Abstract
Rice is a globally significant staple cereal for which cultivation is concentrated in developing countries and, to a large extent, in smallholder farms. There is significant potential for operator exposure to pesticides during such rice production, but research to date is fragmented. This review evaluates methods and outcomes of studies to quantify pesticide exposure amongst rice growers in developing countries. Knapsack sprayers are used very frequently in rice cultivation, but existing exposure estimation methods lack the functionality to generate robust estimates of exposure. Direct measurement methods have been applied in a range of developing countries to measure dermal contact and/or respiratory inhalation during pesticide handling activities, and these have sometimes been coupled with biological monitoring for exposure. Only a few studies have collected contextual information in parallel with exposure assessment, using interviews or questionnaires to capture information on agricultural practices and personal protective measures. There is general agreement that dermal exposure is likely to be larger than inhalation exposure, with dermal contact exacerbated by risk factors including crop structure, maintenance status of equipment, and use of any personal protective equipment. There is frequent use within the reviewed studies of pesticide active substances that have been restricted in other parts of the world. Overall, there is an urgent need for more systematic studies to address gaps in knowledge and improve exposure estimates for use in health analysis and risk assessment.
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References
Abdollahzadeh G, Sharifzadeh MS, Damalas CA (2015) Perceptions of the beneficial and harmful effects of pesticides among Iranian rice farmers influence the adoption of biological control. Crop Prot 75:124–131
Anyusheva M, Lamers M, La N, Nguyen VV, Streck T (2016) Persistence and leaching of two pesticides in a paddy soil in Northern Vietnam. Clean—Soil, Air, Water 44(7):858–866
Atabila A, Phung DT, Hogarh JN et al (2017) Dermal exposure of applicators to chlorpyrifos on rice farms in Ghana. Chemosphere 178:350–358
Atabila A, Phung DT, Hogarh JN et al (2018a) Assessment of dermal exposure to chlorpyrifos among applicators on rice farms in Ghana. Chemosphere 203:83–89
Atabila A, Sadler R, Phung DT et al (2018b) Biomonitoring of chlorpyrifos exposure and health risk assessment among applicators on rice farms in Ghana. Environ Sci Pollut Res 25:20854–20867
Atabila A, Phung DT, Sadler R, Connell D, Chu C (2019) Comparative evaluation of chlorpyrifos exposure estimates from whole-body dermal dosimetry and urinary trichloro-2-pyridinol (TCP) methods. Ecotoxicol Environ Saf 172:439–443
Baharuddin MR, Sahid I, Noor MMA, Sulaiman N, Othman F (2011) Pesticide risk assessment: a study on inhalation and dermal exposure to 2,4-D and paraquat among Malaysian paddy farmers. J Environ Sci Health 46:600–607
Bellinder RR, Miller AJ, Malik RK et al (2002) Improving herbicide application accuracy in South Asia. Weed Technol 16:845–850
Berenstein GA, Hughes EA, March H et al (2014) Pesticide potential dermal exposure during the manipulation of concentrated mixtures at small horticultural and floricultural production units in Argentina: the formulation effect. Sci Total Environ 472:509–516
Berg H (2001) Pesticide use in rice and rice-fish farms in the Mekong Delta, Vietnam. Crop Prot 20:897–905
Cao L, Zhang H, Li F et al (2018) Potential dermal and inhalation exposure to imidacloprid and risk assessment among applicators during treatment in cotton field in China. Sci Total Environ 624:1195–1201
Capri E, Karpouzas DG (2008) Pesticide risk assessment in rice paddies: theory and practice. Elsevier, Amsterdam and Oxford
