Gelatin encapsulation of chloropicrin and 1,3-dichloropropene as fumigants for soilborne diseases in the greenhouse cultivation of cucumber and tomato

doi:10.1016/S2095-3119(16)61623-4

Journal of Integrative Agriculture ›› 2017, Vol. 16 ›› Issue (08): 1758-1766.DOI: 10.1016/S2095-3119(16)61623-4

收稿日期:2016-08-31 出版日期:2017-08-20 发布日期:2017-08-02

Gelatin encapsulation of chloropicrin and 1,3-dichloropropene as fumigants for soilborne diseases in the greenhouse cultivation of cucumber and tomato

YAN Dong-dong¹, WANG Qiu-xia¹, LI Yuan¹, OUYANG Can-bin¹, GUO Mei-xia¹, Jim Xinpei Huang², John Busacca², Jong Neng Shieh², Alisa Ye Yu², Phil Howard², Don Williams², CAO Ao-cheng¹

¹ Key Laboratory of Integrated Pest Management in Crops, Ministry of Agriculture/Institute of Plant Protection, Chinese Academy of Agricultural Sciences, Beijing 100193, P.R.China
² Dow AgroSciences, R&D, Indianapolis 46268, United States

Received:2016-08-31 Online:2017-08-20 Published:2017-08-02
Contact: Correspondence CAO Ao-cheng, Tel: +86-10-62815940, Fax: +86-10-62894863, E-mail: caoac@vip.sina.com
About author:YAN Dong-dong, E-mail: 13260176634@163.com;
Supported by:
The authors are grateful to the financial support from the projects of Dow AgroSciences, Ministry of Agriculture of China (2110402), and the Beijing Agriculture Innovation Consortium (BAIC01-2017) over the years.

摘要/Abstract

Abstract: Combined use of chloropicrin (Pic) and 1,3-dicloropropene (1,3-D) is as effective as methyl bromide (MB) at controlling soilborne diseases in many trials and commercial uses. However, Pic and 1,3-D are both highly volatile and may pose strong exposure risks to humans and the environment. A gelatin capsule formulation containing Pic and 1,3-D has been developed to reduce exposure risks to workers and bystanders and improved application safety. We conducted two experiments in tomato and cucumber greenhouses located in Beijing and Qingdao, China, to study the efficacy of Pic plus 1,3-D gelatin capsules applied at different dosages and soil depths. Results indicated that both injection and gelatin capsules of Pic plus 1,3-D provided good control of soil nematodes and reduced disease index of Fusarium wilt and root-knot nematode. Plant yield of tomato and cucumber treated with gelatin capsules was similar to MB treatment. Based on our results, gelatin capsules applied at a soil depth of 15 cm provided better control of soilborne diseases and led to higher fruit yield compared to an application depth of 5 cm. In conclusion, a gelatin capsule of Pic plus 1,3-D is a promising and novel formulation, which not only shows good efficacy in controlling soilborne diseases, but also reduces potential exposure risks of fumigants.

Key words: soil fumigation , chloropicrin , 1,3-dichloropropene , gelatin capsule formulation , efficacy , application depth

. [J]. Journal of Integrative Agriculture, 2017, 16(08): 1758-1766.

YAN Dong-dong, WANG Qiu-xia, LI Yuan, OUYANG Can-bin, GUO Mei-xia, Jim Xinpei Huang, John Busacca, Jong Neng Shieh, Alisa Ye Yu, Phil Howard, Don Williams, CAO Ao-cheng . Gelatin encapsulation of chloropicrin and 1,3-dichloropropene as fumigants for soilborne diseases in the greenhouse cultivation of cucumber and tomato[J]. Journal of Integrative Agriculture, 2017, 16(08): 1758-1766.

参考文献

Abdel-Monaim M F, Abo-Elyousr K A M, Morsy K M. 2011. Effectiveness of plant extracts on suppression of damping-off and wilt diseases of lupine (Lupinus termis Forsik). Crop Protection, 30, 185–191.

Ajwa H A, Trout T. 2004. Drip application of alternative fumigants to methyl bromide for strawberry production. HortScience, 39, 1707–1715.

Alfonso Cabrera J, Wang D, Schneider S M, Hanson B D. 2011. Subsurface drip application of alternative fumigants to methyl bromide for controlling nematodes in replanted grapevines. Pest Management Science, 68, 773–780.

Barker K R, Nusbaum C J, Nelson L A. 1969. Effects of storage temperature and extraction procedure on recovery of plant-parasitic nematodes from field soils. Journal of Nematology, 1, 240–247.

De Cal A, Martinez-Treceño A, Lopez-Aranda J M, Melgarejo P. 2004. Chemical alternatives to methyl bromide in Spanish strawberry nurseries. Plant Disease, 88, 210–214.

De Cal A, Martinez-Treceño A, Salto T, López-Aranda J M, Melgarejo P. 2005. Effect of chemical fumigation on soil fungal communities in Spanish strawberry nurseries. Applied Soil Ecology, 28, 47–56.

Cardoso J E, Santos A A, Rossetti A G, Vidal J C. 2004. Relationship between incidence and severity of cashew gummosis in semiarid north-eastern Brazil. Plant Pathology, 53, 363–367.

Covarelli L, Pannacci E, Beccari G, D’Errico F P, Tosi L. 2010. Two-year investigations on the integrated control of weeds and root parasites in Virginia bright tobacco (Nicotiana tabacum L.) in central Italy. Crop Protection, 29, 783–788.

