolepis nana: in vitro and in vivo studies in comparison with the anthelmintic praziquantel. Journal of Helminthology 92, 298308.Google Scholar
Boyd, EM (1951) The external parasites of birds: a review. The Wilson Bulletin 63, 363369.Google Scholar
Coles, EH (1986) Veterinary Clinical Pathology, 4th Edn. Philadelphia, PA: WB Saunders Company.Google Scholar
Coles, G and Roush, R (1992) Slowing the spread of anthelmintic resistant nematodes of sheep and goats in the United Kingdom. The Veterinary Records 130, 505510.Google Scholar
Deka, K and Borah, J (2008) Haematological and biochemical changes in Japanese quails Coturnix coturnix japonica and chickens due to Ascaridia galli infection. International Journal of Poultry Science 7, 704710.Google Scholar
Dohner, JW (2001) The Encyclopedia of Historic and Endangered Livestock and Poultry Breeds. Yale Agrarian Studies Series. New Haven, CT: Yale University Press, pp. 425427.Google Scholar
Fatihu, M et al. (1991) Comparative studies on gastrointestinal helminths of poultry in Zaria, Nigeria. Journal of Tropical Livestock Science 44, 175177.Google Scholar
Fisher, M, Mrozik, H and Campbell, W (1989) Chemistry. In Campbell, WC (ed.), Ivermectin and Abamectin. New York, NY: Springer, pp. 123.Google Scholar
Hafeez, M (1996) A Study of Gastrointestinal Parasitism and Hematological Disturbance Associated with Single or Multiple Infections in Sheep (MSc thesis). College of Veterinary Sciences, Lahore, Pakistan.Google Scholar
Hassan, MM et al. (2012) Efficacy of anthelmintics against parasitic infections and their treatment effect on the production and blood indices in black Bengal goats in Bangladesh. Turkish Journal of Veterinary and Animal Sciences 36, 400408.Google Scholar
Herd, RP and McNaught, DJ (1975) Arrested development and the histotrophic phase of Ascaridia galli in the chicken. International Journal for Parasitology 5, 401406.Google Scholar
Ibarra-Velarde, F et al. (2011) Comparison of the anthelmintic efficacy of three commercial products against ascarids and Capillaria spp. in fighting cocks. Pharmacology & Pharmacy 2, 146.Google Scholar
Islam, A et al. (2012) Efficacy of anthelmintics against nematodes in naturally infected free range ducks. Eurasian Journal of Veterinary Science 28, 229232.Google Scholar
Jabbar, A et al. (2006) Anthelmintic resistance: the state of play revisited. Life Sciences 79, 24132431.Google Scholar
Jamila, S and Al-Malki, (2013) In vitro efficacy of a combination of Stromectol and Nigella sativa oil against cestodes in sheep, Taif, Saudi Arabia. World Applied Sciences Journal 27, 413417.Google Scholar
Jatoi, AS et al. (2015) Carcass characteristics and organ development in four different varieties of native Aseel chicken of Pakistan. Pakistan Journal of Science 67, 127132.Google Scholar
Kailani, S, Akhtar, M and Ashraf, M (1995) Antifasciolic efficacy of indigenous plant and drugs: Kalonji, Shahterah and Karanjwa in buffaloes. Pakistan Journal of Pharmaceutical Sciences 8, 1727.Google Scholar
Kaplan, RM (2004) Drug resistance in nematodes of veterinary importance: a status report. Trends in Parasitology 20, 477481.Google Scholar
Katoch, R et al. (2012) Prevalence and impact of gastrointestinal helminths on body weight gain in backyard chickens in subtropical and humid zone of Jammu, India. Journal of Parasitic Diseases 36, 4952.Google Scholar
Khan, MA et al. (2006) Prevalence and effect of helminthiasis on haematological parameters in the migratory sparrows (Alauda arvensis) and treatment with an antihelmintic, fenbendazole. Pakistan Journal of Zoology 38, 105.Google Scholar
Khayatnouri, M et al. (2011) The effect of ivermectin pour-on administration against natural Heterakis gallinarum infestation and its prevalence in native poultry. American Journal of Animal and Veterinary Sciences 6, 5558.Google Scholar
Krivutenko, A (1980) Some aspects of the pathology of Heterakis infection in turkeys. In Patomorfologiya, patogenez I diagnostika bolenzei sel’ sel’ skokhozyaistvennykh zhivotnykh. Moscow, USSR: Kolos, pp. 239240.Google Scholar
Kumar, R et al. (2003) Haematological changes in the Japanese quails (Coturnix coturnix japonica) naturally infected with nematode Ascaridia galli. Indian Veterinary Medical Journal 27, 297299.Google Scholar
Mahmoud, M, El-Abhar, H and Saleh, S (2002) The effect of Nigella sativa oil against the liver damage induced by Schistosoma mansoni infection in mice. Journal of Ethnopharmacology 79, 111.Google Scholar
Mali, RG and Mehta, AA (2008) A review on anthelmintic plants. Natural Product Radiance 7, 466475.Google Scholar
Maqbool, A, Hayat, CS and Tanveer, A (2004). Comparative efficacy of various indigenous and allopathic drugs against fasciolosis in buffaloes. Veterinarski arhiv 74, 107114.Google Scholar
Matta, S and Ahluwalia, S (1982) Haematological indices as influenced by Ascaridia galli infection fowls. Indian Journal of Poultry Science 17, 4651.Google Scholar
Mazur, O, Pronin, N and Tolochko, L (2007) Hematological and immunological properties of herring gull (Larus argentatus) nestlings experimentally infected with Diphyllobothrium dendriticum (Cestoda: Pseudophyllidae). Biological Bulletin 34, 346352.Google Scholar
Mirhadi, K et al. (2011) The effect of ivermectin pour on administration against natural Heterakis gallinarum infestation and its prevalence in native poultry. American Journal of Animal and Veterinary Sciences 6, 5558.Google Scholar
Mohamed, AM, Metwally, NM and Mahmoud, SS (2005) Sativa seeds against Schistosoma mansoni different stages. Memórias do Instituto Oswaldo Cruz 100, 205211.Google Scholar
Okaeme, A (1988) Ivermectin in the control of helminthiasis in guinea fowl Numida meleagris galeata Pallas. Veterinary Quarterly 10, 7071.Google Scholar
Platt, FL (1925) All breeds of poultry: origin, history, description, mating and characteristics. American Poultry Journal 45, 181187.Google Scholar
Rehman, R (1993) A Study on the Prevalence of Ascaridia galli and the Effects of Experimental Infection on Various Blood Parameters and Body Weight Gain in the Chicken (MSc thesis). University of Agriculture, Faisalabad, Pakistan.Google Scholar
Ruff, MD (1999) Important parasites in poultry production systems. Veterinary Parasitology 84, 337347.Google Scholar
Shahadat, H et al. (2008) Comparative efficacy of korolla (Momordica charantia) extract and Ivermec® pour on with their effects on certain blood parameters and body weight gain in indigenous chicken infected with Ascaridia galli. Bangladesh Journal of Veterinary Medicine 6, 153158.Google Scholar
Shalaby, H et al. (2012) In vitro efficacy of a combination of ivermectin and Nigella sativa oil against helminth parasites. Global Veterinaria 9, 465473.Google Scholar
Sharma, R and Bhat, T (1990) Anthelmintic activity of ivermectin against experimental Ascaridia galli infection in chickens. Veterinary Parasitology 37, 307314.Google Scholar
Shoop, W et al. (1995) Avermectins and milbemycins against Fasciola hepatica: In vivo drug efficacy and in vitro receptor binding. International Journal for Parasitology 25, 923927.Google Scholar
Soulsby, EJL (1982) Helminths, Arthropods and Protozoa of Domesticated Animals (7th edn). London, UK: Bailliere Tindall.Google Scholar
Sufian, A et al. (2006) Comparative efficacy of albendazole, ivermectin and korolla (Momordica charantica) fruit extract against naturally infected ascariasis in indigenous chicken. Progressive Agriculture 17, 121126.Google Scholar
Taylor, M, Hunt, K and Goodyear, K (2002) Anthelmintic resistance detection methods. Veterinary Parasitology 103, 183194.Google Scholar
Thienpont, D, Rochette, F and Vanparijs, OFJ (1979) Diagnosing Helminthiasis Through Coprological Examination. Beerse, Belgium: Janssen Research Foundation.Google Scholar
Ullah, R et al. (2017) Anthelmintic potential of thymoquinone and curcumin on Fasciola gigantica. PLoS ONE. 12, e0171267.Google Scholar
Urquhart, GM et al. (1996) Veterinary Parasitology, 2nd ed. Glasgow, UK: Blackwell Sciences, pp. 3137.Google Scholar
Veerakumari, L (2015) Botanical anthelmintics. Asian Journal of Science and Technology 6, 18811894.Google Scholar
Waller, P et al. (1996) The prevalence of anthelmintic resistance in nematode parasites of sheep in southern Latin America: general overview. Veterinary Parasitology 62, 181187.Google Scholar
Whitlock, HV (1948) Some modifications of the McMaster helminth egg-counting technique and apparatus. Journal of the Council for Scientific and Industrial Research. Australia 21, 177180.Google Scholar
Zia-ur-Rehman, AM et al. (2014) Comparative therapeutic efficacy of ivermectin and piperazine citrate against Ascaridia galli in commercial and rural poultry. Scholar's Advances in Animal and Veterinary Research 1, 2024.Google Scholar
Figure 0

