نوع مقاله : مقاله کامل، انگلیسی
نویسندگان
1 مرکز پرورش حشرات و کارآفرینی حشرهشناسی (CIFEE)، گروه مهندسی کشاورزی، دانشگاه مهندسی و فناوری اطلاعات خواجه فرید، رحیم یار خان، پنجاب، پاکستان
2 گروه حشرهشناسی، دانشکده کشاورزی، دانشگاه تربیت مدرس، تهران، ایران
3 گروه حشرهشناسی، دانشگاه کشاورزی مناطق خشک پیر مهر علی شاه، راولپندی، پاکستان
چکیده
چکیده تصویری
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کلیدواژهها
موضوعات
Introduction
The date palm (Phoenix dactylifera L.) is a highly valued fruit mentioned in many holy texts. It is one of the oldest cultivated plants, farmed since 4000 B.C (Al-Mahmoud et al., 2020). Dates are valuable crops that are widely consumed in several nations, particularly throughout the Arab world, either fresh or dried from the date palm. Remarkably, with a total production of 557,279 tons, Pakistan is the sixth largest producer of dates worldwide, behind the Arab world (Abul-Soad et al., 2010; Al-Karmadi & Okoh, 2024). Dates are grown on 114,000 hectares in Pakistan, with an annual production of 557,279 tons (Mallah et al., 2016). Dates include a wealth of vital nutrients, containing fructose, glucose, essential minerals, dietary fiber, fatty acids, vitamins, and proteins (Chandrasekaran & Bahkali, 2013; Muñoz-Bas et al., 2024). Dates are essential emergency nourishment because of their antibacterial, immunomodulatory, antifungal, anticancer, and antioxidant qualities, while date seeds serve as animal feed due to their high protein, fat, and fiber content. The widespread significance of date seeds stems from their industrial, nutritional, medicinal, social, and cultural values, making them highly popular (El Youssfi et al., 2024). Pakistan boasts over 300 distinct varieties of date palms under cultivation. Among these, the Aseel variety stands out as the queen of all date varieties grown in the country, holding a prominent status as a commercial choice. Renowned for its excellence, Aseel variety demonstrates exceptional qualities in both semi-dry and dry variations (Ahmed et al., 2016; Awan et al., 2018). Among major date producing nations, date palm holds a position of greater importance compared to other crops. Unfortunately, the date palm is susceptible to severe impacts from insect pests and diseases. Such pest infestations contribute to the decline syndrome, leading to a substantial loss of dates, particularly in semi-dry circumstances (Khan et al., 2023; Markhand et al., 2010). The beetles species Carpophilus hemipterus and Oryzaephilus surinamensis are widely distributed and pose a significant threat to agricultural products, both pre and post-harvest. In combination with other diseases and pests, these beetles contribute to a 30% reduction in the overall production of date fruits (Hashem et al., 2012; Swamy & Bitra, 2023).
Saw-toothed grain beetle, O. surinamensis L (Coleoptera: Silvanidae), primarily attributed to semi-dry and fresh dry date palm fruits that have been stored, encounters a significant issue of insect infestation. This infestation not only diminishes the quality and quantity of dates but also results in weight loss (Kousar et al., 2021). The geographical distribution of this insect spans various world’s regions (Kousar et al., 2023). This beetle thrives in stored dates and other dry commodities, including wheat, rice, flour, nuts, and packaged foods, due to its small size, flat body, and rapid mobility (Hassan et al., 2020).
Chemical compounds are essential substances formed by the combination of elements, playing pivotal roles in everyday products from household cleaners and pharmaceuticals to industrial materials and agricultural enhancements (Anadón et al., 2025). Their diverse properties enable innovations that improve health, sustainability, and technological progress. Current control strategies rely on chemical fumigants (methyl bromide, phosphine) and synthetic insecticides (pyrethroids, organophosphates). However, O. surinamensis has developed widespread resistance, and its ability to hide in storage crevices complicates eradication (Rajendran, 2020). Furthermore, chemical residues pose risks to human health and trade, particularly for export-grade dates (Gourgouta et al., 2023; Sangeeta et al., 2024). Given these challenges, there is an urgent need for safer, biodegradable alternatives that are effective yet non-toxic to non-target organisms. Plant derived pesticides such as essential oils and botanical powders offer a sustainable solution, as they are rich in bioactive compounds, target specific, and compatible with Integrated Pest Management (IPM) (Latifian et al., 2020). This study evaluates the efficacy of plant based oils and powders against O. surinamensis in stored dates, aiming to identify viable, eco-friendly control methods.