Csinos A S, Sumner D R, Johnson W C, Johnson A W, McPherson R M, Dowler C C. 2000. Methyl bromide alternatives in tobacco, tomato and pepper transplant production. Crop Protection, 19, 39–49.

Dabrowski K, Hinterleitner S. 1989. Applications of a simultaneous assay of ascorbic acid, dehydroascorbic acid and ascorbic sulphate in biological materials. Analyst, 114, 83–87.

Díaz-Pérez M, Camacho-Ferre F, Diánez-Martínez F, Cara-García M, Tello-Marquina J C. 2008. Evaluation of alternatives to methyl bromide in melon crops in Guatemala. Microbial Ecology, 57, 379–383.

Gilreath J. 2004. Methyl bromide alternatives for weed and soilborne disease management in tomato (Lycopersicon esculentum). Crop Protection, 23, 1193–1198.

Gilreath J P, Santos B M, Busacca J D, Eger Jr J E, John M M, Gilreath P R. 2006. Validating broadcast application of Telone C-35 complemented with chloropicrin and herbicides in commercial tomato farms. Crop Protection, 25, 79–82.

Komada H. 1975. Development of a selective medium for quantitative isolation of Fusarium oxysporum from natural soil. Review of Plant Protection Research, 8, 115–125.

Lembright H W. 1990. Soil fumigation: principles and application technology. Journal of Nematology, 22, 632–644.

Li Y, Mao L, Yan D, Ma T, Shen J, Guo M, Wang Q, Ouyang C, Cao A. 2014. Quantification of Fusarium oxysporum in fumigated soils by a newly developed real-time PCR assay to assess the efficacy of fumigants for Fusarium wilt disease in strawberry plants. Pest Management Science, 70, 1669–1675.

Mao L, Wang Q, Yan D, Xie H, Li Y, Guo M, Cao A. 2012. Evaluation of the combination of 1,3-dichloropropene and dazomet as an efficient alternative to methyl bromide for cucumber production in China. Pest Management Science, 68, 602–609.

Mao L, Yan D, Wang Q, Li Y, Ouyang C, Liu P, Shen J, Guo M, Cao A. 2014. Evaluation of the combination of dimethyl disulfide and dazomet as an efficient methyl bromide alternative for cucumber production in China. Journal of Agricultural and Food Chemistry, 62, 4864–4869.

Masago H, Yoshikawa M, Fukada M, Nakanishi N. 1977. Selective inhibition of Pythium spp. on a medium for direct isolation of Phytophthora spp. from soils and plants. Phytopathology, 67, 425–428.

MBTOC (Methyl Bromide Technical Options Committee). 2010. Report of the Methyl Bromide Technical Options Committee. United Nations Environment Programme Ozone Secretariat, Nairobi.

Minuto A, Gullino M, Lamberti F, Daddabbo T, Tescari E, Ajwa H, Garibaldi A. 2006. Application of an emulsifiable mixture of 1,3-dichloropropene and chloropicrin against root knot nematodes and soilborne fungi for greenhouse tomatoes in Italy. Crop Protection, 25, 1244–1252.

Ristaino J B, Thomas W. 1997. Agriculture, methyl bromide, and the ozone hole: Can we fill the gaps? Plant Disease, 81, 964–977.

Ruzo L O. 2006. Physical, chemical and environmental properties of selected chemical alternatives for the pre-plant use of methyl bromide as soil fumigant. Pest Management Science, 62, 99–113.

Santos B, Gilreath J, Motis T, Noling J, Jones J, Norton J. 2006. Comparing methyl bromide alternatives for soilborne disease, nematode and weed management in fresh market tomato. Crop Protection, 25, 690–695.

Somani B L, Khanade J, Sinha R. 1987. A modified anthrone-sulfuric acid method for the determination of fructose in the presence of certain proteins. Analytical Biochemistry, 167, 327–330.

Wang Q, Song Z, Tang J, Yan D, Wang F, Zhang H, Guo M, Cao A. 2009b. Efficacy of 1,3-dichloropropene gelatin capsule formulation for the control of soilborne pests. Journal of Agricultural and Food Chemistry, 57, 8414–8420.

Wang Q, Tang J, Wei S, Wang F, Yan D, Mao L, Guo M, Cao A. 2009a. 1,3-Dichloropropene distribution and emission after gelatin capsule formulation application. Journal of Agricultural and Food Chemistry, 58, 361–365.

Wang Q, Wang D, Tang J, Yan D, Zhang H, Wang F, Guo M, Cao A. 2010. Gas-phase distribution and emission of chloropicrin applied in gelatin capsules to soil columns. Journal of Environmental Quality, 39, 917–922.

Yan D, Wang Q, Mao L, Xie H, Guo M, Cao A. 2012. Evaluation of chloropicrin gelatin capsule gormulation as a soil fumigant for greenhouse strawberry in China. Journal of Agricultural and Food Chemistry, 60, 5023–5027.

Yates S R, Gan J, Papiernik S K, Dungan R, Wang D. 2002. Reducing fumigant emissions after soil application. Phytopathology, 92, 1344–1348.

Gelatin encapsulation of chloropicrin and 1,3-dichloropropene as fumigants for soilborne diseases in the greenhouse cultivation of cucumber and tomato

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics