Submit or Track your Manuscript LOG-IN

In vitro Acaricidal and Repellent Effects of Amomum subulatum Essential Oil Against Hyalomma Ticks

PUJZ_38_2_211-219

In vitro Acaricidal and Repellent Effects of Amomum subulatum Essential Oil Against Hyalomma Ticks

Arslan Muhammad Ali Khan1, Rao Zahid Abbas1*, Zia ud Din Sindhu1, Muhammad Shahid Mahmood2

1Department of Parasitology, University of Agriculture, Faisalabad, 38040, Pakistan.

2Institute of Microbiology, University of Agriculture, Faisalabad, 38040, Pakistan.

Abstract | The experiments were conducted to assess the acaricidal and repellent activities of Amomum subulatum (A. subulatum) (Black cardamom) essential oil against Hyalomma ticks in bovines. Gas chromatography-flame ionization detection (GC-FID) was performed to identify the chemical components of A. subulatum essential oil. The acaricidal and repellent activities of the A. subulatum essential oil against Hyalomma spp. were observed via adult immersion test (AIT), the larval immersion test (LIT), egg hatchability test (EHT), and the tick repellency assay. GC-FID provided that the main compounds of A. subulatum essential oil were monoterpenoids (limonene and α-terpinene, and α-terpineol) (33.8%) while other chemical compounds were α-terpinolene (9.5%), sabinene (9.3%), 1- Carveol (8.9%), α-phellandrene (7.8%), linalool (4.7%), myrtenol (4.7%), nerolidol (4.6%), β-pinene (4.6%), terphenyl acetate (3.6%), 1, 8-cineole (2.7%), and traces (1.7%). Five different concentrations of A. subulatum essential oil (0.31, 0.62, 1.25, 2.50, and 5% v/v) along with positive (0.1% Cypermethrin) and negative control (absolute alcohol) were prepared to check the acaricidal and repellent effects. A. subulatum essential oil significantly (p<0.05) enhanced the rates of mortality in a dose-dependent manner of adult and larvae of Hyalomma spp. Egg number, egg mass, and larval hatching were also reduced significantly (p<0.05) in a dose-dependent manner. As a result, reproductive index (RI), reproductive efficiency index (REI), and nutrient index (NI) were also decreased significantly (p<0.05) in a dose-dependent manner. Similarly, A. subulatum essential oil showed dose-dependent response against repellency of Hyalomma spp. The LC50 and LC90, RC50 and RC90 values for A. subulatum essential oil were also calculated. Excellent larvicidal, adulticidal, and repellent outcomes of A. subulatum essential oil against Hyalomma ticks were achieved.

Novelty Statement | This is the first time used Amomum subulatum essential oil against Hyalomma ticks and result indicates that A. subulatum essential oil is a potential approach for either eliminating or suppressing Hyalomma ticks’ infestation.


Article History

Received: October 21, 2023

Revised: November 05, 2023

Accepted: November 24, 2023

Published: December, 09, 2023

Authors’ Contributions

AMAK analysed the data and wrote the manuscript. RZA supervised the research, revised and edited the manuscript and aquired funds. ZDS and MSM gave suggestions about writing, reviewing and editing the manuscript.

Keywords

Hyalomma, Ticks, Mortality, Repellency, Essential oils, Amomum subulatum

Copyright 2023 by the authors. Licensee ResearchersLinks Ltd, England, UK. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

Corresponding Author: Rao Zahid Abbas

[email protected]

To cite this article: Khan, A.M.A., Abbas, R.Z., Sindhu, Z.D. and Mahmood, M.S., 2023. In vitro acaricidal and repellent effects of Amomum subulatum essential oil against Hyalomma ticks. Punjab Univ. J. Zool., 38(2): 211-219. https://dx.doi.org/10.17582/journal.pujz/2023.38.2.211.219



Introduction

Ticks are the main reservoirs of tick-borne pathogens of medical and veterinary concern. Tick- and tick-borne diseases prevail all over the world, typically in tropical and sub-tropical areas and affect almost 30% of the total cattle population (Basit et al., 2022). Among devastating parasitic infections of livestock, tick- and tick-borne diseases are ranked after mosquitoes and are considered as the most typical arthropod-borne diseases of livestock, humans, and companion animals (Abdelbaset et al., 2022). These ticks and tick-borne infections have doubled in the last two decades (Sanchez-Vicente et al., 2019). Ticks cause direct and indirect losses to the livestock e.g., they induce fever, anemia, irritation leads to chronic stress, immunodepression, hide damage, poor feeding leading to lethargic condition, weight loss, decreased milk production, and in females increased calving interval (Kasaija et al., 2021). Multiple species of ticks infect humans and animals, but the Hyalomma spp. are among the most common ticks infesting and serving as a vector for zoonotic agents (Rjeibi et al., 2022). Hyalomma spp. are among the most considered species of arachnids to be controlled by the farmers and researchers (Valcárcel et al., 2023).

Various acaricides like synthetic pyrethroids organophosphates, carbamates, and organochlorines are being used to control these ticks but their frequent use is resulting in the development of resistant tick species (Selles et al., 2021). Acaricidal resistance has threatened the welfare of livestock farmers globally because it led to decreased productivity and the emergence of infections (Ahmed et al., 2022; Betelhem et al., 2022; Saeed and Alkheraije, 2023; Sikander et al., 2023). Vaccines for the control of ticks have also been developed and being used commercially, but their efficacy is questionable, moreover they have limited value for the control of ticks (Bonnet et al., 2022). The vaccines in the future, if work successfully, cannot replace the therapeutic control measures. In this scenario, the need for alternatives is at prime for the control of ticks (Semenza et al., 2022).

