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Research Article - (2013) Volume 4, Issue 1

Evaluation of Some Botanicals and Entomopathogenic Fungi for the Control of Onion Thrips (Thrips tabaci L.) in West Showa, Ethiopia

Tadele Shiberu, Mulugeta Negeri and Thangavel Selvaraj*
Department of Plant Sciences and Horticulture, College of Agriculture and Veterinary Sciences, Ambo University, Ambo, P.O. Box 19, Ethiopia
*Corresponding Author: Thangavel Selvaraj, Department of Plant Sciences and Horticulture, Professor of Pathology and Microbiology, College of Agriculture and Veterinary Sciences, Ambo University, Ambo, P.O. Box 19, Ethiopia, Tel: +251-913073294, Fax: +251-112362037 Email:


Onion thrips (Thrips tabaci L.) is one of the most important serious insect pests of onion (Allium cepa L.)
cultivation in Ethiopia. The present study was conducted to evaluate some botanical extracts viz. Artemisia annua, Azadirachta indica, Bidens pilosa, Chrysanthemum cinerariaefolium, Cymbopogon citratus, Nicotiana tabacum, Nicotiana spp.,(local var.,), Parthenium hysterophorous, Phytolacca dodecandra, Securidaca longepedunculata and two indigenous isolates of entomopathogenic fungi (EPF) viz. Beauveria bassiana (PPRC-56) and Metarhizium anisopliae (PPRC-6) and soap detergent powder. They were examined for controlling onion thrips (Thrips tabaci L.) under field condition in Guder, Toke Kutaye district of Ethiopia from mid October 2010 to early April 2011. Diazinon 60% E.C was applied at the recommended rate of 1.8 l/h and the plot left was examined as controls. After 1st day application of the different agents, EPF and untreated control were not significantly different. However, the results on
3rd, 5th, and 7th day after application of EPF treatments indicated that highly significant mortality. The rate of mortality in all of the treatments after 1st day ranged from 0 to 74.75%. On the other hand, botanical extracts recorded at 3rd day of application ranged from 26.09 to 74.75% within 3days of the higher mortality was recorded. On 5th and 7th day, except B. bassiana (PPRC-56), the mortality rate in all treatments became declined. The results indicated that insecticidal actions of all the tested agents exhibited to the ranging from 26.09 to 74.75% against onion thrips. Of the different agents, Nicotiana spp., P. dodecandra, S. longepedunculata and N. tabacum exhibited high mortality rate (69.65, 68.99, 63.85 and 63.56%, respectively), whereas in C. cinerariaefolium, A. indica and P. hysterophorous
showed intermediate mortality rate (60.79, 56.89 and 52.06 respectively) and the rest were the lowest mortality rate. High bulb yield reduction was recorded in untreated plots but low yield reduction was observed in treated plots and control check. The treatments also showed reducing onion thrips population and also gave significant control over the treated check. This study indicated that Nicotiana spp., P. dodecandra, S. longepedunculata, N. tabacum and B. bassiana were significantly very effective against onion thrips under field condition at recommended rate and then confirmed the valuable rate of botanicals and EPF as components of Integrated Pest Management (IPM) practices in Ethiopia.

Keywords: Onion thrips; Thrips tabaci; Botanicals; Entomopathogenic fungi; Beauveria bassiana; Metarhizium anisopliae; Diazinon


Allium crops are the most indispensable vegetable crops used as condiments in most Ethiopian cuisine. Among them, onion (Allium cepa L.) is one of the oldest known and an important bulbous vegetable crop grown in Ethiopia. It is used in preparation of different foods and in therapeutic medicine in the country. It has a great potential to produce every year for both local consumption and export with an average yield of 13.3 tons per hectare [1]. Toke Kutaye district of West Showa Zone, Ethiopia has high potential for onion cultivation due to availability of ample irrigated farmlands and the presence of relatively better market access as compared to other districts of West Showa Zone. Currently farmers in the study areas are growing the varieties of Adama red and Bombe red. However, both varieties are susceptible to onion thrips.

