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Post-harvest insect infestation in maize grain stored in woven polypropylene and in hermetic bags

Published online by Cambridge University Press:  01 March 2013

Kukom Edoh Ognakossan
Affiliation:
Ecole Supérieure d'Agronomie, Université de Lomé, BP1515, Lomé, Togo International Institute of Tropical Agriculture (IITA), BP 08-0932 Tri Postal Cotonou, Republic of Benin
Agbéko Kodjo Tounou
Affiliation:
Ecole Supérieure d'Agronomie, Université de Lomé, BP1515, Lomé, Togo
Yendouban Lamboni
Affiliation:
International Institute of Tropical Agriculture (IITA), BP 08-0932 Tri Postal Cotonou, Republic of Benin
Kerstin Hell*
Affiliation:
International Institute of Tropical Agriculture (IITA), BP 08-0932 Tri Postal Cotonou, Republic of Benin
*
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Abstract

Maize was artificially infested with either 10 or 25 individual Prostephanus truncatus (Horn) and Sitophilus zeamais (Motschulsky) or a mixture of both, and stored in a hermetic grain bag (HGB) or a woven polypropylene bag (WPB) for 150 days. Population growth of P. truncatus and S. zeamais during storage was low in HGB, while in WPB, the insect population increased significantly with storage duration. Mortality rate during storage was significantly higher in HGB than in WPB. After 60 days of storage, the average mortality rate of 99.50% was observed in HGB infested with 25 P. truncatus, and 100% for S. zeamais at the same infestation density after 90 days of storage. Grain losses were significantly lower in HGB compared with WPB. Less than 0.5 and 6.0% losses were obtained, respectively, for S. zeamais and P. truncatus in HGB infested with 25 individual insects after 150 days of storage, whereas losses of 19.2% (infestation with S. zeamais) and 27.1% (infestation with P. truncatus) were observed in WPB. HGB seems to be resistant to the perforation of S. zeamais, but not to P. truncatus. The moisture content of maize grains stored in HGB remained practically the same during storage, compared with the levels in WPB, which reduced with storage time. WPB could be used for maize storage, protecting it against insect infestation without the need for insecticide use.