Materials and methods
Culture Collection and rearing of O. surinamensis
Oryzaephilus surinamensis were collected from infested stored dates from markets and storage facilities in Rahim Yar Khan District, Pakistan. The beetles were reared on date fruits in plastic boxes (34 x 20 cm) under controlled conditions, 27–30°C and 60±70% relative humidity at the Center for Insect Farming and Entomological Entrepreneurship (CIFEE), Department of Agricultural Engineering, Khwaja Fareed University of Engineering and Information Technology.
Plant Essential Oils: Toxicity Bioassay
Oil sources
Six commercially available plant oils were tested: Turpentine oil (Turpentine sp.), Wheat seed oil (Trititum aestivum), Radish seed oil (Raphanus sativus), Eucalyptus oil (Eucalyptus globulus), Black seed oil (Nigella sativa), and Rosemary oil (Rosmarinus officinalis).
Fumigation Bioassay
The space fumigation method (Shaaya et al., 1991) was employed. Filter paper strips measuring 4 x 5 cm were soaked in oil concentrations of 6, 12, 18, and 24 µl per liter, using ethanol as the solvent. The treated strips were then attached to the lids of glass vials (10 x 4 cm) that contained 40 adult beetles (1-8 days) and one dry date fruit as a food source. Vials were sealed and stored at lab conditions (27–30°C, 60–70% RH). Mortality was recorded after 24, 48, and 72 h of exposure. Four replicates were conducted per treatment. The same experimental setup was used to maintain the control sample.
Plant Powders: Preparation and Bioassay
Powders Preparation
Fresh leaves of five medicinal plants were used as fine powder based on the method described by Shah et al. (2008): Neem (Azadirachta indica), Eucalyptus (Eucalyptus sp.), Tamarind (Tamarindus indica), Lemon grass (Cymbopogon citratus), and Moringa (Moringa oleifera). Dried leaves were ground using a grinder machine and stored in plastic bags.
Contact Toxicity Bioassay
In this experiment, small glass vials were utilized and positioned within single date fruit for feeding purposes of O. surinamensis. Different plant powders mentioned in the earlier paragraph were incorporated into the vials in specified weight units of 0.7, 0.8, and 0.9 grams. The powder was vibrated thoroughly to ensure proper integration. Thirty adult beetles (1-8 days) were introduced per vial. The control treatment involved no addition of powder. All vials were securely covered with a lid and then kept under suitable lab conditions (27–30°C, 60–70% RH). Mortality of O. surinamensis was determined after exposure periods of 24, 48, and 72 hours. Three replications were performed per treatment, and the same experimental setup was conducted for the untreated control.
Statistical Analysis
Essential oil toxicity: Mortality data were corrected using Abbott’s formula (1925) and analyzed via probit analysis (Polo Plus 2.0) to determine LC₅₀ and LC₉₀ values.
Corrected Mortality (%) =((P-P0)/(100-P0))×100
Where: P = mortality in treatment
Po = mortality in control
Plant powder efficacy: Mortality rates were examined using One-way ANOVA, and means were compared using LSD post hoc tests (SPSS version 21, 2024).