Onion thrips (Thrips tabaci, Lindman; Thysanoptera: Thripidae) is a key insect pest of onion [2]. In Ethiopia, it is an important insect pest that affect onion yield by direct feeding as well as reducing the quality and quantity by rasping the leaves and other tissues of onion crops to release the nutrients [3]. Onion fields can be destroyed by onion thrips, especially in dry seasons and are the major problem on onion crops in Ethiopia. Abate [3], and Merene [4] reported that onion bulb yield losses of 33 and 26-57% respectively, due to onion thrips in Ethiopia. Similar studies at Upper Awash Agro Industry Enterprises revealed yield losses of 10 to 85% due to onion thrips in Ethiopia [5]. In Ethiopia, growers are typically sprayed insecticides to control onion thrips, but it is now apparent that there are widespread ecological consequences such as soil and ground water contamination, impacts on the food chain and potential health concerns. As a result, persistent chemical insecticides are now prohibited in most countries and replaced by less persistent pesticides [6]. The function of these products can only be induced by contact, and therefore, much less effective than barrier treatments [7]. These products can control thrips quite effectively [8]. The limitations with the use of synthetic insecticides have provided the impetus to look for alternatives [9].

Bio-pesticides are likely to have a great attention in the insecticide sector [10]. Botanical insecticides and entomopathogenic fungal (EPF) insecticides are highly effective, safe and ecologically acceptable in general [11]. The common trends in the past two decades towards reducing reliance on synthetic insecticides for control of insect pests in agriculture, forestry, and human health. EPF, particularly Metarhizium anisopliae and Beauveria bassiana are attractive as bio-pesticides for use in integrated pest management, as they combine with host specificity and proven safety [12]. Biological control of pests with the use of plant extracts are not new practices, however, there is a need for science-based approaches to use a formal set of steps to investigate. The determination of the efficacy of botanical pesticides has to develop practical and low cost pest control. Moreover, biological control of insect pests with microbial agents has good since it would reduce inputs of chemical pesticides into the environment. Hence, the present study was taken to evaluate some botanicals and EPF for the control of onion thrips and also to assess the side effect of these bio-pesticides on mortality of natural enemies found in the experimental field.

Materials and Methods

Description of the study area

This study was conducted under field condition at Guder area in Toke Kutaye district of West Showa Zone, Oromia Regional State, Ethiopia. The area is located at 126 km west of Addis Ababa having an altitude of 1990 meter above sea level, latitude of 08° 59’ 01.1’ North and longitude of 37° 46’ 27.6’ East. The average annual rainfall is 1028.7 mm and maximum and minimum temperatures of the area 29.6°C and 11.8°C, respectively [13]. The soil type is a vertisol which is suitable for onion production.

Crop establishment

Seeds of onion (Allium cepa L. var. Bombe red) were obtained from a seed agency, Ambo, Ethiopia, which was seeded on 6 m2 raised nursery bed on October 15th, 2010, and seedlings were transplanted into farmer’s field on December 10th, 2010 (Figures 1 and 2A-2D).


Figure 1: Experimental onion cultivated farmer’s field infested with onion thrips. Scale 3.4.


Figure 2: (A) Onion thrips infested leaf (B) Larvae of onion thrips on leaf (C) Adult onion thrips (D) Larva of onion thrips. Scale 4.4.

Each plot was 3 m2 with five rows. Spaces used between blocks, plots, rows and plants were 1 m, 0.5 m, 0.4 m and 0.25 m, respectively. The experimental field was irrigated twice per week for the first three weeks after transplanting and weekly thereafter. The field was fertilized with Di-ammonium phosphate (DAP) and urea at the rate of 200 kg and 150 kg per hectare, respectively. The DAP was applied during transplanting and urea was applied split into two times. The first half was applied during transplanting and the remaining half after 30 days transplanted. Other recommended agronomic practices were carried out as required.

Experimental activities

The experiment was arranged in randomized complete block design with three replications. The experiment was made with irrigation water and transplanted Allium cepa L. var. Bombe red. Pre spray counts were recorded every week till reached economic threshold level 5 to 10 thrips per plant before treatment application [3]. After foliar treatment application of 1st, 3rd, 5th, and 7th day, post spray count of number of live onion thrips adults and larvae (Figures 2B-2D) were recorded by using hand lenses and digital. The efficacy percentage was calculated by using the Abbott formula [14]:


Where P=the corrected percent mortality; Ta=the observed percent mortality in treatment; Ca=the percent mortality in control

Plots were visually rated for thrips leaf damage using 0 to 8 rating scale: 0=no leaf damage 1=1-10%, 2=11- 20%, 3=21-30%, 4=31-40%, 5=41-50%, 6=51-60%, 7= 61-80% and 8= >81%. A rating of 8 reflected highly devastation by thrips (all white leaves rather than green) whereas a rating of 0 indicated zero thrips attack. A rating of four or below would be considered commercially acceptable. The reactions of the plants to the insecticides such as scorching, growth reduction, or stimulation and some abnormalities were examined and recorded. Finally upon maturity yield data were recorded.

