Review on integrated disease and pest management of field crops
Tóm tắt
The evolution of IPM was followed multiple ways around the world and reached beyond the confines of the plant protection science. Excessive use of chemicals in disease and pest management has caused environmental and health problems, loss of biodiversity, and human disorders. Pests and diseases are pushing the boundaries of their biology, etiology, ecology, and crop production. Improvised techniques of integrated management play an important role in minimizing the use of chemicals. Integrated management of diseases and pests has been done successfully with the help of technology times to present with many success stories, but still in some underdeveloped countries, farmers are still reluctant to adopt integrated management because of their socio-economic behavior. Developed countries like America, Russia, Australia and Africa have made many expansions to develop sustainable IPM systems. The review in this article has focused on controlling diseases and insects through integrated management. There is a lot of diversity among diseases and pests from region to region. The focus in this article was emphasized on cultural, physical/ mechanical, biological and chemical control of integrated management. Benefits and limitations were discussed to analyse the conventional farming system. This information will be helpful to devise an effective model of disease and pest integrated management. Because understanding an epidemic is critical to implementing effective IPM control strategies, the relationship between pest, disease, and their epidemiology is long-term. This approach has proved effective for harmonious and sustainable agriculture.
Tài liệu tham khảo
Abate T, van Huis A, Ampofo JK (2000) Pest management strategies in traditional agriculture: an African perspective. Ann Rev Entomol 45:631–659. doi:https://doi.org/10.1146/annurev.ento.45.1.631
Anthony D (2013) Florida predatory stink bug, Euthyrhynchus floridanus (Linnaeus) https://entnemdept.ufl.edu/
Antignus Y (2014) Management of air-borne viruses by “optical barriers” in protected agriculture and open-field crops. Advanc Virus Res 90:1–33
Archer T, Losade J, Bynum E Jr (1990) Influence of planting date on abundance of panicle-feeding insects associated with sorghum. J Agricul Entomol 7(3):233–239
Bacmaga M, Kucharski J, Wyszkowska J (2015) Microbial and enzymatic activity of soil contaminated with azoxystrobin. Environ Monit Assessm 187(10):1–15
Balogh B, Jones JB, Iriarte F, Momol M (2010) Phage therapy for plant disease control. Curr Pharma Biotech 11(1):48–57
Barnhoorn I, van Dyk C (2020) The first report of selected herbicides and fungicides in water and fish from a highly utilized and polluted freshwater urban impoundment. Environ Sci Pollu Res 27(26):393–398
Barzman M et al (2015) Eight principles of integrated pest management. Agron for Sustain Develop 35(4):1199–1215
Beers EH et al (2016) Nontarget effects of orchard pesticides on natural enemies: lessons from the field and laboratory. Biol Contr 102:44–52
Birkett MA et al (2000) New roles for cis-jasmone as an insect semiochemical and in plant defense. Proce Nati Acad Sci 97(16):9329–9334
Blandino M, Haidukowski M, Pascale M, Plizzari L, Scudellari D, Reyneri A (2012) Integrated strategies for the control of Fusarium head blight and deoxynivalenol contamination in winter wheat. Field Crops Res 133:139–149
Bravo A, Likitvivatanavong S, Gill SS, Soberón M (2011) Bacillus thuringiensis: a story of a successful bioinsecticide. Ins Biochem Mole Biol 41(7):423–431
Buchel K et al (2011) How plants give early herbivore alert: volatile terpenoids attract parasitoids to egg-infested elms. Basic Appl Ecol 12(5):403–412