Table 1. Mean values of eggs per gram (EPG) and percentage faecal egg count reduction (FECR %, in parentheses) of helminth species in Aseel chickens before and after different treatments: group A, ivermectin at 300 μg/kg (2 doses) by subcutaneous route; group B, Nigella sativa oil extract at 200 mg/kg (4 doses) by oral route; group C, ivermectin combined with Nigella sativa oil extract at 300 μg/kg (2 doses) by subcutaneous route and 200 mg/kg dose rate (4 doses) by oral route, respectively; group D, control without treatment.

Figure 1

Table 2. Mean values of PCV (%) of Aseel chickens before and after different treatments: group A, ivermectin at 300 μg/kg (2 doses) by subcutaneous route; group B, Nigella sativa oil extract at 200 mg/kg (4 doses) by oral route; group C, ivermectin combined with Nigella sativa oil extract at 300 μg/kg (2 doses) by subcutaneous route and 200 mg/kg dose rate (4 doses) by oral route, respectively; group D, control without treatment.

Figure 2

Table 3. Mean values of Hb concentration (g/dl) of Aseel chickens before and after different treatments: group A, ivermectin at 300 μg/kg (2 doses) by subcutaneous route; group B, Nigella sativa oil extract at 200 mg/kg (4 doses) by oral route; group C, ivermectin combined with Nigella sativa oil extract at 300 μg/kg (2 doses) by subcutaneous route and 200 mg/kg dose rate (4 doses) by oral route, respectively; group D, control without treatment.