Multiple alternative strategies are being suggested by the scientists, including metallic nanoparticles, entomophagous fungi, botanical products etc. (Raheel et al., 2021; Srisanyong et al., 2021; Hussain et al., 2022). Botanicals have always been a priority for the researchers to use as control of parasitic diseases (Abbas et al., 2020; Mubashir et al., 2022; Tanda et al., 2022). Multiple forms of botanicals i.e., whole plants, plant parts, extracts and essential oils etc. are in consideration (Sobhy et al., 2021; Bangulzai et al., 2022). The essential oils have the most promising importance among the botanicals because of the active compounds present in them (Radwan et al., 2022; Saeed and Alsayeqh, 2023). The essential oils of various plants have been proven to contain multiple medicinal properties (Ali et al., 2022; Bangulzai et al., 2022; Salman and Imran, 2022). Multiple essential oils have been tested for their acaricidal activities (Shezryna et al., 2020; Chaimanee et al., 2021; El-Sayed et al., 2022).

Amomum subulatum is commonly known as the Indian black cardamom or large cardamom (Saeed et al., 2023). It is commonly found in the sub-continent region, and it is famous for its medicinal and culinary usage (Joshi and Piya, 2019). Essential oil of A. subulatum is a dark liquid having a pungent smell (Kumar et al., 2022). A. subulatum has been found to be antiparasitic and acaricidal in multiple experiments (Al-Hoshani et al., 2023a). This experiment was designed to evaluate the acaricidal activities of essential oil of A. subulatum against Hyalomma spp. because of its medicinal properties of A. subulatum. Researchers also checked its effects against arthropods but not particularly against Hyalomma ticks.

Materials and Methods

Collection of ticks and their identification

Hyalomma anatolicum (H. anatolicum), Hyalomma dromedarii (H. dromedarii), and Hyalomma marginatum (H. marginatum) were collected carefully from various parts of Faisalabad by dragging technique, as described by Falco and Fish (1992). The ticks were kept in perforated plastic bottles with labels to allow for air and moisture exchange. The ticks were then brought to the Chemotherapy Laboratory, Department of Parasitology, University of Agriculture, Faisalabad, Pakistan. An identification guidebook was used for the identification of ticks based on morphological traits (Estrada-Peña et al., 2017).

Chemical composition of essential oils by gas chromatography-fluorescent

Ionization detection (GC-FID)

GC-FID technique was performed for the evaluation of the composition of A. subulatum. This technique was performed at Central Hi-tech Laboratory, University of Agriculture Faisalabad, Pakistan, using a GC-17 SHIMADZU® spectrophotometer. The columns were adjusted at DB WEX 30M 0.25, and nitrogen was used as a mobile phase at the flow rate of 20mL/min. Adjustment of temperature was done at 90°C for 120 sec, then at 180°C for the same time and then at 240°C for 180 sec. The observations were recorded and maintained accordingly. The compositions verified the essential oil’s purity, and the active compounds present in them (Zhao et al., 2021).

Experimental design

In vitro acaricidal activity of A. subulatum essential oils was performed by preparing different dilutions. For this purpose, 0.31, 0.62, 1.25, 2.50, and 5% dilutions of A. subulatum essential oil were prepared with absolute alcohol (volume/volume; v/v), for adult immersion, larval immersion, egg hatch and tick repellency assays. For the adult immersion, larval immersion and egg hatch tests, absolute alcohol was maintained as negative control and 0.1% cypermethrin (Alphakill® by Agrichem Pharmauticlas, China) was used as a positive control. While for the acaricidal assay, N, N-diethyl-meta-toluamide (Pakistan Chemicals®; DEET) was used as positive control for the repellent assay and absolute alcohol remained as negative control. All the groups in all the test were replicated thrice for each test.

Adult immersion test

The Drummond et al. (1973) methodology was adhered to for adult mortality. Ten female ticks were initially weighed and immersed in various A concentration in accordance with this methodology five min with essential oil of subulatum. Ticks were dipped, then put in petri dishes with moist filter sheets and in a biological oxygen demand incubator set to maintain a temperature of 27°C and a humidity of 90% for a full day. Subsequently, the adult mortality was determined by counting both dead and live female ticks. After receiving dilutions, live female ticks were placed in perforated Eppendorf tubes and incubated for 20 days at 90% humidity and 27°C. Tick females deposited their eggs in Eppendorf tubes. To calculate reproductive parameters, egg mass and the residual weight of each individual female tick were recorded. For every concentration, the experiment was run three times, with a positive and a negative control. In this test, the following parameters were noted:

Adult mortality

Adult mortality was performed according to Drummond et al. (1973) guideline sand calculated according to the following formula:

Reproductive Index (RI (%))

RI (%) was calculated Toro-Ortiz et al. (1997) using the following formula:

Nutrient index (NI%)

NI% was calculated using the following formula:

Inhibition of oviposition (IO%)

IO% was calculated by using the following formula:

Where IO and PE represented the inhibition of oviposition and product effectiveness, respectively.

Larval immersion test

The larval immersion test was used to calculate the effectiveness of A. subulatum essential oil on the larvae of Hyalomma spp. modified by Rosado-Aguilar et al. (2010). Tick larvae (7–14 days old) were utilized in this investigation. All the treatments and control groups were added into micro-centrifuge tube and 100 larvae were kept in each tube. After that, each tube was closed tightly and shaked vigorously for 5 sec and then gently for 5 min. Tubes were then opened and all larvae were shifted over filter paper to dry. These filter papers were then placed in an incubator for 24 h at 27°C and 90% relative humidity. Data were collected by counting dead and alive larvae with the help of a stereomicroscope (Rosado-Aguilar et al., 2010).

