Growing Science » Current Chemistry Letters » Experimental modeling design to study the effect of different soil treatments on the dissipation of metribuzin herbicide with effect on dehydrogenase activity

Journals


CCL Volumes


Current Chemistry Letters

ISSN 1927-730x (Online) - ISSN 1927-7296 (Print)
Quarterly Publication
Volume 12 Issue 2 pp. 383-396 , 2023

Experimental modeling design to study the effect of different soil treatments on the dissipation of metribuzin herbicide with effect on dehydrogenase activity Pages 383-396 Right click to download the paper Download PDF

Authors: Mohamed Riad Fouad, Mohamed E. I. Badawy, Ahmed F. El-Aswad, Maher I. Aly

DOI: 10.5267/j.ccl.2022.12.001

Keywords: Minitab software, Metribuzin, HPLC, Dissipation, Soil, Half-life, Dehydrogenase

Abstract: The dissipation and side-effect of metribuzin (MBZ) were studied with various factors; two soil types (clay loam and sandy loam), soil amendment (wheat straw and without amendment), two temperature levels (25 and 50°C), sterilization (sterilized and unsterilized soil) and time of incubation (15 and 30 days) and designed by Windows version of MINITAB software package to reduce the time and the cost as well as increased the precision. Determination of MBZ by HPLC with recoveries ranged from 50.85 to 108.09%. The MBZ residues were detected in all samples up to 60 days of storage, respectively with decline in their concentrations with the time of incubation. The clay loam soil showed higher dissipation than the sandy loam soil. The different factors in the present study confirmed that the wheat straw amendment, non-sterilization and incubation at 50°C caused higher dissipation of MBZ than without wheat straw, sterilization and incubation at 25°C. The dissipation was described mathematically by a first order equation with t0.5 was ranged from 9.62 to 16.82 days in clay loam soil and from 10.01 to 16.04 days in sandy loam soil. The side-effect of MBZ was tested on soil dehydrogenase activity that can be considered as an indicator of the biological activity and microbial degradation. The result proved that the enzyme activity was significantly decreased in all treatments compared with the controls at 1 and 3 days of incubation then it was gradually increased at 7, 10, 15 and 30 days of incubation. Treatments of wheat straw, non-sterilized and incubated at 25°C or 50°C showed the lowest enzyme inhibition among all treatments.

How to cite this paper
Fouad, M., Badawy, M., El-Aswad, A & Aly, M. (2023). Experimental modeling design to study the effect of different soil treatments on the dissipation of metribuzin herbicide with effect on dehydrogenase activity.Current Chemistry Letters, 12(2), 383-396.