Effect of botanicals and EPF on ladybird beetle, Adonia variegate

By nature ladybird beetles are moving from place to place. Proportion of the insect was minimal in the test plot required to bring them from other onion fields. To evaluate the effect of botanicals and EPF on beneficial adult ladybird beetle, Adonia variegate (Figure 3a) was collected from onion field. Then the ladybird beetles were prepared and sprayed with both botanicals and EPF fungi in the experimental plots cage. In each plot five adult beneficial insects were tested with covered cages (Figure 3b) having 50 cm length and 15 cm diameter until seven days, every 1st, 3rd, 5th and 7th day observation and data were recorded.


Figure 3: a) Ladybird beetle. Scale 3.2. (Adonia variegate). b) Ladybird beetles (Adonia variegate) on experimental field in tested cage. Scale 2.2.

Extraction and preparation of botanicals

The botanicals and the rates used are given in table 1.

Materials Used Parts used Rate/l Rate/ha Amount of water required/ha (Liters)
Artemisia annua Leaf and stalk 10 g 2 kg 150-200
Azadirachta indica Seed 25 g 5 kg 200-300
Bidens pilosa Whole plant 20 g 3 kg 200-300
Securidaca longepedunculata Root bark 10 g 2 kg 150-200
Cymbopogon citratus Leaf and stalk 10 g 2 kg 150-200
Chrysanthemum cinerariaefolium Flower 10 g 1.5 kg 150-200
Nicotiana tabacum (Verginia k-10) Leaf and stalk 12.5 g 2 kg 150-200
Nicotiana spp. (local variety) Leaf and stalk 20 g 3.kg 150-200
Parthenium hysterophorous Root 20 g 3 kg 150-200
Phytolacca dodecandra Seed 10 g 2 kg 150-200
Soap powder detergent - 10 g 2 kg 150-200
Diazinon 60% E.C - 5 ml 1.8 l 100-200

Table 1: The botanicals and the rates used for Extraction preparation.

The most widely used forms of the botanicals were to grind the plant parts (seed, flower, leaf, stalk, root and root bark) and extracting them with water. The plant parts were grind in a mortar using a pestle to a fine consistency using a plate (corn) mill and placed into a cheese cloth bag. The cheese cloth bag was then suspended in a bucket with water added to the content of the bag. The extract from the bag was collected as it emerges from the bag. The following plants and correspondingly mentioned plant parts were used for extraction (Figure 4).


Figure 4: Botanicals used for the study: (A) Artemisia annua (wormwood) (B) Azadirachta indica (neem), (C) Bidens pilosa (spanish needle), (D) Cymbopogon citratus (lemon grass), (E) Parthenium hyeterosphorous, (F) Chrysanthemum cinerariaefolium (Pyrethrum), (G) Nicotiana tabacum (local tobacco), (H) Phytolacca dodecandra (Endod) (I, J, & K) Securidaca longepedunculata (violet tree, pod with seeds and roots).

Artemisia annua: The matured leaves and stalks were collected from the Ambo Plant Protection Research Center, Ambo and dried under shade. 110 g of leaves and stalk powder were mixed with 1 liter of water, boiled for 10 minutes and then poured into 10 liters with additional water. The spray was made as soon as on onion thrips were observed in the onion field [15].

Azadirachta indica: The neem seeds were collected from Melka Werer Agricultural Research Center, Ethiopia. The seeds were grinded and then 50 g of neem powder was used in 2 liters of water, and extracted over night. The next day it was filtered with the help of cheese cloth and mixed with liquid soap at the rate of 1 ml/ lt of extract. Then the solution was ready for sprayed on infested onion thrips [16].

