Push Pull Technique In Integrated Pest Management

Introduction Pesticides are used to kill the pests and insects which mainly feed on the economic crops. However, they could also impose serious negative impacts on the environment. They hamper the sustainability and normal functioning of the food chains. Pesticide hazards are common especially due to their mobility in the environment which could be by water, air and soil . They could drastically alter the natural balance of the ecosystem by decimating the non-pest or non-target beneficial organisms and indirectly favour the population increase of the pests. So, we opt new Technique for the conservation and utilization of resources available to modifying the behaviour of insect-pests affecting the crops for sustainability in agriculture production by reducing the cost of pest management. The effect of push pull technique adoption is decisive topic because which allow farmers to increase their productivity and income without increasing their impact on the surrounding environment or their reliance on frequently unreliable agricultural input markets.

History Push-pull Technology was developed by scientists at the International Centre of Insect Physiology and Ecology (ICIPE) , in Kenya and Rothamsted Research , in the United Kingdom, in collaboration with other national partners in the 1990s. Donors and Funded Projects Research and development for the push-pull Technique was funded by a number of partners including the Gatsby Charitable Foundation of the UK, the Rockefeller Foundation , the UK’s Department for International Development, and the Global Environment Facility of the UNEP, among others. The EU is also funding ‘Up scaling the benefits of push-pull technology for sustainable agricultural intensification in East Africa. Bio-Vision Foundation is funding 'Intensification of push-pull technology for improved food security, nutrition and incomes’. Swedish Research Council is funding 'Towards sustainable maize production in East Africa: Cropping system resilience under climate change'(Resilient push-pull)’. Norwegian Agency for Development Cooperation - Norad : is funding: 'Combating Arthropod Pests for Better Health, Food and Resilience to Climate Change (CAP-Africa)'

The term “push-pull” was first conceived as a Technique for insect pest management by Pyke, Rice, Sabine and Zaluki in Australia in 1987. A “push–pull’’ Technique is a cropping system in which specifically chosen companion plants are grown in between and around the main crop. Define: These companion plants release semio-chemicals (stimulo-deterrent diversionary strategy) that fend off insect pests from the main crop using an intercrop which is the “push” component and concurrently attract insect pests away from the main crop using a trap crop which is the “pull” component Fig. 1: Principle of push-pull Technique

What is Push ? In this strategy, the pests are repelled or deterred away from the main crop (push) by using stimuli that mask host apparency or are repellent or deterrent. What is Pull ? The pests are simultaneously attracted (pull), using highly apparent and attractive stimuli, to other areas such as traps or trap crops where they are concentrated, facilitating their control. Fig. 2: Push-pull mechanism

Components of Push-Pull Technique Visual stimulants Host volatiles Sex and aggregation pheromones Gustatory and oviposition stimulants Visual cues Synthetic repellents Non-host volatiles Host-derived semiochemicals Anti-aggregation pheromones Alarm pheromones Antifeedants Oviposition deterrents

Push components 1.Visual cues: Manipulation of host color, shape, or size to inhibit host orientation and acceptance behaviors of pests in IPM has rarely been used, as these traits usually lack speciﬁcity and are often impractical to change in hosts. 2. Repellents: Chemical which repel or push the pest from main crop which can be utilized as push component in this strategy. Frontalin acts as repellent i.e. push the coffee berry borer Hypothenemus hampei from coffee. 3. Non-Host Volatiles: Volatiles derived from non-hosts can be used to mask host odors or evoke non host avoidance and repellent behaviors. Plant essential oils such as citronella and eucalyptus are commercially produced as repellents against hematophagous insects. 4. Host Volatiles: Insects recognize suitable hosts by using key volatiles that are often present in speciﬁc Ratios. Directed host Orientation Ceases, If host odors are presented in inappropriate ratios, as herbivore-induced plant volatiles (HIPVs) are produced by plant when herbivores feed on them. The HIPVs can deter plant utilization by subsequent herbivores as indicators of competition or induced defenses .

5. Alarm pheromones: Alarm pheromone released when attacked by the natural enemies, causing avoidance or dispersal behaviour in conspecifics. Many aphid species release (E)-β- farnesene ( Eβf ) as alarm pheromone. On main crop application of alarm pheromones which ward off aphids in the field and Eβf also functions as a kairomonal activity to pull natural enemies of aphids. 6. Antifeedants: Several antifeedants, including azadirachtin (the primary active component of neem, derived from Azadirachta indica ) , applied as NSKE in cotton against H. armigera . However other plants also have antifeedent compounds viz . pongamia, eucalyptus, Melia azedarach , Annona. 7. Oviposition deterrents and oviposition deterring pheromones: ODPs are compounds that prevent or reduce egg deposition and so it can be corporate in the push-pull strategies to control species that cause damage through this process or whose imagoes are pestiferous. During egg laying both parasitic and phytophagous insects are known to deposit chemical signals that modify the behaviour of conspecifics who consequently stay away from depositing eggs into host that are oviposited by others. The deterrents isolated from non hosts plants have deterring oviposition of pests, and of these, frequently evaluated formulation was neem-based formulations and some other plants are also used.

Pull Components: 1.Visual stimulants: The visual cues related to the plant growth stage can be important sole method used to attract pests to traps or trap crops, but they can enhance the effectiveness of olfactory stimuli. Sexually mature apple maggots, Rhagoletis pomonella attracted towards, red spheres (7.5 cm in diameter) mimicking ripe fruit. These traps, coated with either sticky material or contact insecticides and baited with synthetic host odors , have been used successfully for management of pest. 2. Host volatiles: Host volatiles used in host location, mass-trapping, or in attracticide strategies. HIPVs are often reliable indicators of the presence of hosts or prey to predators and parasitoids and are therefore attractive (pull) to these beneficials. The conophthorin acting as the ‘pull’ (attractant) for Hypothenemus hampei .

3. Sex and aggregation pheromones: Insects release sex and aggregation pheromones to attract conspeciﬁcs for mating and optimizing resource use. Both types of pheromones are increasingly important components of IPM, particularly in pest monitoring. Traps baited with these pheromones have a lower detection threshold than other methods and can help in push-pull strategies to determine the timing of stimuli deployment and population-reducing interventions. 4. Gustatory and oviposition stimulants: Trap crops may naturally contain oviposition or gustatory stimulants, which help to retain the pest populations in the trap crop area. Gustatory stimulants, such as sucrose solutions, have also been applied to traps or trap crops to promote ingestion of insecticide bait. Food supplements to establish populations of natural enemies and inﬂuence their distribution .

Push-pull Technique in crops Management of cereal stem borers in eastern Africa The Push-Pull technology involves use of behaviour modifying stimuli to manipulate the distribution and abundance of stem borers and beneficial insects for management of stemborer pests . It is based on in-depth understanding of chemical ecology, agro biodiversity, plant-plant and insect-plant interactions, and involves intercropping a cereal crop with a repellent intercrop such as desmodium (push), with an attractive trap plant such as Napier grass (pull) planted as a border crop around this intercrop. Gravid stem borer females are repelled from the main crop and are simultaneously attracted to the trap crop. Napier grass produces significantly higher levels of attractive volatile compounds (green leaf volatiles), cues used by gravid stem borer females to locate host plants, than maize or sorghum. There is also an increase of approximately 100-fold in the total amounts of these compounds produced in the first hour of nightfall by Napier grass (scotophase), the period at which stem borer moths seek host plants for oviposition, causing the differential oviposition preference. However, many of the stem borer larvae, about 80%, do not survive as Napier grass tissues produce sticky sap in response to feeding by the larvae which traps them causing their mortality.