Colmenarez Y, Vásquez C, Corniani N, Franco J (2016) Implementation and adoption of integrated pest management approaches in Latin America: challenges and potential.Licensee InTech Chap.1p 1–18
Coulson JR, Vail P, Dix M, Nordlund D, Kauffman W (2000) 110 years of biological control research and development in the United States Department of Agriculture. USDA ARS Admin
Cruz-Lacierda ER, Erazo-Pagador GE (2001) Physical, environmental, and chemical methods of disease prevention and control Health Management in Aquaculture. Aquaculture Department, Southeast Asian Fisheries Development Center, pp 97–110
Dahlsten D, Six D, Rowney D, Lawson A, Erbilgin N, Raffa K (2004) Attraction of Ips pini (Coleoptera: Scolytinae) and its predators to natural attractants and synthetic semiochemicals in northern California: Implications for population monitoring. Environ Entomol 33(6):1554–1561
Dahshan H, Megahed AM, Abd-Elall AMM, Abd-El-Kader MA-G, Nabawy E, Elbana MH (2016) Monitoring of pesticides water pollution-the Egyptian River Nile. J Environ Health Sci Engine 14(1):1–9
Dara SK, Peck D, Murray D (2018) Chemical and non-chemical options for managing twospotted spider mite, western tarnished plant bug and other arthropod pests in strawberries. Insects 9(4):156
De Jensen CE, Percich J, Graham P (2002) Integrated management strategies of bean root rot with Bacillus subtilis and Rhizobium in Minnesota. Field Crops Res 74(2–3):107–115
Deliopoulos T, Kettlewell PS, Hare MC (2010) Fungal disease suppression by inorganic salts: a review. Crop Protec 29(10):1059–1075
Dhaliwal GS, Koul O, Cuperus GW (2004) Integrated pest management potential, constraints and challenges.CAB International. p1–20
Dhawan A et al (2007) Incidence and damage potential of mealybug, Phenacoccus solenopsis T. on cotton in Punjab. Indian J Ecol 34(2):166–172
Dillon M, MacKinnon L (2002) Using light traps to suppress Helicoverpa. The Australian cottongrower 23(2):32
Dordas C (2008) Role of nutrients in controlling plant diseases in sustainable agriculture. A review. Agron Sustain Develop 28(1):33–46
Ehi-Eromosele C, Nwinyi O, Ajani OO (2013) Integrated pest management, Chap. 5. Licensee InTech
El-Sayed AS, Ali GS (2020) Aspergillus flavipes is a novel efficient biocontrol agent of Phytophthora parasitica. Biol Contr 140:104072
El-Shafie HAF (2018) Integrated Insect Pest Management In: Pests Control Acarology, Chap. 1
Faleiro J (2006) A review of the issues and management of the red palm weevil Rhynchophorus ferrugineus (Coleoptera: Rhynchophoridae) in coconut and date palm during the last one hundred years. Inter J Trop Inse Sci 26(3):135–154
Falloon RE (2008) Control of powdery scab of potato: Towards integrated disease management. Amer J of Potato Res 85(4):253–260
Funderburk J, Olson S, Stavisky J, Avila Y (2004) Managing thrips and Tomato Spotted Wilt in pepper. http://edis.ifas.ufl.edu/IN401, UF/IFAS EDIS pub. ENY-658
Gan Y, Siddique K, MacLeod W, Jayakumar P (2006) Management options for minimizing the damage by ascochyta blight (Ascochyta rabiei) in chickpea (Cicer arietinum L.). Field Crops Research 97(2–3):121–134
Geier P, Clark L (1961) An ecological approach to pest control. In: Proceedings of the eighth technical meeting International Union of Conservation of Nature and Natural Resources, Warsaw, p 10–18
Ghorbani R, Wilcockson S, Koocheki A, Leifert C (2009) Soil management for sustainable crop disease control: a review Part of the Sustainable Agriculture Reviews book series (SARV), Organic farming, pest control remediation of soil pollutants. vol 1, p 177–201
Gilreath J, Santos B, Mirusso J, Noling J, Gilreath P (2005) Application Considerations for Successful Use of VIF and Metalized Mulches with Reduced Fumigant Rates in Tomato. http://edis.ifas.ufl.edu/HS270, UF/IFAS EDIS pub. HS270, 8/2005
Giovannetti M, Turrini A, Strani P, Sbrana C, Avio L, Pietrangeli B (2006) Mycorrhizal fungi in ecotoxicological studies: soil impact of fungicides, insecticides and herbicides. Preven Today 2(1–2):47–61
Gogo EO, Saidi M, Ochieng JM, Martin T, Baird V, Ngouajio M (2014) Microclimate modification and insect pest exclusion using agronet improve pod yield and quality of French bean. Horti Sci 49(10):1298–1304
Gomes YCB, Dalchiavon FC, Valadao FCdA (2017) Joint use of fungicides, insecticides and inoculants in the treatment of soybean seeds. Revista Ceres 64(3):258–265
Gorska-Drabik E, Golan K, Cwiklinska M (2011) Effectiveness of coloured sticky traps in monitoring of Ctenosciara hyalipennis (Diptera: Sciaridae) on exotic plant species in greenhouse. Acta Scientiarum Polonorum Hortorum Cultus 10(3):209–219
Gurr GM, You M (2016) Conservation biological control of pests in the molecular era: new opportunities to address old constraints. Front Pl Sci 6:1255
Hansen J, Johnson J, Winter D (2011) History and use of heat in pest control: a review. Inter J Pest Manag 57(4):267–289
Heimpel GE, Mills NJ (2017) Biological control. Cambridge University Press
Holb I (2005) Effect of pruning on apple scab in organic apple production. Plant Dise 89(6):611–618
Howell C (2003) Mechanisms employed by Trichoderma species in the biological control of plant diseases: the history and evolution of current concepts. Plant Dise 87(1):4–10
Jarvis WR (1992) Managing diseases in greenhouse crops, vol 288. Aps press St. Paul
Johansen C et al (2008) Integrated crop management of chickpea in environments of Bangladesh prone to Botrytis grey mould. Field Crops Res 108(3):238–249
Joyce K (2019) How to kill Eucalyptus tree. https://www.ehow.co.uk/how_7499101_kill-eucalyptus-tree.html
Junaid JM, Dar NA, Bhat TA, Bhat AH, Bhat MA (2013) Commercial biocontrol agents and their mechanism of action in the management of plant pathogens. Inter J Moder Pl Anim Sci 1(2):39–57
Katan J (2000) Physical and cultural methods for the management of soil-borne pathogens. Crop Protec 19(8–10):725–731
Kelly JL, Hagler JR, Kaplan I (2014) Semiochemical lures reduce emigration and enhance pest control services in open-field predator augmentation. Biol Contr 71:70–77
Komarek M, Cadkova E, Chrastny V, Bordas F, Bollinger J-C (2010) Contamination of vineyard soils with fungicides: a review of environmental and toxicological aspects. Environ Intern 36(1):138–151
Kutcher H, Malhi S (2010) Residue burning and tillage effects on diseases and yield of barley (Hordeum vulgare) and canola (Brassica napus). Soil Tillage Res 109(2):153–160
Kyei-Boahen S, Slinkard A, Walley F (2001) Rhizobial survival and nodulation of chickpea as influenced by fungicide seed treatment. Can J Microbiol 47(6):585–589
Lacey L, Grzywacz D, Shapiro-Ilan D, Frutos R, Brownbridge M, Goettel M (2015) Insect pathogens as biological control agents: back to the future. J Inverteb Pathol 132:1–41
Lamichhane JR, You MP, Laudinot V, Barbetti MJ, Aubertot J-N (2020) Revisiting sustainability of fungicide seed treatments for field crops. Plant Dise 104(3):610–623
Lucas J, Solano BR, Montes F, Ojeda J, Megias M, Manero FG (2009) Use of two PGPR strains in the integrated management of blast disease in rice (Oryza sativa) in Southern Spain. Field Crops Res 114(3):404–410
Mahmood I, Imadi SR, Shazadi K, Gul A, Hakeem KR (2016) Effects of pesticides on environment Plant, soil and microbes. Springer, pp 253–269
McBeath JH, McBeath J (2010) Plant diseases, pests and food security Environmental Change and Food Security in China. Springer, p 117–156