Bidens pilosa: The matured whole plant was collected from Ambo area farmer’s field, Ambo. One matured plant was pounded and 40 g was soaked in 2 liters of water over night, and then added 10 mg of soap powder and filtered out with cheese cloth, then the solution was made ready for spray [16].

Chrysanthemum cinerariaefolium: C. cinerariaefolium var. E-185 was collected from Bokoji Research Sub-Center, Ethiopia. 50 g of flower powder was extracted in 10 liters of water, stirred and filtered with cheese cloth. This mixture was then sprayed on treatment plots as described by Rankin [17].

Cymbopogon citrates: The leaves and stalks were collected from Ambo area farmer’s garden, Ambo, Ethiopia and dried under shade and then grinded 20 g of the powder added into 2 liters of water and filtered in cheese cloth and sprayed [17].

Nicotiana spp. (local var. tobacco): Tobacco leaves and stalks were collected from the gardens of farmers around Guder town, Ethiopia. The collected materials were dried under shade, 30 g of dried leaves and stalks were crushed and mixed with 1.5 liters of water and 10 mg of soap flaks were added as adhesive agent. After one day, the mixed materials were filtered out and sprayed [18].

Nicotiana tabacum (Verginia k-110): N. tabacum var. verginia k-110 leaves and stalks were prepared by mixing 250 g of the sample mixed with 4 liters of water and 30 g of soap flakes were added as adhesive agent. This mixture was boiled for 30 minutes, and the plant parts were filtered out and 16 liters of water was added to form a solution and then sprayed [18].

Parthenium hysterophorous: The matured plant was collected from Ambo town road side and urban agricultural field. 20 g of plant roots were taken and grounded and then soaked in one liter of water over night and 10 mg of soap powder was added. After filtering, the solution was made ready for spray on onion thrips infested onion plants [19].

Phytolacca dodecandra: Fully grown green but unripe berries were collected from road side grown voluntary plantations at Ambo town, Ethiopia. The berries were allowed to dry in the shade for two weeks and the dried berries were crushed and stored in plastic bags at room temperature (20-30°C). The powder extract was obtained by soaking in water for 24 h and then filtered. 150 g of seed powder was mixed with 15 liters of water and 10 mg of soap powder was added and then filtered and ready for sprayed [19].

Securidaca longepedunculata: The root bark of S. longepedunculata was collected from Gendeberet District, West Showa Zone, Ethiopia. The root bark was collected from underground part of the plant, washed, grinded in mortal, and then made a paste. 50 g was added in 5 liters of water and filtered through cheese cloth and then sprayed on infested onion plants [20].

In addition to the above mentioned botanicals, soap detergent powder and Diazinon 60% E.C were used as a treatment and standard check, respectively. 10 g of soap detergent powder was added to 1000 ml holding jar and filled with water to dilute the soap. This liquid was placed in a spray bottle for a basic homemade insecticidal soap for spraying on onion thrips.

Preparation of EPF conidial spores

Two indigenous EPF viz. Beauveria bassiana (PPRC-6) and Metarhizium anisopliae (PPRC-56) were obtained from Ambo Plant Protection Research Center, Ambo, Ethiopia. Sabouraud Dextrose Yeast Agar (SDYA) media was used for sub-culturing of both EPF (Figures 5 and 6). The cultures were incubated at 28°C for 10 days in the dark. On each culture plate, spores were harvested by flooding 10 ml of distilled sterilized water and 0.01% Tween 20 on plates. The spore suspensions were again filtered through cheese cloth and diluted (1:10) in sterile water. The suspensions were vortexed for eight minutes to avoid clumping of the spores. The conidial concentration of each isolate was adjusted to 1×107 conidia/ml using haemocytometer [21,22] and then made ready for foliar application by hand sprayers.


Figure 5: Beauveria bassiana culture plate.


Figure 6: Metarhizium anisopliae culture plate.

Data analysis

Analysis of variance (ANOVA) was conducted using Statistical Analysis Software [23] and compared treatment effects. The mean comparisons were carried out using Duncan’s Multiple Range Test (DMRT). Efficacy analysis was done based on data transformation to Arcsine [24]. Correlation analysis was also made to establish the relationship between bulb yield losses and infestation level. Yield loss percentage was calculated by comparing the standard check with other treatments.