Refrences

1. Skopalová J., Lemr K., Kotouček M., Čáp L., and Barták P. (2001) Electrochemical behavior and voltammetric determination of the herbicide metribuzin at mercury electrodes. Fresenius J. Anal. Chem., 370 (7) 963-969.
2. Badawy M. E., El-Aswad A. F., Aly M. I., and Fouad M. R. (2017) Effect of different soil treatments on dissipation of chlorantraniliprole and dehydrogenase activity using experimental modeling design. Int. J. Adv. Res. Chem. Sci., 4 (12) 7-23.
3. Fouad M. R., Abou-Elnasr H., Aly M. I., and El-Aswad A. F. (2021) Degradation Kinetics and Half-Lives of Fenitrothion and Thiobencarb in The New Reclaimed Calcareous Soil of Egypt Using GC-MS. Journal of the Advances in Agricultural Researches, 26 (1) 9-19.
4. Aly M. I., Fouad M. R., Abou-Elnasr H. S., and El-Aswad A. F. (2021) Comparison of Dissipation Kinetics and Residual Behaviour for Fenitrothion Insecticide and Thiobencarb Herbicide in Clay Soil. Alex. J. Agric. Sci., 66 (1) 1-11.
5. Huertas-Pérez J.F., del Olmo Iruela M., García-Campaña A.M., González-Casado A., and Sánchez-Navarro A. (2006) Determination of the herbicide metribuzin and its major conversion products in soil by micellar electrokinetic chromatography. J. Chromatogr. A, 1102, 280-286.
6. Ara B., Shah J., Jan M.R., and Muhammad M. (2016) Spectrophotometric determination of metribuzin herbicide with p-dimethylamino-benzaldehyde using factorial designs for optimization of experimental variables. J. Saudi Chem. Soc., 20, S566-S572.
7. Henriksen T., Svensmark B., and Juhler R.K. (2002) Analysis of metribuzin and transformation products in soil by pressurized liquid extraction and liquid chromatographic–tandem mass spectrometry. J. Chromatogr. A, 957 (1) 79-87.
8. Savage K. (1977) Metribuzin persistence in soil. Weed Sci., 55-59.
9. Walker A., Moon Y. H., and Welch S. J. (1992) Influence of temperature, soil moisture and soil characteristics on the persistence of alachlor. Pestic. Sci., 35 (2) 109-116.
10. Moorman T., and Harper S. (1989) Transformation and mineralization of metribuzin in surface and subsurface horizons of a Mississippi Delta soil. J. Environ. Qual., 18 (3) 302-306.
11. Khoury R., Geahchan A., Coste C., Cooper J.F., and Bobe A., (2003) Retention and degradation of metribuzin in sandy loam and clay soils of Lebanon. Weed Res., 43 (4) 252-259.
12. Stenrød M., Perceval J., Benoit P., Almvik M., Bolli R. I., Eklo O. M., Sveistrup T. E., and Kværner J., (2008) Cold climatic conditions: Effects on bioavailability and leaching of the mobile pesticide metribuzin in a silt loam soil in Norway. Cold Reg. Sci. Technol., 53 (1) 4-15.
13. Gallaher K., and Mueller T. C. (1996) Effect of crop presence on persistence of atrazine, metribuzin, and clomazone in surface soil. Weed Sci., 44 (3) 698-703.
14. Banks P. A., and Robinson E. L. (1982) The influence of straw mulch on the soil reception and persistence of metribuzin. Weed Sci., 3 (2) 164-168.
15. Sharom M. S., and Stephenson G. (1976) Behavior and fate of metribuzin in eight Ontario soils. Weed Sci., 24 (2) 153-160.
16. Milburn P., O'Neill H. Gartley C., Pollock T., Richards J., and Bailey H. (1991) Leaching of dinoseb and metribuzin from potato fields in New Brunswick. Can. Agric. Eng., 33 (2) 197-204.
17. Fouad M. R., and El-Aswad A. F., (2018) Competitive and non-competitive adsorption of atrazine and diuron on alluvial soil. Alex. Sci. Exch. J., 39 (July-September) 527-533.‏
18. Locke M. A., and Harper S. S. (1991) Metribuzin degradation in soil: I—effects of soybean residue amendment, metribuzin level, and soil depth. Pest. Manag. Sci., 31 (2) 221-237.
19. Dewangan M., Singh A., and Chowdhury T. (2016) Influence of Herbicides on Phytotoxicity and Soil Dehydrogenase Enzyme Activity in Chickpea (Cicer arietinum L.). Int. j. bio-resour. stress manag., 7 (4) 533-538.
20. Singh R. (2012) Soil Enzyme Activities of Wheat Soil in Response to Metribuzin and Fertilizers in Aligarh Soil. Int. J. Sci. Res., 3 (6) 1705-1709.
21. Fouad M. R. (2021) Study on toxicity effect of bispyribac-sodium herbicide on earthworms by filter paper and soil mixing method. International Journal of Agriculture and Environmental Research. 7 (4) 755-766.
22. Fouad M. R., Shamsan A. Q. S., and Abdel-Raheem Sh. A. A. (2023) Toxicity of atrazine and metribuzin herbicides on earthworms (Aporrectodea caliginosa) by filter paper contact and soil mixing techniques. Curr. Chem. Lett., 12 (1) 185-192.
23. Cardaropoli G., Araujo M., and Lindhe, J. (2003) Dynamics of bone tissue formation in tooth extraction sites. J. Clin. Periodontol., 30 (9) 809-818.
24. Greaves M., and Malkomes H. (1980) Effects on soil microflora. Interactions between herbicides and the soil.
25. Felsot A. S., and Dzantor E. K. (1995) Effect of alachlor concentration and an organic amendment on soil dehydrogenase activity and pesticide degradation rate. Environ. Toxicol. Chem., 14 (1) 23-28.
26. El-Aswad A. F., Aly M. I., Fouad M. R., and Badawy M. E., (2019) Adsorption and thermodynamic parameters of chlorantraniliprole and dinotefuran on clay loam soil with difference in particle size and pH. J. Environ. Sci. Health B, 54 (6) 475-488.‏
27. Fouad M. R. (2022) Validation of adsorption-desorption kinetic models for fipronil and thiamethoxam agrichemicals on three soils in Egypt. Egypt. J. Chem., Accepted Manuscript (DOI: 10.21608/EJCHEM.2022.143450.6289).
28. Fouad M. R. (2023) Physical characteristics and Freundlich model of adsorption and desorption isotherm for fipronil in six types of Egyptian soil. Curr. Chem. Lett., 12 (1) 207-216.
29. Fouad M. R. (2022) Spectrophotometric detection and quantification limits of fipronil and neonicotinoids in acetonitrile. International Journal of Food Science, Nutrition Health and Family Studies, 3 (1) 106-123.‏
30. Fouad M. R., El-Aswad A. F., Badawy M. E. I., and Aly M. I. (2019) Adsorption isotherms modeling of herbicides bispyribac-sodium and metribuzin on two common Egyptian soil types. Journal of Agricultural, Environmental and Veterinary Sciences, 3 (2) 69-91.
31. Papadakis E. N., and Papadopoulou-Mourkidou E. (2002) Determination of metribuzin and major conversion products in soils by microwave-assisted water extraction followed by liquid chromatographic analysis of extracts. J. Chromatogr. A, 962 (1-2) 9-20.
32. Janaki P., Sundaram K. M., Chinnusamy C., and Sakthivel N. (2015) Determination of residues of metribuzin in soil and sugarcane by QuEChERS. Asian J. Chem., 27 (10) 3692.
33. Xie Y. L., Zhao Z. D., Zhang X. L., Tang L. l., Zhang Y., and Zhang C. H. (2017) Simultaneous analysis of herbicide metribuzin and its transformation products in tomato using QuEChERS-based gas chromatography coupled to a triple quadrupole mass analyzer. Microchem. J., 133, 468-473.
34. López-Piñeiro A., Peña D., Albarrán A., Becerra D., and Sánchez-Llerena, J., (2013) Sorption, leaching and persistence of metribuzin in Mediterranean soils amended with olive mill waste of different degrees of organic matter maturity. J. Environ. Manage., 122, 76-84.
35. López-Cabeza R., Gámiz B., Cornejo J., and Celis, R., (2017) Behavior of the enantiomers of the herbicide imazaquin in agricultural soils under different application regimes. Geoderma, 293, 64-72.
36. Singh N., and Singh S. (2015) Adsorption and Leaching Behaviour of Bispyribac-Sodium in Soils. Bull. Environ. Contam. Toxicol., 94 (1) 125-128.
37. Abate G., and Masini J. C. (2005) Sorption of atrazine, propazine, deethylatrazine, deisopropylatrazine and hydroxyatrazine onto organovermiculite. J. Braz. Chem. Soc., 16, 936-943.
38. Castillo M. d. P., and Torstensson L. (2007) Effect of biobed composition, moisture, and temperature on the degradation of pesticides. J. Agric. Food Chem., 55 (14) 5725-5733.
39. Fouad, M. R. (2022). Effect of temperature and soil type on the adsorption and desorption isotherms of thiamethoxam using the Freundlich equation. Egypt. J. Chem., (DOI: 10.21608/ejchem.2022.164539.7015).
