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Good Agricultural Practices and Monitoring of Herbicide Residues in India

  • K. K. Sharma
  • Vandana Tripathy
  • Madhuban Gopal
  • Suresh Walia
Chapter
Part of the Environmental Chemistry for a Sustainable World book series (ECSW, volume 12)

Abstract

Herbicides have proved very effective for the control of weeds in cropped areas in India. However, the herbicide use in the country is far less as compared to insecticides and fungicides. While persistent herbicides remain in crops, soil, ground and surface water for a considerable period of time, they may pose hazard to human and animal life as well as the environment. From risk assessment point of view, herbicide residues are monitored through multi-location supervised field trials at various centres of ICAR-sponsored All India Network Project (AINP) on Pesticide Residues and DAC-sponsored central sector scheme on Monitoring of Pesticide Residues at National Level at IARI New Delhi, and All India Coordinated Project on Weed Management (AICRP-WM) at the Directorate of Weed Research, Jabalpur. Besides focusing on weeds and weed management strategies, these laboratories generate globally acceptable data under good agricultural practices (GAP) for export certification and international trade. So far, edible commodities in India have been found to be mostly safe from herbicide residues. Since in future, the herbicide use is likely to increase, therefore herbicide residues problems will be more frequent and may have implications for human health.

References

  1. Aktar MW, Gupta A, Gade V (2007) Fate and behavior of benthiocarb, a herbicide in transplanted paddy under East-Indian climatic condition. Bull Environ Contam Toxicol 79:646–649CrossRefGoogle Scholar
  2. Aktar MW, Gupta D, Alam S, Chowdhury A (2009) Degradation dynamics of a dinitro aniline herbicide (trifluralin) in/on blackgram (Vigna mungo) under East-Indian climatic condition. Electron J Environ Agric Food Chem 8(11):1172–1177Google Scholar
  3. Belz RG, Duke SO (2014) Herbicides and plant hormesis. Pest Manag Sci 70(5):698–707CrossRefGoogle Scholar
  4. Bhatti KH, Parveen T, Farooq A, Nawaz K, Hussain K, Siddiqui EH (2013) A critical review on herbicide resistance in plants. World Appl Sci J 27(8):1027–1036Google Scholar
  5. Biswas PK, Kumar S, Mitra SR, Bhattacharyya A (2007) Persistence of napropamide in/on tea under North-East Indian climatic condition. Bull Environ Contam Toxicol 79:566–569CrossRefGoogle Scholar
  6. Blus JL, Charles JH (1997) Field studies on pesticides and birds: unexpected and unique relations. Ecol Appl 7(4):1125–1132.  https://doi.org/10.1890/1051–0761(1997)007[1125:FSOPAB]2.0.CO;2 CrossRefGoogle Scholar
  7. Chhonkar RS, Malik RK (2002) Isoproturon-resistant littleseed canary grass (Phalaris minor) and its response to alternate herbicides. Weed Technol 16:116–123CrossRefGoogle Scholar
  8. Chhonkar RS, Sharma RK (2008) Multiple herbicide resistance in littleseed canary grass (Phalaris minor): a threat to wheat production in India. Weed Biol Manag 8(2):112–123CrossRefGoogle Scholar
  9. Dinis-Oliveira RJ, Remião F, Carmo H, Duarte JA, Sánchez NA, Bastos ML, Carvalho F (2006) Paraquat exposure as an etiological factor of Parkinson’s disease. Neurobehav Toxicol 27(6):110–112Google Scholar
  10. Duary B (2008) Recent advances in herbicide resistance in weeds and its management. Indian J Weed Sci 40(3&4):124–135Google Scholar
  11. FAO (2003) Herbicide-resistance management in developing countries (Bernal E. Valverde.) In: Labrada R (ed) Weed management for developing countries addendum 1 FAO plant production and protection paper 120 Add. 1. http://www.fao.org/docrep/006/Y5031E/y5031e0h.htm
  12. FAO (2004) Good agricultural practices – a working concept. Background paper for the FAO Internal Workshop on Good Agricultural Practices. Accessed from ftp://ftp.fao.org/docrep/fao/010/ag856e/ag856e00.pdf
  13. FSSAI (2015) Food safety standard authority of India, fixation of MRL. http://www.fssai.gov.in/Portals/0/Pdf/Draft_WTO_Notification_Pesticides_23_11_2015
  14. FAO/WHO (2016) Codex pesticides residues in food online database. Pesticide residues in food and feed. http://www.fao.org/fao-who-codexalimentarius-texts/dbs/pestres/en/
  15. Gorell JM, Johnson CC, Rybicki BA, Peterson EL, Richardson RJ (1998) The risk of Parkinson’s disease with exposure to pesticides, farming, well water, and rural living. Neurology 50(5):1346–1350CrossRefGoogle Scholar
  16. Havens PL, Sims GK, Erhardt-Zabik S (1995) Fate of herbicides in the environment. In: Handbook of weed management systems. M. Dekker, New York, pp 245–278Google Scholar
  17. Hawaldar S, Agasimani CA (2012) Effect of herbicides on weed control and productivity of maize (Zea mays L.). Karnataka J Agric Sci 25(1):137–139Google Scholar
  18. Hayes TB, Collins A, Lee M et al (2002) Hermaphroditic, demasculinized frogs after exposure to the herbicide atrazine at low ecologically relevant doses. Proc Natl Acad Sci 99(8):5476–5480CrossRefGoogle Scholar
  19. Hiller E, VeronikaTatarkova V, Alexandra Simonovicova A, Bartal M (2012) Sorption, desorption, and degradation of (4- chloro-2-methylphenoxy) acetic acid in representative soils of the Danubian Lowland, Slovakia. Chemosphere 87(5):437–444CrossRefGoogle Scholar
  20. Janaki P, Sharmal N, Chinnusamy C, Sakthivel N, Nithya C (2015) Herbicide residues and their management strategies. Indian J Weed Sci 47(3):329–344Google Scholar
  21. Kanwar JS, Sekhon GS (1998) Nutrient management for sustainable intensive agriculture. Fertil News 43:33–40Google Scholar
  22. Kaur R, Gill BS (2012) Analysis of herbicide residues in celery seeds. Indian J Ecol 39(2):258–260Google Scholar
  23. Kettles MK, Browning SR, Prince TS, Horstman SW (1997) Triazine herbicide exposure and breast cancer incidence: an ecologic study of Kentucky counties. Environ Health Perspect 105(11):1222–1227CrossRefGoogle Scholar
  24. Kogevinas M, Becher H, Benn T, Bertazzi PA, Boffetta P, Bueno-de-Mesquita HB, Coggon D, Colin D, Flesch-Janys D, Fingerhut M, Green L, Kauppinen T, Littorin M, Lynge E, Mathews JD, Neuberger M, Pearce N, Saracci R (1997) Cancer mortality in workers exposed to phenoxy herbicides, chlorophenols, and dioxins. An expanded and updated international cohort study. Am J Epidemiol 145(12):1061–1051CrossRefGoogle Scholar
  25. Kulshrestha G, Singh SB, Gautam KC (1995) Residues of fluazifop-P-butyl following application to soybean. Bull Environ Contam Toxicol 55(2):276–282CrossRefGoogle Scholar
  26. Lagana A, Bacaloni A, deLeva I, Faberi A, Fago G, Aal M (2002) Occurrence and determination of herbicides and their major transformation products in environmental waters. Anal Chim Acta 462(2):187–198CrossRefGoogle Scholar
  27. Loos R, Locoro G, Comero S, Contini S, Schwesig D, Werres F, Balsaa P, Gans O, Weiss S, Blaha L, Bolchi M, Gawlik BM (2010) Pan-European survey on the occurrence of selected polar organic persistent pollutants in ground water. Water Res 44(14):4115–4126CrossRefGoogle Scholar
  28. MacKinnon DS, Freedman B (1993) Effects of silvicultural use of the herbicide glyphosate on breeding birds of regenerating clear cuts in Nova Scotia, Canada. J Appl Ecol 30(3):395–406CrossRefGoogle Scholar
  29. Malik RK, Singh S (1995) Littleseed canary grass (Phalaris minor) resistance to isoproturon in India. Weed Technol 9:419–425CrossRefGoogle Scholar
  30. Morrison HI, Wilkins K, Semenciw R, Mao Y, Wigle D (1992) Herbicides and cancer. J Nat Cancer Inst 84(24):1866–1874CrossRefGoogle Scholar
  31. Newton I (2004) The recent declines of farmland bird populations in Britain: an appraisal of causal factors and conservation actions. Intern J Avian Sci 146(4):579–600Google Scholar