Results and Discussion

Effect of botanicals and EPF against onion thrips and impact on onion crops

The results of the preliminary assessment of the study area found that the onion thrips infestation was high and specifically damage was increased on the crop during late February to early April. In order to reduce the infestation level of the thrips on onion through some botanicals and EPF agents under field condition was determined. Highly significant differences among the treatments were observed after application of botanicals and EPF agents and the results are depicted in tables 2,3 and figure 7. After 1st day application of treatments, EPF and untreated control were not significantly different. The rate of mortality in all of the treatments after 1st day ranged from 0 to 74.75%. In terms of mortality some of the treatments viz. Nicotiana spp., P. dodecandra, S. longepedunculata and N. tabacum exhibited high mortality rate (69.65, 68.99, 63.85 and 63.56%, respectively). On the other hand, the different treatments were recorded at 3rd day of application ranged from 26.09 to 74.75%. The better treatment effects were recorded after the 3rd day of application of Nicotiana sp. (local var.) P. dodecandra, S. longepedunculata and N. tabacum (verginia k-110) A. indica and C. cinerariaefolium with mortality rates 69.65, 68.99, 63.85, 63.56, 60.79 and 56.89%, respectively. The rest of the treatments were gradually decreased after the third day of application (Table 2). In 5th and 7th day, the mortality rate of all treatments except B. bassiana (PPRC-56) became declined. Unlikely, B. bassiana was increased after three days. However, after treatment application of 3rd, 5th, and 7th day indicated that highly significant (P<0.01) differences from untreated control. Nicotiana spp. (leaf and stalk), N. tabacum (Verginia k-110, leaf and stalk), P. dodecandra (seed) and S. longepedunculata (root bark) extracts provided the best control of onion thrips. The other botanicals C. cinerariaefolium, A. indica and P. hysterophorous also provided an adequate control. In most cases, these botanicals significantly reduced thrips population densities, but not necessarily to a level that would be considered adequate. But B. pilosa, A. annua, C. citratus, and soap detergent powder were performed very low in reducing onion thrips (Table 2).

Per cent mortality of onion thrips /Days after application
Treatments 1st day 3rd day
Artemisia annua 50.46 (45.26 ± 0.79)def 32.49 (34.45 ± 0.61)d
Azadirachta indica 63.47 (52.92 ± 0.92)cde 76.17 (60.79 ± 1.06)ab
Bidens pilosa 31.74 (30.08 ± 0.60)f 34.48 (35.94 ± 0.63)d
Securidaca longepedunculata 78.10 (58.34 ± 1.08)bcd 79.57 (63.85 ± 1.10)ab
Cymbopogon citratus 44.13 (41.35 ± 0.73)ef 31.41 (33.41 ± .59)d
Chrysanthemum cinerariaefolium 62.70 (52.43 ± 0.91)cde 69.77(56.89 ± 1.0)abc
Nicotiana tabacum (Ver. k-110) 79.19 (62.98 ± 1.10)abc 80.10 (63.56 ± 1.11)ab
Nicotiana spp.(local variety ) 86.31 (68.60 ± 0.19)ab 86.97 (69.65 ± 1.20)a
Parthenium hysterophorous 62.14 (52.06 ± 0.91)cde 40.06 (38.93 ± 0.69)cd
Phytolacca dodecandra 76.98 62.22 ± 1.07)abc 86.37 (68.99 ± 1.19)a
Beauveria bassiana (PPRC-6) 0.0 (0.0 ± 0)g 50.78 (46.18 ± 0.79)bcd
Metarhizium anisopliae (PPRC-56) 0.0 (0.0 ± 0)g 26.56 (26.09 ± 0.54)d
Soap powder detergent 43.12 (41.02 ± 0.72)de 31.84 (33.31 ± 0.31)d
Diazinon 60% E.C (standard check) 91.58 (74.75 ± 1.28)a 91.27 (74.75 ± 1.27)a
Untreated control 0.0 (0.0 ± 0)g 0.0 (0.0 ± 0)e
MSE 10.43(7.12) 15.39(11.02)
CV (%) 20.53(16.55) 29.36(23.38)
Days after application/ per cent of mortality
Treatments 5th day 7th day
Artemisia annua 1.81 (4.49 ± 0.31)cd 2.31 (5.08 ± 0.15)c
Azadirachta indica 60.80 (51.31 ± 0.89)a 55.03 (47.93 ± 0.84)ab
Bidens pilosa 7.30 (12.16 ± 0.27)bcd 2.75 (5.56 ± 0.17)c
Securidaca longepedunculata 62.37 (52.23 ± 0.91)a 63.43 (52.24 ± 0.91)ab
Cymbopogon citratus 8.0 (16.16 ± 0.29)bc 3.33 (11.25 ± 0.18)c
Chrysanthemum cinerariaefolium 59.23 (50.41 ± 0.88)a 56.53 (48.82 ± 0.85)ab
Nicotiana tabacum (Ver. k-110) 55.73 (48.33 ± 0.84)a 52.30 (46.32 ± 0.81)ab
Nicotiana spp. (local variety) 68.48 (55.96 ± 0.97)a 64.70 (53.62 ± 0.93)ab
Parthenium hysterophorous 12.77 (17.28 ± 0.36)bc 10.94 (13.25 ± 0.34)c
Phytolacca dodecandra 42.51 (40.62 ± 0.71)a 43.97 (41.51 ± 0.72)b
Beauveria bassiana (PPRC-6) 65.84 (54.31 ± 0.95)a 75.63 (60.67 ± 1.05)a
Metarhizium anisopliae (PPRC-56) 17.58 (23.09 ± 0.43)b 13.56 (16.41 ± 0.38)c
Soap powder detergent 9.50 (16.10 ± 0.31)bc 6.90 (2.38 ± 0.27)c
Diazinon 60% E.C (standard check) 71.74 (55.17 ± 0.96)a 67.01 (57.93 ± 1.01)ab
Untreated control 0.0 (0.00 ± 0)d 0.0 (0.00 ± 0)c