Legumes in the Desmodium genus ( silverleaf , D . uncinatum, greenleaf, D . intortum ), on the other hand produce repellent volatile chemicals that push away the stemborer moths . These include (E)-ß-ocimene and (E)-4,8-dimethyl-1,3,7-nonatriene, semiochemicals produced during damage to plants by herbivorous insects are responsible for the repellence of desmodium to stemborers. Desmodium also control striga , resulting in significant yield increases of about 2 t/ha per cropping season. In the elucidation of the mechanisms of striga suppression by D. uncinatum , it was found that, in addition to benefits derived from increased availability of nitrogen and soil shading , an allelopathic effect of the root exudates of the legume, produced independently of the presence of striga, is responsible for this dramatic reduction in an intercrop with maize. This combination thus provides a novel means of in situ reduction of the striga seed bank in the soil through efficient suicidal germination even in the presence of graminaceous host plants in the proximity. Other Desmodium spp. have also been evaluated and have similar effects on stemborers and striga weed and are currently being used as intercrops in maize, sorghum and millets.

2. Control of Helicoverpa in Cotton Push pull Technique is now used to control the polyphagous lepidopteran pest Helicoverpa armigera and Helicoverpa punctigera attacking cotton. Neem seed extracts are applied to the cotton crop (push) and alongside an attractive trap crop of either pigeon pea ( cajanus cajan ) or maize ( zea mays ) is planted (pull). Field trials have shown the efficacy of this approach which is far more than the individual component alone. According to experiment on Push-pull technology on cotton for Helicoverpa spp.: Material for experiment 1. Cotton variety = PKV-Rajat 2. Pigeon pea variety = TAT-10 3. Sunflower variety = Modern

Treatment details: Treatment Details of experiment T1 Cotton (NSE treated), Pigeon pea (NPV treated) T2 Cotton (NSE treated), Pigeon pea (untreated) T3 Cotton (untreated), Pigeon pea (NPV treated) T4 Cotton (untreated), Pigeon pea(untreated) T5 Cotton (NSE treated), Sunflower (NPV treated) T6 Cotton (NSE treated), Sunflower(untreated) T7 Cotton (untreated), Sunflower (NPV treated) T8 Cotton (untreated), Sunflower(untreated) T9 Cotton (NSE and NPV) Cotton (NSE) T10 Cotton (NSE treated) T11 Cotton (NOV treated) T12 Cotton (untreated) J adhav et al. (2008) Akola, Maharashtra

Treatment Eggs/plant Larvae/plant % age fruiting damage T1 5.52 (2.28) 0.86 (0.92) 0.90 (0.95) T2 5.56 (2.36) 1.47 (1.21) 1.36 (1.17) T3 11.72 (3.42) 2.81 (1.67) 2.48 (1.57) T4 13.13 (3.62) 3.33 (1.82) 2.45 (1.72) T5 5.79 (2.41) 1.10 (1.05) 1.09 (1.04) T6 6.17 (2.48) 1.74 (1.32) 1.49 (1.22) T7 12.11 (3.48) 2.95 (1.72) 2.76 (1.66) T8 13.59 (3.69) 3.44 (1.85) 3.19 (1.78) T9 8.73 (2.95) 2.19 (1.48) 1.73 (1.31) T10 9.40 (3.06) 2.51 (1.58) 2.08 (1.44) T11 14.74 (3.84) 4.09 (2.09) 2.59 (1.61) T12 15.79 (3.97) 4.89 (2.21) 6.10 (2.47) F test Sig. Sig. Sig. SE(m)± 0.02 0.04 0.03 CD @ 5% 0.06 0.12 0.09 Effect of “Push-pull Technique ” on egg laying, Larval and percentage damage on of H.armigera on main crop, Cotton.

Observation All observation were recorded 3rd, 7th and 14th DAS. Egg, larval population and damage in fruiting bodies on main crop and intercrop.

Tr no. Treatment details Average egg production of H.armigera per plant Average 3DAS 7DAS 14 DAS T1 Cotton (NSE treated), Pigeon pea (NPV treated) 7.75 8.76 9.85 8.79 T2 Cotton (NSE treated), Pigeon pea (untreated) 9.58 10.80 12.15 10.84 T3 Cotton (untreated), Pigeon pea (NPV treated) 13.82 14.97 16.05 14.95 T4 Cotton (untreated), Pigeon pea (untreated) 13.28 14.67 16.22 14.72 Effect of Push-pull technology on Egg laying of H.armigera on trap crop, Pigeon pea. Best treatment was T1 and T2 Application of NSE on cotton reduces egg laying on trap crop also. This is due to repellent action on cotton as well as pigeon pea, due to less distance between the cotton and pigeon pea.