  32. OECD (Organization for Economic Co-operation and Development) (2011) OECD MRL calculator: spreadsheet for single data set and spreadsheet for multiple data set, 2 March 2011. In: Pesticide publications/publications on pesticide residues. Available online: http://www.oecd.org
  33. Oerke EC (2006) Crop losses to pests. J Agric Sci 144(1):31–43CrossRefGoogle Scholar
  34. Panchal M, Kapoor C (2016) Indian agrochemicals market to reach $6.8 bn by FY17. Tata Strategic Management Group study. http://www.business-standard.com/content/b2b-chemicals/indian-agrochemicals-market-to-reach-6-8-bn-by-fy17-tata-strategic-management-group-113081200449_1.html
  35. Parmar NB, Maraviya GV, Shah PG, Patel BK, Ghelani LM, Patel AM (1998) Pendimethalin residues in tobacco plant. Tob Res 24(1):57–59Google Scholar
  36. Paul R, Sharma R, Kulshrestha G, Singh SB (2009) Analysis of metsulfuron-methyl residues in wheat field soil: a comparison by HPLC and bioassay. Pest Manag Sci 65:963–968CrossRefGoogle Scholar
  37. Ramesh A, Maheswari ST (2004) Dissipation of alachlor in cotton plant soil and water and its bio-accumulation in fish. Chemosphere 54:547–652CrossRefGoogle Scholar
  38. Rao VS (1993) Principles of weed sciences. Oxford and IBH publishing Co, New Delhi., 1993, pp 23–42Google Scholar
  39. Rao S (2000) Principles of weed science, 2nd edn. Science Publishers, New York, p 526Google Scholar
  40. Rao AN, Chauhan BS (2015) Weeds and weed management in India – a review. In: Weed science in the Asian-Pacific Region. pp 87–118. www.oar.icrisat.org/9093/1/Chapter.pd
  41. Retzinger EJ, Mallory-Smith C (1997) Classification of herbicides by site of action for weed resistance management strategies. Weed Technol 11:384–393CrossRefGoogle Scholar
  42. Reuber MD (1981) Carcinogenicity of picloram. J Toxicol Environ Health 7(2):207–222CrossRefGoogle Scholar
  43. Rice PJ, Anderson TA, Coats JR (2002) Degradation and persistence of metolachlor in soil: effects of concentration, soil moisture, soil depth, and sterilization. Environ Toxicol Chem 21(12):2640–2648CrossRefGoogle Scholar
  44. Robbins CS, Dowell BA, Dawson DK, Colon JA, Estrada R, Sutton A, Sutton R, Weyer D (1989) Comparison of neotropical migrant land bird populations wintering in tropical forest, isolated forest fragments, and agricultural habitats. In: Hagan JM, Johnston DW (eds) Ecology and conservation of neotropical migrant landbirds. Smithsonian Institution Press, Washington, DC, pp 207–220Google Scholar
  45. Samsel A, Seneff S (2016) Glyphosate pathways to modern diseases V: amino acid analogue of glycine in diverse proteins. J Biol Phys Chem 16:9–46CrossRefGoogle Scholar
  46. Sanbagavalli S, Kandasamy OS, Ganesan K (2000) Herbicide resistance in weeds: a review. Agric Rev 21(2):80–88Google Scholar
  47. Santos EA, Correia NM, Silva JRM, Velini ED, Passos ABRJ, Durigan JC (2015) Herbicide detection in groundwater in Córrego Rico-SP watershed. Planta Daninha 33(1):147–155. Available from.  https://doi.org/10.1590/S0100-83582015000100017 CrossRefGoogle Scholar
  48. Senarathna L, Eddleston M, Wilks MF, Woollen BH, Tomenson JA, Roberts DM, Buckley NA (2009) Prediction of outcome after paraquat poisoning by measurement of the plasma paraquat concentration. QJM Intern J Med 102(4):251–259.  https://doi.org/10.1093/qjmed/hcp006. CrossRefGoogle Scholar
  49. Sharma KK (2016) AINP annual report 2015–16, All India Network Project on Pesticide Residues. Indian Council of Agricultural Research, New DelhiGoogle Scholar
  50. Si Y, Takagi K, Iwasaki A, Zhou D (2009) Adsorption, desorption and dissipation of metolachlor in surface and subsurface soils. Pest Manag Sci 65:956–562CrossRefGoogle Scholar
  51. Sing SB, Sharma R, Singh N (2012) Persistence of pyrazosulfuron in rice-field and laboratory soil under Indian tropical conditions. Pest Manag Sci 68(6):828–833CrossRefGoogle Scholar
  52. Singh SB, Das TK, Kulshrestha G (2013) Persistence of herbicide fenoxaprop ethyl and its acid metabolite in soil and wheat crop under Indian tropical conditions. J Environ Sci Health Part B 48(5):324–330CrossRefGoogle Scholar