Choi H, Moon JK, Kim JH (2013) Assessment of the exposure of workers to the insecticide imidacloprid during application on various field crops by hand-held power sprayer. J Agric Food Chem 61:10642–10648
Colosio C, Rubino FM, Alegakis A et al (2012) Integration of biological monitoring, environmental monitoring and computational modelling into the interpretation of pesticide exposure data: introduction to a proposed approach. Toxicol Lett 213:49–56
Da Silva M, Stadlinger N, Mmochi AJ, Lundborg CS, Marrone G (2016) Pesticide use and self-reported health symptoms among rice farmers in Zanzibar. J Agromed 21(4):335–344
Dasgupta S, Meisner C, Huq M (2007a) A pinch or a pint? Evidence of pesticide overuse in Bangladesh. J Agric Econ 58:91–114
Dasgupta S, Meisner C, Wheeler D, Xuyen K, Lam NT (2007b) Pesticide poisoning of farm workers—implications of blood test results from Vietnam. Int J Hyg Environ Health 210:121–132
Defra (2006) Pesticides: Code of practice for using plant protection products. Section 4: working with pesticides. https://www.hse.gov.uk/pesticides/resources/C/Code_of_Practice_for_using_Plant_Protection_Products_-_Section_4.pdf. Accessed 11 Oct 2019
ECHA (2015) Guidance for human health risk assessment. Volume III human health, part b risk assessment. Draft version 2.0. https://echa.europa.eu/documents/10162/23047722/bpr_vol_iii_partb_draft_chapter3_ca_en.pdf/04f7ba38-c55e-48a7-a1f3-e9ef0024cc23. Accessed 15 Oct 2019
ECHA (2016) Guidance on information requirements and chemical safety assessment. Chapter R. 14: Occupational exposure assessment. Version 3.0. European Chemicals Agency. https://echa.europa.eu/documents/10162/13632/information_requirements_r14_en.pdf. Accessed 21 Nov 2019
EFSA (2012) Guidance on dermal absorption EFSA panel on plant protection products and their residues (PPR). EFSA J 10(4):2665
EFSA (2014) EFSA guidance on the assessment of exposure for operators, workers, residents and bystanders in risk assessment for plant protection product. EFSA J 12(10):3874
Elahi E, Weijum C, Zhang H, Nazeer M (2019) Agricultural intensification and damages to human health in relation to agrochemicals: application of artificial intelligence. Land Use Policy 83:461–474
Epa US (1992) Guideline for exposure assessment. Risk assessment forum. U.S. Environmental Protection Agency, Washington D.C
European Commission (2011) EU reference laboratories for residues of pesticides: pesticides authorise for use on rice. National Food Institute (Denmark). https://www.eurl-pesticides.eu/docs/public/tmplt_article.asp?LabID=400&CntID=806&Theme_ID=1&Pdf=False&Lang=EN. Accessed 14 Nov 2019
Fabro L, Varca LM (2012) Pesticide usage by farmers in Pagsanjan-Lumban catchment of Laguna de Bay, Philippines. Agric Water Manag 106:27–34
FAO (2018a) Food outlook: biannual report on global food markets. http://www.fao.org/3/CA0239EN/ca0239en.pdf. Accessed 13 Oct 2019
FAO (2018b) FAO rice market monitor (RMM). Volume XXI—Issue No. 1. http://www.fao.org/economic/est/publications/rice-publications/rice-market-monitor-rmm/en/. Accessed 13 Oct 2019
Gammon DW, Liu Z, Becker JM (2011) Carbofuran occupational dermal toxicity exposure and risk assessment. Pest Manag Sci 68:362–370
Gangemi S, Miozzi E, Teodoro M et al (2016) Occupational exposure to pesticides as a possible risk factor for the development of chronic diseases in humans (review). Mol Med Rep 14:4475–4488
Groβkopf C, Mielke H, Westphal D et al (2013) A new model for the prediction of agricultural operator exposure during professional application of plant protection products in outdoor crops. Journal Fur Verbraucherschutz Und Lebensmittelsicherheit-J Consum Prot Food Saf 8:143–153
Hamsan H, Ho YB, Zaidon SZ et al (2017) Occurrence of commonly used pesticides in personal air samples and their associated health risk among paddy farmers. Sci Total Environ 603–604:381–389
Heong KL, Escalada MM, Sengsoulivong V, Schiller J (2002) Insect management beliefs and practices of rice farmers in Laos. Agr Ecosyst Environ 92:137–145
Hongsibsong S, Sittitoon N, Sapbamrer R (2017) Association of health symptoms with low-level exposure to organophosphates, DNA damages, AChE activity, and occupational knowledge and practice among rice, corn, and double-crop farmers. J Occup Health 59:165–176
How V, Hashim Z, Ismail P et al (2015) Characterisation of risk factors for DNA damage among paddy farm worker exposed to mixtures of organophosphates. Arch Environ Occup Health 70:102–190
Jabran K, Chauhan BS (2015) Weed management in aerobic rice systems. Crop Prot 78:151–163
Jansen K (2017) Business conflict and risk regulation: understanding the influence of the pesticide industry. Global Environ Politics 17:4
Jayasumana C, Paranagama P, Agampodi S, Wijewardane C, Gunatilake S, Siribaddana S (2015) Drinking well water and occupational exposure herbicides is associated with chronic kidney disease, in Padavi-Sripura, Sri Lanka. Environ Health 14:6
Kaewboonchoo O, Kongtip P, Woskie S (2015) Occupational health and safety for agricultural workers in Thailand: gaps and recommendations, with a focus on pesticide use. New Solut A J Environ Occup Health Policy 25(1):102–120
Kalliora C, Mamoulakis C, Vasilopoulos E et al (2018) Association of pesticide exposure with human congenital abnormalities. Toxicol Appl Pharmacol 346:58–75
Kedia SK, Palis FG (2008) Health effects of pesticide exposure among Filipino rice farmers. Appl Anthropol 28(1):40–59
Kegley S, Conlisk E (2010) Pesticide risk mitigation engine. Inhalation risk index—white paper. Available at: https://pesticiderisk.org/materials/PRiME_Inhalation_Index_white_paper_092910.pdf. Accessed 20 May 2020
Kim E, Lee H, Hong S, Park KH, An X, Kim JH (2012) Comparative exposure of operators to fenthion during treatment in paddy field. J Korean Soc Appl Biol Chem 55:827–830
Konradsen F, van der Hoek W, Cole DC et al (2003) Reducing acute poisoning in developing countries—options for restricting the availability of pesticides. Toxicology 192:249–261
La N, Lamers M, Bannwarth M, Nguyen VV, Streck T (2015) Imidacloprid concentrations in paddy rice fields in northern Vietnam: measurement and probabilistic modelling. Paddy Water Environ 13:191–203
Lam S, Pham G, Nguyen-Viet H (2017) Emerging health risks from agricultural intensification in Southeast Asia: a systematic review. Int J Occup Environ Health 23(3):250–260
Lappharat S, Siriwong W, Taneepanichskul N, Borjan M, Perez HM, Robson M (2014) Health risk assessment related to dermal exposure of chlorpyrifos: a case study of rice growing farmers in Nakhon Nayok Province, Central Thailand. J Agromed 19:294–302
Lee J, Kim E, Shin Y et al (2018) Whole body dosimetry and risk assessment of agricultural operator exposure to the fungicide kresoxim-methyl in apple orchards. Ecotoxicol Environ Saf 155:94–100
Li Z, Liu W, Wu C, She D (2019) Effect of spraying direction on the exposure to handlers with hand-pumped knapsack sprayer in maize field. Ecotoxicol Environ Saf 170:107–111
Machado SC, Martins I (2018) Risk assessment of occupational pesticide exposure: use of endpoints and surrogates. Regul Toxicol Pharmacol 98:276–283
Maroni M, Colosio C, Ferioli A, Fait A (2000) Biological monitoring of pesticide exposure: a review. Introduction. Toxicology 143:5–8
Matsukawa M, Ito K, Kawakita K, Tanaka T (2016) Current status of pesticide use among rice farmers in Combodia. Appl Entomol Zool 51:571–579
Mohamed Z, Terano R, Shamsudin MN, Abd Latif I (2016) Paddy farmers’ sustainability practices in Granary Areas in Malaysia. Resources 5:17
Mostafalou S, Abdollahi M (2013) Pesticides and human chronic diseases: evidences, mechanisms, and perspectives. Toxicol Appl Pharmacol 268(2):157–177
OECD (1997). Guidance document for the conduct of studies of occupational exposure to pesticides during agricultural application. Series on testing and assessment no. 9, Environmental Directorate, OCDE/GD(97)148. Organisation for Economic Co-operation and Development, Paris
Pan UM, Siriwong W (2010) Risk assessment for dermal exposure of organophosphate pesticides in rice-growing farmers at Rangsit Agricultural Ara, Pathumthani Province, Central Thailand. J Health Res 24(suppl 2):141–148
Panuwet P, Prapamontol T, Chantara S et al (2008) Concentrations of urinary pesticide metabolites in small-scale farmers in Chiang Mai Province, Thailand. Sci Total Environ 407:655–668
Panuwet P, Siriwong W, Prapamontol T et al (2012) Agricultural pesticide management in Thailand: status and population health risk. Environ Sci Policy 17:72–81
Phung DR, Connell D, Miller G, Chu C (2012a) Probabilistic assessment of chlorpyrifos exposure to rice farmers in Viet Nam. J Eposure Sci Environ Epidemiol 22:417–423
Phung DT, Connell D, Miller G et al (2012b) Biological monitoring of chlorpyrifos exposure to rice farmers in Vietnam. Chemosphere 87:294–300
Phung DT, Connell D, Yu Q, Chu C (2013) Health risk characterisation of chlorpyrifos using epidemiological dose-response data and probabilistic techniques: a case study with rice farmers in Vietnam. Risk Anal 33(9):1596–1607
Phung D, Miller G, Connell D, Chu C (2019) Is the World Health Organisation predicted exposure assessment model for space spraying of insecticides applicable to agricultural farmers? Environ Sci Pollut Res 26:896–904
PPDB (2019) The Pesticide Properties Database (PPDB) developed by the Agriculture and Environment Research Unit (AERY), University of Hertfordshire. https://sitem.herts.ac.uk/aeru/ppdb/en/atoz.htm. Accessed 27 Dec 2019
Qiao F, Huang J, Zhang L, Rozelle S (2012) Pesticide use and farmers’ health in China’s rice production. China Agric Econ Rev 4(4):468–484
Rahman S, Chima CD (2018) Determinants of pesticide use in food crop production in Southeastern Nigeria. Agriculture 8:35
Ray DK, Mueller ND, West PC, Foley JA (2013) Yield trends are insufficient to double global crop production by 2050. PLoS ONE 8(6):e66428
Regulation EC No 1107/2009 (2009) Regulation of the European parliament and of the council of 21 October 2009 concerning the placing of plant protection products on the market and repealing council directives 79/117/EEC and 91/414/EEC. Off. J. Eur. Union L 309
Rubino FM, Mandic-Rajcevic S, Ariano E et al (2012) Farmers’ exposure to herbicides in North Italy: assessment under real-life conditions in small-size rice and corn farms. Toxicol Lett 210:189–197
Salcedo R, Vallet A, Granell R et al (2017) Eulerian-Lagrangian model of the behaviour of droplets produced by an air-assisted sprayer in a citrus orchard. Biosys Eng 154:76–91
Sankoh AI, Whittle R, Semple KT, Jones KC, Sweetman AJ (2016) An assessment of the impacts of pesticide use on the environment and health of rice farmers in Sierra Leone. Environ Int 94:458–466
Sapbamrer R, Nata S (2014) Health symptoms related to pesticide exposure and agricultural tasks among rice farmers from northern Thailand. Environ Health Prev Med 19:12–20
Sapbamrer R, Hongsibsong S, Kerdnoi T (2017) Urinary dialkylphosphate metabolites and health symptoms among farmers in Thailand. Arch Environ Occup Health 72(3):145–152
Sattler C, Schrader J, Farkas VM, Settele J, Franzen M (2018) Pesticide diversity in rice growing areas of Northern Vietnam. Paddy Water Environ 16:339–352
Schreinemachers P, Afari-Sefa V, Heng CH et al (2015) Safe and sustainable crop protection in Southeast Asia: status, challenges and policy options. Environ Sci Policy 54:357–366
Snelder DJ, Masipiquena MD, de Snoo GR (2008) Assessment of pesticide usage by smallholder farmers in the Cagayan Valley (Philippines). Crop Prot 27:747–762
So J, Ahn J, Lee TH et al (2014) Comparison of international guidelines of dermal absorption tests used in pesticides exposure assessment for operators. Toxicol Res 30(4):251–260
Sombatsawat E, Norkaew S, Siriwong W (2014) Blood cholinesterase level as biomarker of organophosphate and carbamate pesticide exposure effect among rice farmers in Tarnlalord sub-district, Phimai District, Nakhon Ratchasima Province, Thailand. J Health Res 28(suppl):S33–40
Spinazze A, Lunghini F, Campagnolo D et al (2017) Accuracy evaluation of three modelling tools for occupational exposure assessment. Ann Work Expo Health 61(3):284–298
Sruthi SN, Shyleschandran MS, Mathew SP, Ramasamy EV (2017) Contamination from organochlorine pesticides (OCPs) in agricultural soils of Kuttanad agroecosystem in India and related potential health risk. Environ Sci Pollut Res 24:969–978
Toan PV, Sebesvari Z, Blasing M, Rosendahl I, Renaud FG (2013) Pesticide management and their residues in sediments and surface and drinking water in the Mekong Delta, Vietnam. Sci Total Environ 452–453:28–39
Tuc VP, Wangsuphachart V, Tasanapradit P, Fungladda W, Trong PV, Nhung NT (2007) Impacts of pesticide use on semen characteristics among rice farmers in Kienxuong District, Thaibinh Province, Vietnam. Southeast Asian J Trop Med Public Health 38(3):569–575
US EPA (2018) Exposure assessment tools by routes—dermal. https://www.epa.gov/expobox/exposure-assessment-tools-routes-dermal. Accessed 30 May 2020
Varona-Uribe ME, Torres-Rey CH, Diaz-Criollo S et al (2016) Exposure to pesticide mixtures and DNA damage among rice field workers. Arch Environ Occup Health 71(1):3–9
Vivien H, Hashim Z, Ismail P et al (2013) Biological monitoring of genotoxicity to organophosphate pesticide exposure among rice farmers: exposure-effect continuum study. JOHE 2:1–2
Wang H, Deng XW (2018) Development of the “third-generation” hybrid rice in China. Genom Genom Bioinf 16:393–396
Wang J, Chu M, Ma Y (2018) Measuring rice farmers’ pesticide overuse practice and the determinants: a statistical analysis based on data collected in Jiangsu and Anhui Provinces of China. Sustainability 10:677
WHO (2018) Generic risk assessment model for indoor and outdoor space spraying of insecticides, 2nd edn. https://apps.who.int/iris/handle/10665/276564. Accessed 22 Dec 2019
Wilson C, Tisdell C (2001) Why farmers continue to use pesticides despite environmental, health and sustainability costs. Ecol Econ 39:449–462
Wong HL, Garthwaite DG, Ramwell CT, Brown CD (2018) Assessment of exposure of professional agricultural operators to pesticides. Sci Total Environ 619–620:874–882
Yamano T, Arouna A, Labarta RA, Huelgas ZM, Mohanty S (2016) Adoption and impacts of international rice research technologies. Global Food Secur 8:1–8
Zhao MA, Yu A, Zhu YZ, Wu SQ, Kim JH (2016) Human exposure and risk assessment of chromafenozide during treatment in rice fields. Hum Ecol Risk Assess 22:116–125
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The authors gratefully acknowledge the support of this review by the Universiti Malaysia Kelantan and the University of York.
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All authors contributed to the study design and methods. The first draft of the manuscript was written by Hie Ling Wong, and Colin Brown critically revised the previous versions of the manuscript. All authors read and approved the final manuscript.
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Wong, H.L., Brown, C.D. Assessment of occupational exposure to pesticides applied in rice fields in developing countries: a critical review. Int. J. Environ. Sci. Technol. 18, 499–520 (2021). https://doi.org/10.1007/s13762-020-02834-6
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DOI: https://doi.org/10.1007/s13762-020-02834-6