Tr. no Treatment details Average egg production of H.armigera per plant Average 3DAS 7DAS 14DAS T5 Cotton (NSE treated), Sunflower (NPV treated) 2.54 3.12 4.11 3.26 T6 Cotton (NSE treated), Sunflower (untreated) 3.51 4.10 4.94 4.18 T7 Cotton (untreated), Sunflower (NPV treated) 4.31 5.44 6.26 5.34 T8 Cotton (untreated), Sunflower (untreated) 4.98 5.55 6.58 5.70 Tr no. Treatment details Average egg production of H.armigera per plant Average 3 DAS 7DAS 14DAS T1 Cotton (NSE treated), Pigeon pea (NPV treated) 1.65 1.55 2.01 1.64 T2 Cotton (NSE treated), Pigeon pea (untreated) 2.26 2.68 3.03 2.66 T3 Cotton (untreated), Pigeon pea (NPV treated) 2.17 2.45 2.92 2.51 T4 Cotton (untreated), Pigeon pea(untreated) 3.23 3.60 4.04 3.64 Effect push-pull technology on egg laying of H.armigera on trap crop sunflower Minimum egg laying was observed in T5 and T6 Effect push-pull technology on Larval population of H.armigera on trap crop Pigeon pea Best effective treatment was T1 followed by T3 Both contain NPV. This indicate that NPV on trap crop reduced the larval population of H.armigera .

Effect push-pull technology on Larval population of H.armigera on trap crop Sunflower Minimum larval population found inT5 thenT7, NPV plays important role for larval control. Effect push-pull technology on percent pod damage by H.armigera on trap crop Pigeon pea Tr. No. Treatment details Average egg production of H.armigera per plant Average 3DAS 7DAS 14DAS T5 Cotton (NSE treated), Sunflower (NPV treated) 0.38 0.42 0.70 0.50 T6 Cotton (NSE treated), Sunflower(untreated) 1.02 1.28 1.71 1.37 T7 Cotton (untreated), Sunflower (NPV treated) 0.84 0.80 1.33 1.01 T8 Cotton (untreated), Sunflower(untreated) 1.126 1.55 1.85 1.55 Tr. no. Treatment details Average egg production of H.armigera per plant Average 3 DAS 7DAS 14DAS T1 Cotton (NSE treated), Pigeon pea (NPV treated) 5.60 9.60 11.20 8.80 T2 Cotton (NSE treated), Pigeon pea(untreated) 13.60 10.40 19.20 14.40 T3 Cotton (untreated), Pigeon pea (NPV treated) 9.60 13.60 12.80 12.00 T4 Cotton (untreated), Pigeon pea(untreated) 12.80 14.40 23.20 16.80 Minimum damage T1 and T3

Treatment Yield kg/ha Cost of yield Rs/ha Gross monitory Rs/ha Cost of plant protection Net return Rs/ha Cotton Trap Cotton traps T1 862 286 17067.60 6149 23216.60 1689 21527.60 T2 580 180 11484.00 3870 15354 858 14496 T3 520 220 10296 4730 15026 831 14195 T4 485 160 9603 3440 13043 13043 T5 690 150 13662 2700 16362 1689 14673 T6 519 120 10692 2160 12852 858 11994 T7 489 130 9682 2340 12022 831 11191 T8 475 95 9405 1710 11115.5 11115 T9 553 - 10969.20 - 10969.20 1689 9280.20 T10 541 - 10711.80 - 10711.80 858 9853.80 T11 497 - 9860.40 - 9860.40 831 9029.40 T12 450 - 8910.00 - 8910.00 8910.00 Economics of Push-pull technology Maximum yield was found T1 followed by T5

3. Pea leaf weevil management in beans Sitona lineatus , Pea leaf weevil is a pest of legumes in Europe, the Middle East and United States. Synthetic aggregation pheromone 4-methyl-3,5-heptanedione acted as pull component and commercially available neem antifeedant formed the push component of the strategy. Neem reduced weevil abundance satisfactorily. Just to maintain the efficacy repeated application was needed. Speedy removal of the aggregated weevil population must be done to prevent them from redistributing in the main crop.