  53. Soltani N, Shropshire C, Sikkema PH (2015) Pendimethalin residues from weed management in dry bean can cause injury in autumn seeded winter wheat. Agric Sci 6:159–163.  https://doi.org/10.4236/as.2015.61014 CrossRefGoogle Scholar
  54. Sondhia S (2007) Fluazifop-butyl residues in soybean crop and soil. Pestic Res J 19:248–250Google Scholar
  55. Sondhia S (2008a) Determination of imazosulfuron persistence in rice crop and soil. Environ Monit Assess 137(1–3):205–211CrossRefGoogle Scholar
  56. Sondhia S (2008b) Persistence of metsulfuron-methyl in wheat crop and soil. Environ Monit Assess 147(1–3):463–469CrossRefGoogle Scholar
  57. Sondhia S (2009a) Leaching behaviour of metsulfuron in two texturally different soils. Environ Monit Assess 154(1–4):111–115.  https://doi.org/10.1007/s10661-008-0381-8 CrossRefPubMedGoogle Scholar
  58. Sondhia S (2009b) Persistence of metsulfuron-methyl in paddy field and detection of its residues in crop produce. Bull Environ Contam Toxicol 83:799–802CrossRefGoogle Scholar
  59. Sondhia S (2013) Harvest time residues of pendimethalin in tomato, cauliflower, and radish under field conditions. Toxicol Environ Chem 95:254–259.  https://doi.org/10.1080/02772248.2013.765620 CrossRefGoogle Scholar
  60. Sondhia S (2014) Herbicides residues in soil, water, plants and non-targeted organisms and human health implications: an Indian perspective. Indian J Weed Sci 46(1):66–85Google Scholar
  61. Sondhia S, Dixit A (2012) Bioefficacy and persistence of ethoxysulfuron in rice. Oryza 49:178–182Google Scholar
  62. Sondhia S, Varshney JG (2010) Herbicides. Satish Serial Publication House, New Delhi, p 567Google Scholar
  63. Sondhia S, Waseem U, Varma RK (2013) Fungal degradation of an acetolactate synthase (ALS) inhibitor pyrazosulfuron-ethyl in soil. Chemosphere 93:2140–2147CrossRefGoogle Scholar
  64. Sondhia S, Sharma N, Janaki P et al (2015a) Herbicide residue hazards and their mitigation. Indian Farming 65(7):34–39Google Scholar
  65. Sondhia S, Khankhane PJ, Singh PK et al (2015b) Determination of imazethapyr residues in soil and grains after its application to soybeans. J Pestic Sci 40(3):106–110.  https://doi.org/10.1584/jpestics.D14-109 CrossRefGoogle Scholar
  66. Srivastava AK, Trivedi P, Srivastava MK, Lohani M, Srivastava LP (2011) Monitoring of pesticide residues in market basket samples of vegetable from Lucknow City India: QuEChERS method. Environ Monit Assess 176(1–4):465–472.  https://doi.org/10.1007/s10661-010-1597-y CrossRefPubMedGoogle Scholar
  67. Stryer L (1995) Biochemistry, 4th edn. W.H. Freeman and Company. New York, USA, p 1064, ISBN 0-7167-2009-4Google Scholar
  68. Talbot AR, Shiaw MH, Huang JS, Yang SF, Goo TS, Wang SH, Chen CL, Sanford TR (1991) Acute poisoning with a glyphosate-surfactant herbicide (‘Roundup’): a review of 93 cases. Hum Exp Toxicol 10(1):1–8CrossRefGoogle Scholar
  69. Tandon S (2014) Degradation kinetics of anilofos in soil and residues in rice crop at harvest. Pest Manag Sci 70:1706–1710.  https://doi.org/10.1002/ps.3707 CrossRefPubMedGoogle Scholar
  70. Tandon S (2015) Dissipation kinetics and residues analysis of pendimethalin in soil and maize under field conditions. Plant Soil Environ 61:496–500CrossRefGoogle Scholar
  71. Vencill W, Grey T, Culpepper S (2011) Resistance of weeds to herbicides. In: Kortekamp A (ed) Herbicides and environment. Intech Open Science, LondonGoogle Scholar
  72. Walia US, Bar LS, Dhaliwal BK (1997) Resistance to isoproturon in Phalaris minor Retz. in Punjab. Plant Prot Q 12:138–140Google Scholar

Copyright information

© Springer Nature Singapore Pte Ltd. 2019

Authors and Affiliations

  • K. K. Sharma
    • 1
  • Vandana Tripathy
    • 1
  • Madhuban Gopal
    • 1
  • Suresh Walia
    • 1
  1. 1.Division of Agricultural ChemicalsICAR-Indian Agricultural Research InstituteNew DelhiIndia

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