Note: Means with the same letter(s) are not significantly different for each other. All treatment effects were highly significant at P<0.01 (DMRT). Figures in parentheses are Arcsin image percent transformed value.

Table 2: Percentage mortality of onion thrips due to botanicals and EPF under field condition.

Treatments Mean leaf damaged (score) Leaf damaged (%)
Artemisia annua 3.2cd 21-32
Azadirachta indica 2.53efd 21-30
Bidens pilosa 4.73b 41-50
Securidaca longepedunculata 2.47ef 21-30
Cymbopogon citratus 3.73c 31-40
Chrysanthemum cinerariaefolium 2.27fg 11-20
Nicotiana tabacum (Verginia k-10) 1.67gh 11-20
Nicotiana spp. (local variety ) 1.33h 11-20
Parthenium hysterophorous 3.07cde 21-30
Phytolacca dodecandra 1.60h 11-20
Beauveria bassiana (PPRC-6) 3.67c 31-40
Metarhizium anisopliae (PPRC-56) 4.93b 41-50
Soap powder detergent 3.20cd 21-30
Diazinon 60% E.C/Check 1.0h 1-10
Control/Untreated plot 6.47a 21-30
MSE 0.38  
CV (%) 12.1  

Note: Means with the same letter(s) are not significantly different for each other. All treatment effects were highly significant at P<0.01 (DMRT).

Table 3: Percentage of leaf damaged scores due to some botanicals and EPF against onion thrips under field condition.


Figure 7: Mortality percentage of EPF for controlling onion thrips under field condition.