Results
Toxicity of plant essential oils against O. surinamensis
Among the tested plant oils, Turpentine oil exhibited the highest toxicity, followed by rosemary, black seed, radish, eucalyptus, and wheat seed oil (Table 1). Turpentine oil showed LC50 values, indicating the highest toxicity, 32.720 ppm (72 h), 28.236 ppm (48 h), and 24.020 ppm (24 h). Moreover, Turpentine oil's LC90 values at these intervals were 117.355, 97.852, and 60.706 ppm. Rosemary oil was the second most effective, with LC50 values of 19.643 ppm (24 h), 27.598 ppm (48 h), and 27.251 ppm (72 h). Wheat seed oil exhibited the quickest knockdown effect at 24 hours (LC50 = 14.626 ppm); however, its residual efficacy was lower than that of Turpentine and rosemary oils over extended exposures.
Mortality increased with exposure time and concentration for all oils. Complete dose mortality responses (LC50, LC90) are detailed in Table 1.
Effect of plant powders on O. surinamensis
All tested plant powders exhibited significant mortality within the 24, 48, and 72-hour intervals, compared to the control (untreated group), with effects increasing over time (Fig. 1). Most impactful powder was neem powder, with highest percentage of adult mortality recorded at weight units (0.9, 0.8, 0.7) respectively at 72 hours, mortality rate of insects in neem powder was notably high (df = 17; F = 299.168; P <0.001) (Fig 1-C) followed by Lemon grass, Tamarind and Eucalyptus powder in 48 hours (df = 17; F = 185.286; P <0.001) (Fig 1-B). Conversely, in 24 hours, the insect mortality rate in Moringa powder was lower (df = 17; F = 167.893; P <0.001) (Fig. 1-A).
Discussion
Pest infestations pose a growing threat to global food security, with O. surinamensis emerging as a major pest of stored date fruits, causing significant economic losses and compromising food safety (Kavallieratos et al., 2022). Conventional pest control relies heavily on synthetic pesticides, which raise concerns about human health risks and environmental degradation. Botanical alternatives, such as plant derived oils and powders, offer promising eco-friendly solutions for managing stored product pests (Kim et al., 2019). This study not only confirms the efficacy of plant based oils and powders but also provides novel insights into their comparative performance, mechanisms of action, and potential for integration into sustainable pest management strategies. Unlike previous research, our findings specifically address O. surinamensis in stored dates, a critical but understudied area. Essential oils disrupt pest physiology through fumigant and contact toxicity, Turpentine oil exhibited the highest toxicity against O. surinamensis, with LC50 values declining over time, indicating cumulative effects.
|
Table 1: Toxicity of plant essential oils against O. surinamensis at 24, 48, and 72 h exposure intervals. |
|||||||
|
E.I. |
Plant oils |
LC50a (ppm) (95% FLb) |
LC90c (ppm) (95% FLb) |
Df |
X2d |
P |
Ne |
|
72 Hours |
Turpentine |
32.720 (20.698-51.726) |
117.355 (74.552-186.311) |
2 |
0.025 |
0.703 |
40 |
|
Rosemary |
27.251 (18.306-40.568) |
81.128 (54.498-120.772) |
2 |
0.018 |
0.686 |
40 |
|
|
Black seed |
25.552 (17.490-37.331) |
76.984 (52.694-112.472) |
2 |
0.036 |
0.780 |
40 |
|
|
Radish seed |
23.183 (16.331-32.908) |
64.783 (45.637-91.961) |
2 |
0.036 |
0.797 |
40 |
|
|
Eucalyptus |
20.834 (15.155-28.641) |
53.108 (38.632-73.010) |
2 |
0.040 |
0.818 |
40 |
|
|
Wheat seed |
18.043 (13.516-24.087) |
43.047 (32.246-57.466) |
2 |
0.024 |
0.813 |
40 |
|
|
48 Hours |
Turpentine |
28.236 (18.563-42.950) |
97.852 (64.329-148.844) |
2 |
0.011 |
0.701 |
40 |
|
Rosemary |
27.598 (17.300-44.026) |
106.129 (66.528-169.304) |
2 |
0.019 |
0.593 |
40 |
|
|
Black seed |
24.799 (15.954-38.548) |
93.793 (60.339-145.795) |
2 |
0.011 |
0.695 |
40 |
|
|
Radish seed |
19.320 (13.576-27.495) |
56.612 (39.781-18.565) |
2 |
0.025 |
0.711 |
40 |
|
|
Eucalyptus |
17.770 (12.2914-24.452) |
46.606 (33.871-64.130) |
2 |
0.049 |
0.760 |
40 |
|
|
Wheat seed |
15.548 (11.575-20.884) |
38.343 (28.545-51.505) |
2 |
0.025 |
0.733 |
40 |
|
|
24 Hours |
Turpentine |
24.020 (17.075-33.791) |
60.706 (43.153-85.399) |
2 |
0.046 |
0.728 |
40 |
|
Rosemary |
19.643 (14.685-26.275) |
44.799 (33.492-59.925) |
2 |
0.011 |
0.693 |
40 |
|
|
Black seed |
18.275 (13.338-25.038) |
46.582 (33.999-63.821) |
2 |
0.039 |
0.708 |
40 |
|
|
Radish seed |
16.464 (12.949-20.933) |
32.906 (25.881-41.839) |
2 |
0.041 |
0.774 |
40 |
|
|
Eucalyptus |
15.335 (12.334-19.065) |
28.812 (23.174-35.821) |
2 |
0.044 |
0.738 |
40 |
|
|
Wheat seed |
14.626 (11.749-18.207) |
27.565 (22.143-34.315) |
2 |
0.015 |
0.716 |
40 |
|
|
E.I. = Exposure Intervals; a LC50 = Kill 50% insect population; b FL = Fiducial limit; cLC90 = Kill 90% insect population; d = Chi-square; e = Total number of exposed adults |
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Fig. 1: Effect of medicinal plant powders on O. surinamensis after 24 (A), 48 (B), and 72 (C) hours. The mean ± SE of adult mortality was observed in 2024. Different alphabetic letters indicate significant differences in adult mortality across various times and powder toxicities (p < 0.00, Tukey test).
This cumulative toxicity is a novel observation for O. surinamensis and suggests that prolonged exposure to turpentine oil could enhance its practical efficacy in storage facilities (Lomtadze et al., 2018). These findings align with research demonstrating the fumigant potency of essential oils against other stored product pests like Tribolium castaneum and Tenebrio molitor (Kavallieratos et al., 2024). Rosemary and black seed oils also showed significant insecticidal activity, with LC50 values of 27.251 ppm and 25.552 ppm at 72 h, respectively. While these oils have been studied for their efficacy against coleopteran pests such as Sitophilus oryzae and Lasioderma serricorne (Kim et al., 2003), our work is the first to document their potency against O. surinamensis, highlighting their broad spectrum potential.
Among plant powders, neem (Azadirachta indica) demonstrated the highest mortality rates, attributed to its active compound, azadirachtin. This result is consistent with existing literature, but our study further reveals that eucalyptus, tamarind, lemongrass, and moringa powders also exhibit dose and time dependent toxicity, with mortality increasing significantly after 48–72 h of exposure. This delayed but substantial effect is particularly notable for moringa and eucalyptus, which have not been previously evaluated for their long term impact on O. surinamensis. Eucalyptus, tamarind, lemongrass, and moringa powders also exhibited dose and time dependent toxicity, with mortality increasing significantly after 48–72 h of exposure. Field studies support these findings; for instance, eucalyptus and moringa extracts have proven effective against wheat aphids (Shah et al., 2017). The integration of plant based oils and powders into Integrated Pest Management (IPM) strategies could reduce reliance on synthetic chemicals while mitigating environmental and health risks.
In conclusion, it is important to emphasize that this study not only validates plant derived oils and powders as eco-friendly alternatives for controlling O. surinamensis in stored dates but also provides new evidence of their cumulative effects, comparative efficacy, and potential for scalability. These findings advance the field by offering actionable insights for reducing chemical inputs in agriculture. Further research is needed to: optimize application methods and dosages for large scale use, evaluate long term impacts, including resistance development in pest populations, and conduct field trials and economic analyses to assess practicality. Future studies should also concentrate on scalability and effectiveness in real world settings to guarantee their practical application.
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