Type
Research Papers
Copyright
Copyright © ICIPE 2013

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References

Abebe, F., Tefera, T., Mugo, S., Beyene, Y. and Vidal, S. (2009) Resistance of maize varieties to the maize weevil Sitophilus zeamais (Motsch.) (Coleoptera: Curculionidae). African Journal of Biotechnology 8, 59375943.Google Scholar
Bailey, S. W. and Banks, H. J. (1980) A review of recent studies of the effects of controlled atmospheres on stored product pests, pp. 101118. In Controlled Atmosphere Storage of Grains. Proceedings of an International Symposium held from 12 to 15 May 1980, at Castelgandolfo (Rome) Italy (edited by Shejbal, J.). Elsevier Scientific Publishing Company, Amsterdam.Google Scholar
Baoua, I. B., Margam, V., Amadou, L. and Murdock, L. L. (2012) Performance of triple bagging hermetic technology for postharvest storage of cowpea grain in Niger. Journal of Stored Products Research 51, 8185.Google Scholar
Baributsa, D., Lowenberg-DeBoer, J., Murdock, L. and Moussa, D. (2010) Profitable chemical-free cowpea storage technology for smallholder farmers in Africa: Opportunities and challenges. Julius-Kühn-Archiv 425, 10461052. doi: 10.5073/jka.2010.425.340.Google Scholar
Ben, D. C., Liem, P. V., Dao, N. T., Gummert, M. and Rickman, J. F. (2006) Effect of hermetic storage in the super bag on seed quality and on milled rice quality of different varieties in Bac Lieu, Vietnam. International Rice Research Notes 31, 5556.Google Scholar
Borgemeister, C., Holst, N. and Hodges, R. J. (2003) Biological control and other pest management options for larger grain borer Prostephanus truncatus, pp. 311328. In Biological Control in IPM Systems in Africa (edited by Neuenschwander, P., Borgemeister, C. and Langewald, J.). CAB International, Wallingford.Google Scholar
Boxall, R. A. (1986) A Critical Review of the Methodology for Assessing Farm-Level Grain Losses After Harvest. TDRI, Slough. 139 pp.Google Scholar
Boxall, R. A. (2002) Damage and loss caused by the larger grain borer Prostephanus truncatus. Integrated Pest Management Reviews 7, 105121.Google Scholar
Chabi-Olaye A., Borgemeister C., Nolte C., Schulthess F., Gounou S., Ndemah R. and Sétamou M. (2005) Role of habitat management technologies in the control of stem and cob borers in sub-Saharan Africa, pp. 167–184. In Second International Symposium on Biological Control of Arthropods, held 12–16 September 2005, Davos, Switzerland. USDA Forest Service, Publication FHTET-2005-08.Google Scholar
Compton, J. A. F., Floyd, S., Magrath, P. A., Addo, S., Gbedevi, S. R., Agbo, B., Bokor, G., Amekupe, S., Motey, Z., Penni, H. and Kumi, S. (1998) Involving grain traders in determining the effect of post-harvest insect damage on the price of maize in African markets. Crop Protection 17, 483489.CrossRefGoogle Scholar
Cowley, R. J., Howard, D. C. and Smith, R. H. (1980) The effect of grain stability on damage caused by Prostephanus truncatus (Horn) and three other beetle pests of stored maize. Journal of Stored Products Research 16, 7578.Google Scholar
Danho, M., Haubruge, E., Gaspar, C. and Lognay, G. (2000) Selection of grain-hosts by Prostephanus truncatus (Coleoptera, Bostrychidae) in the presence of Sitophilus zeamais (Coleoptera, Curculionidae) previously infested grains. Belgian Journal of Zoology 130, 3039.Google Scholar
De Dios, C. V., Cosico, M. F. A., Julian, D. D., Dator, J. V., Martinez, M. E. and Tiongson, R. L. (2001) Adoption of hermetic storage on milled rice using the Volcani Cube® in the Philippines, pp. 251260. In Proceedings of an International Conference on Controlled Atmosphere and Fumigation in Stored Products, 29 October–3 November 2000, Fresno, USA (edited by Donahaye, E. J., Navarro, S. and Leesch, J. G.). Executive Printing Services, Clovis, CA. http://www.ftic.co.il/2000FresnoPDF/25.pdf.Google Scholar
Donahaye, E. J. and Navarro, S. (2000) Comparisons of energy reserves among strains of Tribolium castaneum selected for resistance to hypoxia and hypercarbia, and the unselected strain. Journal of Stored Products Research 36, 223234.Google Scholar
Giga, D. P. and Canhao, S. J. (1993) Competition between Prostephanus truncatus (Horn) and Sitophilus zeamais (Motsch.) in maize at two temperatures. Journal of Stored Products Research 29, 6370.CrossRefGoogle Scholar