Similarly the efficacy of botanicals viz., P. dodecandra, C. cinerariaefolium, N. tabacum and A. indica for the controlling the onion thrips has been reported by Stoll [16] earlier. Dodia et al. [25] also mentioned that in addition to the above botanicals Cymbopogon citratus and Parthenium hysterophorous were found effect on the onion thrips. From such results, it appears that these botanicals may possess anti-feedant, repellent and insecticidal or combination of these effects to reduce the damage level caused by onion thrips [25]. According to Ayalew [26] found that the ethanol extracts of neem seed powder evaluated against onion thrips, reduced thrips population under field condition. Leaves of Bidens pilosa and soap powder were used as an insecticide for the control of leaf miners and other insects [27]. Similarly, PAN [28] indicated that B. pilosa was effective against aphid, cutworm and termites. Likely, in this study, B. pilosa was minimized the number of onion thrips population but exhibited low mortality rate percentage when compared to other treatments. S. longepedunculata showed a better performance than commonly used botanicals, A. indica and C. cinerariaefolium (Table 2). S. longepedunculata is a toxic plant and its root bark contains “Chamana’e” which is commonly used for washing clothes as well as medicinal value against snake attack in areas where the plant is grown. Under Ethiopian condition there is a study made on the use and toxicity potential of the plant against any insect pest. In this study, this plant was found performance better than the already known botanicals, A. indica and C. cinerariaefolium (Table 2). Atawodi et al. [29] reported that the powder of root bark of this plant used as a storage grain weevil control. In this study, it was true that pyrethrum was intermediate type in its efficacy compared to other treatments, but highly significantly out of performed the untreated plot and no significant different observed as to standard check on 3rd day of treatment application. According to Purseglove [30] found that C. cinerariaefolium (pyrethrum) has insecticidal properties, anti-feedant or bite inhibition and contact poison properties, which is effectively used against numerous agricultural and non-agricultural insects, but harmless to human and other worm blooded animals. Casida [31] mentioned that it was a broad spectrum insecticide used to control whiteflies, aphids, mites, thrips and beetles and also reported the level of pest control is likely to be higher on field condition when properly applied. In this study, C. citratus was at 1st, 3rd, 5th, and 7th day scored lesser efficacy percent against onion thrips under field condition but Stoll [16] reported that lemongrass, the whole plant extract was very effective against rice pest. In this study, P. hysterophorous root extract was minimized onion thrips at 1st day but prolonged to decline within 7 days. Previously there was no information on effect of P. hysterophorous extract on thrips control but parthenium extract was reported as effective on tortoise beetle causing significant mortality on its larvae [32].

Effect of EPF on onion thrips

The effect of EPF was also evaluated on the same experimental field against onion thrips. In this study, Beauveria and Metarhizium were caused 46.18% and 26.09% mortality of onion thrips at the 3rd day of application, respectively. It was observed that the effect of Beauveria against the onion thrips was significantly increased after 3 days whereas the effect of Metarhizium against the onion thrips was prolonged unlikely decreasing trend resulting unsatisfactory control of the pest. The control effect of B. bassiana was not significantly different from the standard check Diazinon 60% at 7th day after spray (Table 2 and Figure 7). Both EPF treatments showed highly significant (P<0.01) difference from the untreated control. These findings are in agreement with the previous reports of Metcalf et al. [33]. They had also mentioned that B. bassiana was most effective when used early at economic threshold level, before large thrips populations have built up. According to Vestergaard et al. [34] reported that the temperature is the principal factor in determining EPF efficacy. The influence of temperature on the infection process is very important. According to them, the temperature at which Metarhizium infecting adult thrips is about 23°C and decreases in temperature of 3 to 5°C increase the time to death of the insect about a day. Beauveria is used as a contact myco-insecticide but survives a relatively short period of time when exposed on a leaf surface. The killing capacity of this fungus at 3rd, 5th, and 7th day was 46.18, 54.31 and 60.67%, respectively. These results in agreement with the reports of Neil et al. [35] reported that Beauveria infection can kill the insect from 3 to 7 days, leaving a while mass of spores which can spread to other insects.

Effect of botanicals and EPF on yield

The loss of bulb yield depicted in table 4 showed that bulb yield loss attributed to onion thrips infestations. The onion crops were harvested on April 20th, 2011 and measured on the same day. There was a significant increase in super colossal yield bulbs in the treatment specifically Nicotiana spp. (local var.), P. dodecandra, S. longepedunculata, C. cinerariaefolium, N. tabaccum (verginia k-110) and A. indica treated plots gave high yield percentage compared to untreated plot. Rana et al. [36] also reported that the leafhopper and thrips populations were effectively managed by tobacco 5% and gave significantly higher yield against untreated control. High yield loss was recorded on treatments of B. pilosa, M. anisopliae, Soap detergent powder, C. citratus, A. annua, and P. hysterophorous, (28.74, 27.59, 24.48, 23.79, 23.33, and 20.34% respectively). This showed that the yield loss due to onion thrips infestation was very high and significantly (P<0.05) different among the treatments. The yield losses ranged from 0 to 36.44% were recorded during the study period. While the relationship between yield loss and onion thrips infestation level was attributed to reduction of yield significantly (P<0.05) and positive correlation (r=0.97) between yield reduction and leaf area damage (Figures 8 and 9). This means that as infestation level increased the yield loss becomes increased (Figure 8). This indicated that the yield loss due to onion thrips without any control mechanism at Gudar area, West Showa zone, Ethiopia under field condition (Table 4). Similarly, Merene [4] suggested that onion yield loss due to onion thrips recorded 26-57% in Showa Robit area, Ethiopia.