Egg hatchability test

In glass tubes, 300 Hyalomma eggs were submerged for 5 min in 5mL of A. subulatum essential oil. After decanting the solutions, the tubes were sealed with cotton plugs and incubated for roughly 14 days at 27 to 28°C and a relative humidity of 70 to 80%, until the eggs began to hatch. Ethanol was utilized as negative control and cypermethrin was used as positive control. There were three replications of each treatment. Larval hatchability and inhibition of larval hatchability percentages were recorded (Kaaya et al., 1996).

Where Hc and Ht represented the hatchability in control and treated groups, respectively.

Tick repellency assay

The vertical migratory kind of behavior of adult ticks, which was created and redesigned by Tabari et al. (2020), was utilized to evaluate repellant activity. For this purpose, ten ticks were observed to check the repellency behavior of Hyalomma ticks against A. subulatum essential oil with absolute alcohol as negative control and DEET as a positive control. The whole experiment was conducted at 27°C and 90% relative humidity. After one hour, the number of ticks above and below the filter paper strips were counted for 15 min and the percentage repellency was calculated.

Statistical analysis

Statistical analysis was done through one-way analysis of variance (ANOVA) and Tukey’s test by Minitab software while Probit Analysis by IBM SPSS software by keeping 95% confidence level and considering the results to be non-significant when P>0.05.

Results and Discussion

Chemical composition of A. subulatum

In the essential oil of A. subulatum, 13 chemical compounds were found among which the Limonene was present in greater concentration. The compounds are represented in Table 1; the peeks in the GC-FID assay are given in Figure 1.

 

Table 1: Phytochemical composition of A. subulatum essential oil through gas chromatography-flame ionization detection.

Sr. No

Time of retention

Name of the component

Concentration (%)

1

2.317

Limonene

11.9

2

7.783

α-Terpinene

11.1

3

19.367

α- Terpnineol

10.8

4

5.150

α-Terpinolene

9.5

5

13.050

Sabinene

9.3

6

16.567

1- Carveol

8.9

7

22.567

α-Phellandrene

7.8

8

37.300

Linalool

4.7

9

40.550

Myrtenol

4.7

10

25.700

Nerolidol

4.6

11

32.967

β-Pinene

4.6

12

28.750

Terphenyl acetate

3.6

13

31.133

1, 8-cineole

2.7

14

1.433

Traces/noise

1.7

 

 

Adult tick mortality

An adult immersion test was used to assess A. subulatum’s acaricidal activity against adult Hyalomma ticks at five different concentrations (0.31, 0.62, 1.25, 2.50, and 5%). The outcome showed that 5% of A. subulatum exhibited a significant (p<0.05) acaricidal effects against adult ticks as compared to negative control. Table 2 shows the lethal concentrations, or LC50 and LC90, that have also been found to be 2.80 and 21.11%, respectively. Probit analysis with a regression equation revealed a positive correlation between the concentration of A. subulatum essential oil and adult mortality. This showed that the concentration of essential oils increased together with an increase in adult mortality (Figure 2).

 

Table 2: Effect of various concentrations of A. subulatum essential oil against adults and larval stages.

Treatments

Adult tick mortality

Larval tick mortality

C1

6.66±5.77e

12.33±3.05f

C2

10±0de

21.33±2.08f

C3

23.33±5.77cd

31.33±2.51d

C4

36.66±5.77cd

45.33±3.05c

C5

53.33±5.77b

68.33±4.04b

CP

86.66±5.77a

90±4.58a

CN

6.66±5.77e

3.66±0.57g

 

C1, A. subulatum oil 0.31%; C2, A. subulatum oil 0.625%; C3, A. subulatum oil 1.5%; C4, A. subulatum oil 2.5%; C5, A. subulatum oil 5%; CN, Control Negative; CP, Control Positive. Mean±SD along with the same superscripts have a non-significant difference (p>0.05) from each other.

 

 

Larval tick mortality

The larvicidal effect of A. subulatum essential oil at five different concentrations (0.31, 0.62, 1.25, 2.50, and 5%) was evaluated against the larvae of Hyalomma ticks by using a larval immersion test. Result revealed that 5% concentration of A. subulatum showed a significant (p<0.05) larvicidal effect against larvae of Hyalomma ticks. LC50 and LC90 values were also calculated which were 2.08 and 19.75%, respectively (Table 2). A. subulatum essential oil concentration and larval mortality were found to be positively correlated by probit analysis using a regression equation. This indicated that as essential oil concentration increased, adult mortality also did so, as illustrated in Figure 3.

Effect of various concentrations of A. subulatum essential oil on reproductive parameters and larval hatchability

There is evidence showing that the essential oil extracted from A. subulatum can decrease the Hyalomma tick’s reproductive capabilities. At 5% concentration, A. subulatum essential oil reduced Hyalomma tick oviposition by 64.88%. Additionally, it induced larval hatching at 38% and inhibited larval hatching at 62%. As the concentration of A. subulatum essential oil increased, the effect on oviposition reduction increased, but the egg hatching rate had been dropped from 80 to 38% when p< 0.05. Data revealed that as the concentration of the essential oil grew, the rate of larval hatching dropped, which affected the reproductive index and, thus, the rate of reproduction, as illustrated in Table 3.