Golob, P. (2002) Chemical, physical and cultural control of Prostephanus truncatus. Integrated Pest Management Reviews 7, 245277.Google Scholar
Lamboni, Y. and Hell, K. (2009) Propagation of mycotoxigenic fungi in maize stores by post-harvest insects. International Journal of Tropical Insect Science 29, 3139.Google Scholar
Li L. (1988) Behavioral ecology and life history evolution in the larger grain borer, Prostephanus truncatus (Horn). PhD thesis, University of Reading. 229 pp.Google Scholar
Meikle, W. G., Adda, C., Azoma, K., Borgemeister, C., Degbey, P., Djomamou, B. and Markham, R. H. (1998) Varietal effects on the density of Prostephanus truncatus (Horn) (Col.: Bostrichidae) and Sitophilus zeamais Motsch. (Col.: Curculionidae) in grain stores in Benin Republic. Journal of Stored Products Research 34, 4558.Google Scholar
Meikle W. G., Degbey P., Oussou R., Holst N., Nansen C. and Markham R. H. (1999) Pesticide use in grain stores: an evaluation based on survey data from Benin. PhAction News 1, 5–9. Available at: http://www.iita.org/info/phnews/phcontent.htm.Google Scholar
Meikle, W. G., Rees, D. and Markham, R. H. (2002) Biological control of the larger grain borer, Prostephanus truncatus (Horn) (Coleoptera: Bostrichidae). Integrated Pest Management Reviews 7, 123138.Google Scholar
Moreno, M. E., Jimenez, A. S. and Vazquez, M. E. (2000) Effect of Sitophilus zeamais and Aspergillus chevalieri on the oxygen level in maize stored hermetically. Journal of Stored Products Research 36, 2536.Google Scholar
Murdock, L. L., Margam, V., Baoua, I., Balfe, S. and Shade, R. E. (2012) Death by desiccation: effects of hermetic storage on cowpea bruchids. Journal of Stored Products Research 49, 166170.Google Scholar
Murdock, L. L., Seck, D., Ntoukam, G., Kitch, L. and Shade, R. E. (2003) Preservation of cowpea grain in sub-Saharan Africa – bean/cowpea CRSP contributions. Field Crops Research 82, 169178.Google Scholar
Nansen, C. and Meikle, W. G. (2002) The biology of the larger grain borer, Prostephanus truncatus (Horn) (Coleoptera: Bostrichidae). Integrated Pest Management Reviews 7, 91104.Google Scholar
NGI (New Growth International) (2009) Science and Innovation for African Agricultural Value Chains: Lessons Learned in Transfer of Technologies to Smallholder Farmers in Sub-Saharan Africa. Available at: http://merid.org/~/media/Files/Projects/Value%20Chains%20Microsite/Value_Chain_Innovations_-_Lessons_learned_091007.ashx.Google Scholar
Obeng-Ofori, D. and Reichmuth, C. (1999) Plant oils as potentiation agents of monoterpenes for protection of stored grains against damage by stored products beetle pests. International Journal of Pest Management 45, 155159.Google Scholar
Oxley, T. A. and Wickenden, G. (1963) The effect of restricted air supply on some insects which infest grain. Annals of Applied Biology 51, 313324.Google Scholar
PACN (Pan Africa Chemistry Network) (2010) Africa's water quality: a chemical science perspective. Joint Royal Society of Chemistry and Syngenta UK Report. March 2010.Google Scholar
Rickman, J. F. and Aquino, E. (2007) Appropriate technology for maintaining grain quality in small-scale storage, pp. 149157. In Proceedings of an International Conference on Controlled Atmosphere and Fumigation in Stored Products, 8–13 August 2004, Gold-Coast, Australia (edited by Donahaye, E. J., Navarro, S., Bell, C., Jayas, D., Noyes, R. and Phillips, T. W.). FTIC Publishing Ltd, Israel. http://www.ftic.co.il/2004gold-coastPDF/IS3.2.pdf.Google Scholar
SPSS (2007) SPSS Version 16 for Windows. SPSS Incorporated, Chicago, IL.Google Scholar
Thamaga-Chitja, J. M., Hendriks, S. L., Ortmann, G. F. and Green, M. (2004) Impact of maize storage on rural household food security in Northern Kwa-Zulu-Natal. Tydskrif vir Gesinsekologie en Verbruikerswetenskappe 32, 815.Google Scholar
Varnava, A., Navarro, S. and Donahaye, E. (1995) Long-term hermetic storage of barley in PVC-covered concrete platforms under Mediterranean conditions. Postharvest Biology and Technology 6, 177186.Google Scholar
Yuya, A., Tadesse, A., Azerefegne, F. and Tefera, T. (2009) Efficacy of combining Niger seed oil with malathion 5% dust formulation on maize against the maize weevil, Sitophilus zeamais (Coleoptera: Curculionidae). Journal of Stored Products Research 45, 6770.Google Scholar
Zia-Ur-Rehman, (2006) Storage effects on nutritional quality of commonly consumed cereals. Food Chemistry 95, 5357.Google Scholar