Advantages of Push-pull Technique Push-Pull technology is the first integrated pest and soil fertility management technique that effectively combines control of both stemborers and striga weed. Increase maize yield by 25 % to 30% in the areas where only stem borers are a problem but more than 100% where both stem borers and striga problem. Desmodium controls striga, resulting in significant yield increases. Push-pull technology provides all-year round quality fodder, and this is one of the main motivating factors for its adoption by many livestock farmers. Fix nitrogen into your farm by desmodium legume, so we save on fertilizer costs. Protect soil from erosion as desmodium acts as a cover crop. Retain soil moisture in plot because desmodium acts as a mulch. Save on farm labour as you do not have to manually remove striga weed from the farm. The push pull components are generally nontoxic and therefore, the strategies are usually integrated with biological control. Due to its multiple benefits, the technology has opened up opportunities for smallholder growth and represents a platform technology around which new income generation and human nutritional components, such as livestock keeping, can be added.

Limitations of Push-pull Technique The use of push-pull strategies has some over conventional pest control regimes. Limited specificity. Less effective to complete with abundant surrounding odor sources for attraction. Limitation to development: Understanding the behavioral and chemical ecology of the host and pest Insufficient knowledge, control break down Development of semi-chemical component Limitation to adoption: Integrated approach to pest control, more complex. Requiring monitoring and decision system. More insecticide and less knowledge of biological control agent.

Conclusion The principles of the push-pull Technique are used to minimizing detrimental effect on environment while maximize control efficacy, competency, sustainability and outputs. The push and pull components are generally nontoxic and can be useful for the small and marginal farmers by reducing cost of cultivation and indirectly uplift the standard of living. hence, the strategies are usually integrated with biological control and cultural control for management of pest. Although each individual component of the technique may not be as effective as a broad-spectrum insecticide at reducing pest numbers, the efficacy of push and pull components is increased through tandem deployment.

Future for push-pull technology Several new technologies may help develop and improve future push-pull strategies because we better understand the behaviour of pest and beneﬁcial insects, enabled by advances in analytical techniques, synthesis procedures, and formulation science, we may have a larger and more effective armory of semiochemicals and other stimuli for future use. In plant-based strategies the use of induced defenses and plants that produce the desired semiochemicals themselves rather than applying them to the plant, would help make the strategies more sustainable and available, especially for poor farmer. The continued spread of insecticide resistance and the withdrawal of insecticides due of legislation leave few other alternatives, Adoption would increase. Push pull targeted at predator and parasitoids, while enable to manipulation of their distribution for improved biological control, are just around the corner. This prospect will allow these strategies to applied in novel ways and increase their use in IPM in future. Changing attitudes towards replacing broad spectrum insecticide with new technologies, particularly semiochmicals tools, to manipulate the behaviour of natural enemies for improved biological control will enable improved push pull strategies to be developed and used more widely in the future.

REFERENCES Cook, S. M.; Khan, Z. R. and Pickett, J. A. ( 2007). The Use of Push-Pull Strategies in Integrated Pest Management. Annu . Rev. Entomol , 52: 375–400. Chatterjee, D. and Kundu, A. (2022 ). Just Agriculture Multidisciplinary e-news letter , 2 (9): e-ISSN: 2582-8223. Gaikwad, M. B.; Challa , N.; Panma , Y. and Thakur, P. (2019). Push-pull strategy: Novel approach of pest management. Journal of Entomology and Zoology Studies, 7(5): 220-223. Jadhav, S. B.; Sadawarte , A. K. and Bhalkare , S. K. (2008). Evaluation on push-pull Technique for the management of Helicoverpa armigera on Cotton. Indian Journal of Entomolgy , 70 (4): 360-364. http://www.push-pull.net/ https://en.wikipedia.org/wiki/Push%E2%80%93pull_agricultural_pest_management#:~:text=Push%E2%80%93pull%20technology%20is%20an,often%20infested%20by%20stem%20borers.

Push Pull Technique In Integrated Pest Management

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