 

 

Percentage repellency of Hyalomma ticks

As illustrated in Figure 4, all concentrations of A. subulatum essential oil showed significant (p< 0.05) results against repellency of Hyalomma ticks except 0.31% concentration. The highest activity was observed at 5% concentrations of A. subulatum essential oil. RC50 and RC90 were also calculated by using probit analysis with regression equation which showed 2.68 and 19.49% values.

Product effectiveness

The efficacy of a test substance against ticks was measured through the product effectiveness parameter. Different concentrations of A. subulatum essential oil were used and proved to have different results in relation to effectiveness against Hyalomma species. The 5% concentration showed the best results against Hyalomma ticks, which had non-significant (p>0.05) results from the positive control (0.1% cypermethrin) as shown in Figure 5.

 

Infestation of arthropods, especially arachnids, causes huge economic loss globally (Jabeen et al., 2022; Naseer et al., 2022; Mehnaz et al., 2023). The tick infestations have been controlled by synthetic acaricides over the years, but ticks have developed resistance, which led to the discovery of alternative methods of tick control, especially

 

Table 3: Effect of various concentrations of A. subulatum essential oil on reproductive parameters and larval hatchability.

Treatments

IO (%)

EH/LH (%)

ILH (%)

RI (%)

REI (%)

NI (%)

C1

0.49±8.29d

80.33±2.4a

19.66±2.4d

51.06±4.25a

81.9±4.48a

72.85±0.4a

C2

12.05±10.6d

76.55±1.0a

23.44±1.01d

45.13±5.44a

69.06± 7.96a

69.77±1.9a

C3

38.1±7.66c

57.55±9.82b

42.44±9.82c

31.76±3.93b

36.95±10.49b

61.47±2.6b

C4

47.21±7.4bc

42.11±5.09c

57.88±5.09b

27.09±3.8bc

23.01±5.87bc

57.86±2.9b

C5

64.88±2.57b

38±1.52c

62±1.52b

18.02±1.3c

13.67±0.44cd

47.23±2c

CP

95.41±1.7a

11.33±2.51d

88.66±2.5a

2.35±0.87d

0.55±0.28d

8.82±2.9d

CN

0±0.94d

80±1.52a

20±1.52d

51.31±0.4a

82.09±1.09a

73.02±0a

 

IO, Inhibition of oviposition; EH/LH, Egg hatchability/larval hatchability; ILH, Inhibition of larval hatchability; RI, Reproductive index; REI, Reproductive efficiency index; NI, Nutrient index; C1, A. subulatum oil 0.31%; C2, A. subulatum oil 0.625%; C3, A. subulatum oil 1.5%; C4, A. subulatum oil 2.5%; C5, A. subulatum oil 5%; CN, control negative; CP: control positive. Mean±SD along with the same superscripts have a non-significant difference (p>0.05) from each other.

 

botanical agents, including essential oil (Ibrahium et al., 2022; Akhtar et al., 2023). These essential oils are a volatile mixture of organic compounds that have a mechanism of action and target the ticks in a variety of ways (Faraone et al., 2020; Catani et al., 2022; Özüiçli et al., 2023). A. subulatum essential oil was extracted by hydro-distillation technique and its composition was determined by GC-FID. The major components found in A. subulatum were limonene and α-terpinene. These compositions are like previous studies (Thinh et al., 2021; Bhutia et al., 2022) but variation in the quantity of different components is because of the various factors such as genotype, geographic conditions, harvest time, drying techniques, extraction techniques, and storage conditions (Li et al., 2021; da Silva et al., 2022; Jimayu, 2022). These factors have an impact on the content and composition of the essential oils (Abou Chehade et al., 2022). The other GC-FID detected components along with their quantity in percentage and retention time are listed in Table 1. In the present study, different dilutions of A. subulatum essential oils were prepared in absolute alcohol. The response to adult and larval Hyalomma ticks was dose-dependent (Figure 2 and 3). In the mortality time graph, a significant (P<0.05) difference was observed between higher concentrations (2.5 and 5%) of A. subulatum and the negative control (absolute alcohol) and concluded that higher doses caused greater mortality of adult ticks and larvae. Alruhaili et al. (2023) reported that chemical constituents obtained from A. subulatum were very effective against insects, particularly Tribolium castaneum. In a similar study, Syzygium aromaticum essential oil had shown 100% tick mortality when it was used in 100mg/mL dose (Ferreira et al., 2018). On the other hand, a dose-dependent response was also observed in terms of egg production, egg hatchability, inhibition of larval hatchability, reproductive index, reproductive efficiency, and nutrient index. Nutrient index value was also decreased when the concentration of A. subulatum increased. The acaricidal activity of tested essential oil may be because of the main component’s limonene and α-terpinene which cause the inhibition of acetylcholinesterase enzyme activity in ticks (da Silva Lunguinho et al., 2021) while other compounds such as α- phellandrene, linalool, β-pinene, and 1, 8-cineole have minor inhibitory activity, but they have synergistic action (Wojtunik-Kulesza et al., 2019). The reduction in the egg numbers was because of the female mortality in the first few days after A. subulatum oil treatment. The reduction in oviposition led to a drastic reduction in reproductive index and reproductive efficiency of the Hyalomma ticks when concentrations of essential oil are increased. Essential oils induce cuticular waxes to break and plug the ticks’ respiratory spiracles, which causes water stress and asphyxia (Al-Hoshani et al., 2023b). Additionally, these oils enter the cuticle, diffuse into the haemolymph, and are then transported to internal organs including the ovaries and salivary glands, impairing the digestion and reproductive systems (Jesser et al., 2017).

Like acaricidal activity, a dose-dependent response of A. subulatum against the repellency of Hyalomma ticks was observed for 5 different concentrations. 5% concentration of A. subulatum produced effective response against Hyalomma ticks and showed significant (p<0.05) difference from the DEET treatment as shown in Figure 4. RC50 and RC90 were also calculated by using probit analysis with regression equation which showed 2.68 and 19.49% values. The repellency of A. subulatum is due to the active component limonene and other active components present in essential oil. Terpinene and limonene in the essential oils have proven repellent efficacy against Ixodes ticks (da Silva Lunguinho et al., 2021; Oladipupo, 2022) and these were major components of essential oil of A. subulatum in this study (Table 1). These volatile substances create vapor barriers, driving arthropods away from the essential oil and giving them repelling properties (Salman et al., 2020).

Conclusions and Recommendations

The result of this study indicates that A. subulatum essential oil is a possible approach option for either eliminating or suppressing Hyalomma tick infestation. Further investigation is required to confirm these findings before recommending for commercial application. Moreover, methods to improve the longevity of essential oils as well as processes for improving oil yield following extraction needs to be improved.

Consent for publication

All authors are fine with the current version of the manuscript and give their consent for publication.

Ethical approval

Not applicable.

Conflict of interest

The authors have declared no conflict of interest.

References

Abbas, R.Z., Zaman, M.A., Sindhu, D., Sharif, M., Rafique, A., Saeed, Z., Siddique, F., Zaheer, T., Khan, M.K. and Akram, M.S., 2020. Anthelmintic effects and toxicity analysis of herbal dewormer against the infection of Haemonchus contortus and Fasciola hepatica in goat. Pak. Vet. J., 40: 455-460. https://doi.org/10.29261/pakvetj/2020.083

Abdelbaset, A.E., Nonaka, N. and Nakao, R., 2022. Tick-borne diseases in Egypt: A one health perspective. One Hlth., pp. 100443. https://doi.org/10.1016/j.onehlt.2022.100443

Abou Chehade, L., Angelini, L.G. and Tavarini, S., 2022. Genotype and seasonal variation affect yield and oil quality of safflower (Carthamus tinctorius L.) under Mediterranean conditions. Agronomy, 12: 122. https://doi.org/10.3390/agronomy12010122

Ahmed, M., Riad, E., Diab, O., Mansour, H. and El-Mossalami M., 2022. Antibiotic residues in locally marketed fresh and frozen livers in Cairo and Giza, Egypt. Int. J. Vet. Sci., 11: 37-42. https://doi.org/10.47278/journal.ijvs/2021.073

Akhtar, T., Shahid, S., Asghar, A., Naeem, M., Aziz, S. and Ameer, T., 2023. Utilisation of herbal bullets against Newcastle disease in poultry sector of Asia and Africa (2012-2022). Int. J. Agric. Biosci., 12: 56-65. https://doi.org/10.47278/journal.ijab/2023.044

Al-Hoshani, N., Al Syaad, K.M., Saeed, Z., Kanchev, K., Khan, J.A. and Asif, M., 2023a. Anticoccidial activity of star anise (Illicium verum) essential oil in broiler chicks. Pak. Vet. J., 43: 553-558.

Al-Hoshani, N., Zaman, M.A., Al Syaad, K.M., Salman, M., Rehman, T. and Olmeda, A.S., 2023b. Assessment of repellency and acaricidal potential of Nigella sativa essential oil using Rhipicephalus microplus ticks. Pak. Vet. J., , 43(3): 606-610. http://dx.doi.org/10.29261/pakvetj/2023.054

Ali, A., Bahmani, M., Pirhadi, M., Kaviar, V., Karimi, E. and Abbasi, N., 2022. Phytochemical analysis and antimicrobial effect of essential oil and extract of Loranthus europaeus Jacq on Acinetobacter baumannii, Staphylococcus aureus, and Pseudomonas aeruginosaKafkas Univ. Vet. Fak. Derg., 28: 161-167.

Alruhaili, M.H., Almuhayawi, M.S., Gattan, H.S., Alharbi, M.T., Nagshabandi, M.K., Jaouni, S.K.A., Selim, S. and AbdElgawad, H., 2023. Insight into the phytochemical profile and antimicrobial activities of Amomum subulatum and Amomum xanthioides: An in vitro and in silico study. Front. Pl. Sci., 14: 1136961. https://doi.org/10.3389/fpls.2023.1136961

Bangulzai, N., Ahmed, S.F., Kashif, M., Fatima, M., Ahmed, M. and Mushtaq, N., 2022. Antifungal activity of essential oils extracted from different plants against Penicillium digitatum causing green mold of Citru. Int. J. Agric. Biosci. 11: 75-83. https://doi.org/10.47278/journal.ijab/2022.011

Basit, M.A., Ijaz, M., Abbas, R.Z., Khan, J.A. and Ashraf, K., 2022. First molecular evidence of Ehrlichia infection: An emerging pathogen of small ruminants in Pakistan. Pak. Vet. J., 42: 208-214.