McRobert N, Hughes G, Savary S (2003) Integrated approaches to understanding and control of diseases and pests in field crops. Austr Pl Pathol 32(2):167–180
Michereff MF, Michereff Filho M, Blassioli-Moraes M, Laumann RA, Diniz IR, Borges M (2015) Effect of resistant and susceptible soybean cultivars on the attraction of egg parasitoids under field conditions. J Appl Entomol 139(3):207–216
Mills N, Daane K (2005) Biological and cultural control, nonpesticide alternatives can suppress crop pests. Calif Agric 59(1):23–28
Nettles R et al (2016) Influence of pesticide seed treatments on rhizosphere fungal and bacterial communities and leaf fungal endophyte communities in maize and soybean. Appl Soil Ecol 102:61–69
Newitt JT, Prudence SM, Hutchings MI, Worsley SF (2019) Biocontrol of cereal crop diseases using streptomycetes. Pathogens 8(2):78
Olivier CY, Lowery DT, Stobbs LW (2009) Phytoplasma diseases and their relationships with insect and plant hosts in Canadian horticultural and field crops. Can Entomol 141(5):425–462
Orlob G (1973) Ancient and medieval plant pathology Pflanzenschutz Nachrichten Bayer, Leverkusen, Germany. p 63–294
Ozkara A, Akyıl D, Konuk M (2016) Pesticides, environmental pollution, and health. IntechOpen
Peshin R, Bandral RS, Zhang W, Wilson L, Dhawan AK (2009) Integrated pest management A global overview of history, programs and adoption. p 1–49
Radcliffe EB, Hutchison WD, Cancelado RE (2009) Integrated pest management: concepts, tactics, strategies and case studies. Cambridge University Press
Rathore HS, Nollet LM (2012) Pesticides: evaluation of environmental pollution. CRC press, Amazon.com
Rezaei R, Safa L, Damalas CA, Ganjkhanloo MM (2019) Drivers of farmers’ intention to use integrated pest management: Integrating theory of planned behavior and norm activation model. J Environ Manag 236:328–339
Sharma A et al (2020) Global trends in pesticides: A looming threat and viable alternatives. Ecotoxicol Environ Saf 201:110812
Singh S (2004) Some success stories in classical biological control of agricultural pests in India. Asia-Pacific Association of Agricultural Research Institutions (APAARI), FAO, pp 1–80
Singh VK, Chawla S (2012) Cultural Practices: An Ecofriendly Innovative Approach in Plant Disease Management. In: V.K. Singh YSaAS (ed). International Book Publishers and Distributers, Dehradun – 248 001 (India), p 01–20
Stenberg JA (2017) A conceptual framework for integrated pest management. Trends Pl Sci 22:749–769
Stephenson GR, Coats J, Yamamoto H (2000) Pesticide use and world food production: risks and benefits. In, Proceedings of the 2000 National Meeting - Expert Committee on Weeds. Canadian Weed Science Society, p 9–15
Tudi M et al (2021) Agriculture development, pesticide application and its impact on the environment. Inter J Environ Res Pub Heal 18(3):1112
Van Driesche R, Bellows TS Jr (2012) Biological control. Springer Science & Business Media
Wilhoit L (2018) History of pesticide use reporting in California Managing and Analyzing Pesticide Use Data for Pest Management, Environmental Monitoring, Public Health, and Public Policy. ACS Publications, pp 3–14
Wollaeger H, Smitley D, Cloyd R (2015) Commercially available biological control agents for common greenhouse insect pests.Exten Bulle(3299):1–8
Wyatt TD, Phillips AD, Gregoire JC (1993) Turbulence, trees and semiochemicals: wind-tunnel orientation of the predator, Rhizophagus grandis, to its barkbeetle prey, Dendroctonus micans. Physiol Entomol 18(2):204–210
Zhang W (2018) Global pesticide use: profile, trend, cost/benefit and more. Proce Inter Acad Ecol Environ Sci 8(1):1
Ziaei Madbouni MA, Samih MA, Qureshi JA, Biondi A, Namvar P (2017) Compatibility of insecticides and fungicides with the zoophytophagous mirid predator Nesidiocoris tenuis. PLoS ONE 12(11):e0187439