Figure 8: Relationship between leaf areas damaged and yield loss due to onion thrips infestation.


Figure 9: Estimated linear relationship between mean leaf areas damaged and yield loss due to onion thrips infestation.

S.No Treatments Mean yield/plot (kg) Mean Yield/ha (kg) % yield loss
1 Artemisia annua 6.7bcd 22230 23.33
2 Azadirachta indica 7.6abc 25330 12.64
3 Bidens pilosa 6.2bcd 20670 28.74
4 Securidaca longepedunculata 8.0ab 26670 8.05
5 Cymbopogon citratus 6.6bcd 22100 23.79
6 Chrysanthemum cinerariaefolium 7.9ab 26230 9.54
7 Nicotiana tabacum (Verginia k-110) 7.7abc 25870 11.15
8 Nicotiana spp. (loca tobacco) 8.5ab 28330 2.30
9 Parthenium hysterophorous 6.9abc 23100 20.34
10 Phytolacca dodecandra 8.2ab 27230 6.09
11 Beauveria bassiana (PPRC-6) 7.0abc 23330 19.54
12 Metarhizium anisopliae (PPRC-56) 6.3bcd 21000 27.59
13 Soap detergent powder 6.6bcd 21900 24.48
14 Diazinon 60% E.C/Check 8.7a 29000 ----
15 Untreated control 5.5d 18430 36.44
MSE 1.00    
CV (%) 13.73    

Note: Means with the same letter(s) are not significantly different for each other. All treatment effects were significant at P<0.05 (DMRT)

Table 4: Mean yield and onion bulb yield loss treated with botanicals and EPF against onion thrips.

Adult ladybird beetles mortality

Observation on predatory insect showed the presence of ladybird beetles on experimental field was found. All of the botanicals and the EPF did not affect the adult ladybird beetles in the experimental field. Dodia et al. [25] reported that nicotine is not selective insecticide and is highly toxic to a range of species including predatory insects. However, this study which was in agreement with the findings of Diraviam and Viraktamath [37] mentioned nicotine is a safer insecticide for higher animals and safer to Curinus coeruleus and other predators. Saxena [38] reported that A. indica is harmless to ladybird beetles that consume aphids and wasps that act as parasites on various crop pests. Artemisia spp. (leaf and stalk extract), C. citratus, B. pilosa, and C. cinerariaefolium were found to be friendly to the existing non-target organisms whereas recent studies showed that pyrethrin based chemical products are harmful to natural enemies, fish and crustaceans and pose environmental risks [28]. In this study, percent reductions of ladybird beetle populations were observed in standard check plots. This indicated that Diazinon 60% E.C had its side effect on ladybird beetles to some extent.


This study clearly indicated that the application of some botanicals based on formulation of aqua water and powder extracts were effectively control onion thrips infesting onion crops. Among tested botanicals and EPF, Nicotiana spp. (local tobacco), N. tabacum (Verginia k-110) P. dodecandra, S. longepedunculata, and B. bassiana were significantly very effective against onion thrips after 3rd day and followed by C. cinerariaefolium, A. indica and P. hysterophorous under field condition at recommended rate and then confirmed the valuable rate of botanicals and EPF as components of Integrated Pest Management (IPM) practices in Ethiopia. Further study on development of natural plants for the control of onion thrips, shelf life of the botanical extracts, frequency and the rate of application to be needed for the further investigation.


I am greatly indebted to my advisors Dr. Mulugeta Negeri and Prof. Thangavel Selvaraj for their invaluable professional help initiatives and encouragement. This research work also could have been realized without the consistent support of the whole staff of Ambo Plant Protection Research Center (APPRC) and the Department of Plant Sciences of Ambo University, Ambo, Ethiopia.


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Citation: Shiberu T, Negeri M, Selvaraj T (2013) Evaluation of Some Botanicals and Entomopathogenic Fungi for the Control of Onion Thrips (Thrips tabaci L.) in West Showa, Ethiopia. J Plant Pathol Microb 4:161.

Copyright: ©2 013 Shiberu T, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.