Betelhem, T., Shubisa, A. and Bari, F., 2022. Isolation, identification and antimicrobial resistance of Staphylococcus aureus isolates from mastitis cases of lactating dairy cows found in Sululta and Holleta Towns, Oromia, Ethiopia. Agrobiol. Rec., 8: 27-34. https://doi.org/10.47278/journal.abr/2022.006

Bhutia, S.G., Upadhyay, S., Pradhan, A. and Sharma, L., 2022. Composition of essential oils from four major cultivars of large cardamom (Amomum subulatum Roxb.) grown in Sikkim. J. appl. Hortic., 24: 121-124. https://doi.org/10.37855/jah.2022.v24i01.23

Bonnet, S.I., Vourc’h, G., Raffetin, A., Falchi, A., Figoni, J., Fite, J., Hoch, T., Moutailler, S. and Quillery, E., 2022. The control of Hyalomma ticks, vectors of the Crimean–Congo hemorrhagic fever virus: Where are we now and where are we going? PLoS Negl. Trop. Dis., 16: e0010846. https://doi.org/10.1371/journal.pntd.0010846

Catani, L., Grassi, E., di Montanara, A.C., Guidi, L., Sandulli, R., Manachini, B. and Semprucci, F., 2022. Essential oils and their applications in agriculture and agricultural products: A literature analysis through VOSviewer. Biocatal. Agric. Biotechnol., pp. 102502. https://doi.org/10.1016/j.bcab.2022.102502

Chaimanee, V., Warrit, N., Boonmee, T. and Pettis, J.S., 2021. Acaricidal activity of essential oils for the control of honeybee (Apis mellifera) mites Tropilaelaps mercedesae under laboratory and colony conditions. Apidologie, 52: 561-575. https://doi.org/10.1007/s13592-021-00843-z

da Silva, L.A., das, G., Cardoso, M., Ferreira, V.R.F., Konig, I.F.M., Gonçalves, R.R.P., Brandão, R.M., Caetano, A.R.S., Nelson, D.L. and Remedio, R.N., 2021. Acaricidal and repellent activity of the essential oils of Backhousia citriodora, Callistemon viminalis and Cinnamodendron dinisii against Rhipicephalus spp. Vet. Parasitol., 300: 109594. https://doi.org/10.1016/j.vetpar.2021.109594

da Silva, W.M.F., Kringel, D.H., de Souza, E.J.D., da Rosa Zavareze, E. and Dias, A.R.G., 2022. Basil essential oil: Methods of extraction, chemical composition, biological activities, and food applications. Fd. Bioprocess. Technol., 15: 1-27. https://doi.org/10.1007/s11947-021-02690-3

Drummond, R.O., Ernst, S.E., Trevino, J.L., Gladney, W.J. and Graham, O.H., 1973. Boophilus annulatus and B. microplus: laboratory tests of insecticides. J. Econ. Entomol., 66: 130-133. https://doi.org/10.1093/jee/66.1.130

El-Sayed, S.M., Ahmed, N., Selim, S., Al-Khalaf, A.A., El Nahhas, N., Abdel-Hafez, S.H., Sayed, S., Emam, H.M. and Ibrahim, M.A.R., 2022. Acaricidal and antioxidant activities of anise oil (Pimpinella anisum) and the oil’s effect on protease and acetylcholinesterase in the two-spotted spider mite (Tetranychus urticae Koch). Agriculture, 12: 224. https://doi.org/10.3390/agriculture12020224

Estrada-Peña, A., Pfäffle, M.P. and Petney, T.N., 2017. Genus Hyalomma Koch, 1844. Ticks of Europe and North Africa: A guide to species identification. pp. 343-348. https://doi.org/10.1007/978-3-319-63760-0_65

Falco, R.C. and Fish, D., 1992. A comparison of methods for sampling the deer tick, Ixodes dammini, in a Lyme disease endemic area. Exp. Appl. Acarol., 14: 165-173. https://doi.org/10.1007/BF01219108

Faraone, N., Light, M., Scott, C., MacPherson, S. and Hillier, N.K., 2020. Chemosensory and behavioural responses of Ixodes scapularis to natural products: Role of chemosensory organs in volatile detection. Insects, 11: 502. https://doi.org/10.3390/insects11080502

Ferreira, F.M., Delmonte, C.C., Novato, T.L.P., Monteiro, C.M.O., Daemon, E., Vilela, F.M.P., and Amaral, M.P.H., 2018. Acaricidal activity of essential oil of Syzygium aromaticum, hydrolate and eugenol formulated or free on larvae and engorged females of Rhipicephalus microplus. Med. Vet. Entomol.32: 41-47. https://doi.org/10.1111/mve.12259

Hussain, K., Alsayeqh, A.F., Abbas, A., Abbas, R.Z., Rehman, A., Waqar, Z.A.I.B. and Mahmood, M.S., 2022. Potential of Glycyrrhiza glabra (Licorice) extract an alternative biochemical and therapeutic agent against coccidiosis in broiler chickens. Kafkas Univ. Vet. Fak. Derg., 28: 585-591.

Ibrahium, S.M., Aboelhadid, S.M., Wahba, A.A., Farghali, A.A., Miller, R.J., Abdel-Baki, A.A.S. and Al-Quraishy, S., 2022. Preparation of geranium oil formulations effective for control of phenotypic resistant cattle tick Rhipicephalus annulatus. Sci. Rep., 12: 11693. https://doi.org/10.1038/s41598-022-14661-5

Jabeen, F., Mushtaq, M., Qayyum, M., Ul Hasan, M., Zafar, M.A., Riaz, A. and Nasir, F., 2022. Tick taxonomy and nucleotide sequence analysis by internal transcribed spacer 2 (ITS 2) in large ruminants of Pothohar, Pakistan. Pak.Vet. J., 42: 554-560.

Jesser, E.N., Werdin-González, J.O., Murray, A.P. and Ferrero, A.A., 2017. Efficacy of essential oils to control the Indian meal moth, Plodia interpunctella (Hübner)(Lepidoptera: Pyralidae). J. Asia PacEntomol., 20: 1122-1129. https://doi.org/10.1016/j.aspen.2017.08.004

Jimayu, G., 2022. Essential oil yield and yield related of basil (Ocimum basilicum L) as affected by NPS and nitrogen fertilizer rates at Wondo Genet, Southern Ethiopia. Int. J. Agri. Biosc. 11: 34-41. https://doi.org/10.47278/journal.ijab/2022.005

Joshi, N.P. and Piya, L., 2019. Large cardamom (Amomum subulatum Roxb.) production, marketing and trade in the Indian sub-continent. J. Contemp. India Stud. Spac. Soc., 9: 1-13.

Kaaya, G.P., Mwangi, E.N. and Ouna, E.A., 1996. Prospects for biological control of livestock ticks, Rhipicephalus appendiculatus and Amblyomma variegatum, Using the Entomogenous Fungi Beauveria bassiana and Metarhizium Anisopliae. J. Invertebr. Pathol., 67: 15-20. https://doi.org/10.1006/jipa.1996.0003

Kasaija, P.D., Estrada-Peña, A., Contreras, M., Kirunda, H. and de la Fuente, J., 2021. Cattle ticks and tick-borne diseases: a review of Uganda’s situation. Ticks Tick Borne Dis., 12: 101756. https://doi.org/10.1016/j.ttbdis.2021.101756

Kumar, S.P., Gautam, G.K., Kumar, R. and Kumar, G., 2022. A review on Amomum subulatum and Elettaria Cardamomum with their pharmacological activity. Mat. J., 4: 1-6.

Li, W., Yu, Y., Wang, L., Luo, Y., Peng, Y., Xu, Y., Liu, X., Wu, S., Jian, L. and Xu, J., 2021. The genetic architecture of the dynamic changes in grain moisture in maize. Pl. Biotechnol. J., 19: 1195-1205. https://doi.org/10.1111/pbi.13541

Mehnaz, S., Abbas, R., Kanchev, K., Rafique, M., Aslam, M., Bilal, M., Ather, A., Zahid, A. and Batool, T., 2023. Natural control perspectives of Dermanyssus gallinae in poultry. Int. J. Agric. Biosci., 12: 136-142. https://doi.org/10.47278/journal.ijab/2023.056

Mubashir, A., Ghani, A. and Mubashar, A., 2022. Common medicinal plants effective in peptic ulcer treatment: A nutritional review. Int. J. Agric. Biosci., 11: 70-74. https://doi.org/10.47278/journal.ijab/2022.010

Naseer, M.U., Iqbal, Z. and Aslam, B., 2022. In vitro efficacy of Areca catechu against cypermethrin resistant Rhipicephalus microplus and its phytochemical analysis. Pak. Vet. J., 42: 414-418.

Oladipupo, S.O., 2022. Toxicity and physiological effects of essential oil components against the German Cockroach, Blattella germanica (L.) (Ectobiidae). Auburn University.

Özüiçli, M., Girişgin, A., Diker, A., Baykalir, Y., Kisadere, İ. and Aydin, L., 2023. The efficacy of thyme, peppermint, eucalyptus essential oils, and nanoparticle ozone on nosemosis in honey bees. Kafkas Univ. Vet. Fak. Derg., 29. https://doi.org/10.9775/kvfd.2023.29167

Radwan, I., Abdel-Hafeez, M.M.M., Hassan, S., Abdel-Wahab, A.A. and Abed. A.H., 2022. Effect of essential oils on biological criteria of gram-negative bacterial pathogens isolated from diseased broiler chickens. Int. J. Vet. Sci., 11: 59-67. https://doi.org/10.47278/journal.ijvs/2021.078

Raheel, I., Orabi, A. and Tag, N., 2021. Down regulation of biofilm and quorum sensing genes of Pseudomonas aeruginosa and Pasteurella multocida isolated from broiler chicken pericarditis lesions by the action of some essential oils. Int. J. Vet. Sci., 10: 301-306. https://doi.org/10.47278/journal.ijvs/2021.058

Rjeibi, M.R., Amairia, S., Mhadhbi, M., Rekik, M. and Gharbi, M., 2022. Detection and molecular identification of Anaplasma phagocytophilum and Babesia spp. infections in Hyalomma aegyptium ticks in Tunisia. Arch. Microbiol., 204: 385. https://doi.org/10.1007/s00203-022-02995-7

Rosado-Aguilar, J.A., Aguilar-Caballero, A., Rodriguez-Vivas, R.I., Borges-Argaez, R., Garcia-Vazquez, Z. and Mendez-Gonzalez, M., 2010. Acaricidal activity of extracts from Petiveria alliacea (Phytolaccaceae) against the cattle tick, Rhipicephalus (Boophilus) microplus (Acari: ixodidae). Vet. Parasitol., 168: 299-303. https://doi.org/10.1016/j.vetpar.2009.11.022

Saeed, Z., Abbas, R.Z., Khan, M.K. and Saleemi, M.K., 2023. Anticoccidial activities of essential oil of Amomum subulatum in broiler chicks. Pak. J. Agric. Sci., 60.

Saeed, Z. and Alkheraije, K.A., 2023. Botanicals: A promising approach for controlling cecal coccidiosis in poultry. Front. Vet. Sci., 10: 1157633. https://doi.org/10.3389/fvets.2023.1157633

Saeed, Z. and Alsayeqh, A., 2023. Evaluation of anthelmintic, hematological and serum biochemical effects of herbal dewormer on the cattle. Slov. Vet. Res., 60. https://doi.org/10.26873/SVR-1624-2022

Salman, M., Abbas, R.Z., Israr, M., Abbas, A., Mehmood, K., Khan, M.K., Hussain, R., Saleemi, M.K. and Shah, S., 2020. Repellent and acaricidal activity of essential oils and their components against Rhipicephalus ticks in cattle. Vet. Parasitol., 283: 109178. https://doi.org/10.1016/j.vetpar.2020.109178

Salman, M., and Imran, A., 2022. In vitro anticoccidial evaluation of Citrus sinensis essential oil against Eimeria oocysts. Agrobiol. Rec., 10: 15-18. https://doi.org/10.47278/journal.abr/2022.020

Sanchez-Vicente, S., Tagliafierro, T., Coleman, J.L., Benach, J.L. and Tokarz, R., 2019. Polymicrobial nature of tick-borne diseases. Clin. Sci. Epidemiol., 10: 10-1128. https://doi.org/10.1128/mBio.02055-19

Selles, S.M.A., Kouidri, M., González, M.G., González, J., Sánchez, M., González-Coloma, A., Sanchis, J., Elhachimi, L., Olmeda, A.S. and Tercero, J.M., 2021. Acaricidal and repellent effects of essential oils against ticks: A review. Pathogens, 10: 1379. https://doi.org/10.3390/pathogens10111379

Semenza, J.C., Rocklöv, J. and Ebi, K.L., 2022. Climate change and cascading risks from infectious disease. Infect. Dis. Ther., 11: 1371-1390. https://doi.org/10.1007/s40121-022-00647-3

Shezryna, S., Anisah, N., Saleh, I. and Syamsa, R.A., 2020. Acaricidal activity of the essential oils from Citrus hystrix (Rutaceae) and Cymbopogon citratus (Poaceae) on the cattle tick Rhipicephalus (Boophilus) microplus larvae (Acari: Ixodidae). Trop. Biomed., 37: 433-442.

Sikander, M., Ashraf, M. and Muhammad, K.M.T.S., 2023. Antimicrobial resistance and virulence determinants of E. coli in bovine clinical mastitis in dairy farms. Cont. J. Vet. Sci., 3: 54-59.

Sobhy, H., AboElnaga, T.R., Behour, T.S. and Razin, E.A., 2021. In vitro trypanocidal activity of essential oils of some plants against Trypanosoma evansi. Int. J. Vet. Sci., 10: 191-195. https://doi.org/10.47278/journal.ijvs/2021.043

Srisanyong, W., Bunyaluk, D., Srinontong, P. and Chitsanoor, S., 2021. Acaricidal activity of phenolic crude extract from Artocapus lakoocha leaves against cattle tick Rhipicephalus (Boophilus) microplus. Int. J. Vet. Sci., 10: 307-311. https://doi.org/10.47278/journal.ijvs/2021.063

Tabari, M.A., Rostami, A., Khodashenas, A., Maggi, F., Petrelli, R., Giordani, C., Tapondjou, L.A., Papa, F., Zuo, Y. and Cianfaglione, K., 2020. Acaricidal activity, mode of action, and persistent efficacy of selected essential oils on the poultry red mite (Dermanyssus gallinae). Fd. Chem. Toxicol., 138: 111207. https://doi.org/10.1016/j.fct.2020.111207

Tanda, A.S., Kumar, M., Tamta, A.K. and Deeksha, M.G., 2022. Advances in integrated management technology of insect pests of stored grain, advances in integrated pest management technology. Springer, pp. 157-196.

Thinh, B.B., Doudkin, R.V. and Thanh, V.Q., 2021. Chemical composition of essential oil of Amomum xanthioides Wall. ex Baker from Northern Vietnam. Biointerface Res. Appl. Chem., 11: 12275-12284. https://doi.org/10.33263/BRIAC114.1227512284

Toro-Ortiz, R.D., Junior, I.d.S.V., Gonzales, J.C. and Masuda, A., 1997. Monoclonal antibodies against Boophilus microplus and their effects on tick reproductive efficiency. Vet. Parasitol., 69: 297-306. https://doi.org/10.1016/S0304-4017(96)01107-7

Valcárcel, F., Elhachimi, L., Vilá, M., Tomassone, L., Sánchez, M., Selles, S.M.A., Kouidri, M., González, M.G., Martín-Hernández, R. and Valcárcel, Á., 2023. Emerging Hyalomma lusitanicum: From identification to vectorial role and integrated control. Med. Vet. Entomol., https://doi.org/10.1111/mve.12660

Wojtunik-Kulesza, K.A., Kasprzak, K., Oniszczuk, T. and Oniszczuk, A., 2019. Natural monoterpenes: Much more than only a scent. Chem. Biodiv., 16: e1900434. https://doi.org/10.1002/cbdv.201900434

Zhao, Y., Yang, Y.H., Ye, M., Wang, K. B., Fan, L.M. and Su, F.W., 2021. Chemical composition and antifungal activity of essential oil from Origanum vulgare against Botrytis cinerea. Fd. Chem., 365: 130506. https://doi.org/10.1016/j.foodchem.2021.130506

To share on other social networks, click on any share button. What are these?

Punjab University Journal of Zoology

June

Vol.39, Iss. 1, Pages 01-134

Featuring

Click here for more

Subscribe Today

Receive free updates on new articles, opportunities and benefits


Subscribe Unsubscribe