40. Rice P. J., Anderson T. A., and Coats J. R. (2002) Degradation and persistence of metolachlor in soil: Effects of concentration, soil moisture, soil depth, and sterilization. Environ. Toxicol. Chem., 21 (12) 2640-2648.
41. Berns A., Philipp H., Narres H.D., Burauel P., Vereecken H., and Tappe W. (2008) Effect of gamma‐sterilization and autoclaving on soil organic matter structure as studied by solid state NMR, UV and fluorescence spectroscopy. Eur. J. Soil Sci., 59 (3) 540-550.
42. Bouchard D. C., and Lavy, T. L., Marx D. B. (1982) Fate of metribuzin, metolachlor, and fluometuron in soil. Weed Sci., 30 (6) 629-632.
43. Fernandes M. C., Cox L., Hermosín M. C., and Cornejo J. (2003) Adsorption–desorption of metalaxyl as affecting dissipation and leaching in soils: role of mineral and organic components. Pest. Manag. Sci., 59 (5) 545-552.
44. Briceño G., Palma G., and Durán N. (2007) Influence of organic amendment on the biodegradation and movement of pesticides. Crit. Rev. Environ. Sci. Technol., 37 (3) 233-271.
45. Cox L., Velarde P., Cabrera A., Hermosín M., and Cornejo J. (2007) Dissolved organic carbon interactions with sorption and leaching of diuron in organic‐amended soils. Eur. J. Soil Sci., 59 (58) 714-721.
46. Thevenot M., Dousset S., Hertkorn N., Schmitt-Kopplin P., and Andreux F. (2009) Interactions of diuron with dissolved organic matter from organic amendments. Sci. Total Environ., 407 (14) 4297-4302.
47. García-Jaramillo M., Cox L., Cornejo J., and Hermosín M. (2014) Effect of soil organic amendments on the behavior of bentazone and tricyclazole. Sci. Total Environ., 466, 906-913.
48. Haham H., Oren A., and Chefetz B. (2012) Insight into the role of dissolved organic matter in sorption of sulfapyridine by semiarid soils. Environ. Sci. Technol., 46 (21) 11870-11877.
49. Cabrera A., Cox L., Spokas K., Hermosín M., Cornejo J., and Koskinen W. (2014) Influence of biochar amendments on the sorption–desorption of aminocyclopyrachlor, bentazone and pyraclostrobin pesticides to an agricultural soil. Sci. Total Environ., 470, 438-443.
50. Carro N., García I., Ignacio M., and Mouteira A., (2006) Microwave-assisted solvent extraction and gas chromatography ion trap mass spectrometry procedure for the determination of persistent organochlorine pesticides (POPs) in marine sediment. Anal. Bioanal. Chem., 385 (5) 901-909.
51. Shah J., Jan M. R., Ara B., and Mohammad M. (2009) Extractive spectrophotometric method for determination of metribuzin herbicide and application of factorial design in optimization of various factors. J. Hazard. Mater., 164 (2-3) 918-922.
52. Torres R. A., Mosteo R., Pétrier C., and Pulgarin C. (2009) Experimental design approach to the optimization of ultrasonic degradation of alachlor and enhancement of treated water biodegradability. Ultrason. Sonochem., 16 (3) 425-430.
53. Dick R. P. (1994) Soil enzyme activities as indicators of soil quality. Defining soil quality for a sustainable environment, 35, 107-124.
54. Brzezińska M., Stępniewska Z., and Stępniewski, W. (1998) Soil oxygen status and dehydrogenase activity. Soil Biol. Biochem., 30 (13) 1783-1790.
55. Tu C. (1992) Effect of some herbicides on activities of microorganisms and enzymes in soil. J. Environ. Sci. Health B, 27 (6) 695-709.
56. Järvan M., Edesi L., Adamson A., and Võsa T. (2014) Soil microbial communities and dehydrogenase activity depending on farming systems. Plant Soil Environ., 60 (10) 459-463.
57. Sahoo S., Adak T., Bagchi T.B., Kumar U., Munda S., Saha S., Berliner J., Jena M., and Mishra B. (2017) Effect of pretilachlor on soil enzyme activities in tropical rice soil. Bull. Environ. Contam. Toxicol., 98 (3) 439-445.
58. Ahmed A. A., Mohamed S. K., and Abdel-Raheem Sh. A. A. (2022) Assessment of the technological quality characters and chemical composition for some Egyptian Faba bean germplasm. Curr. Chem. Lett., 11 (4) 359-370.
59. Mohamed S. K., Mague J. T., Akkurt M., Alfayomy A. M., Abou Seri S. M., Abdel-Raheem Sh. A. A., and Abdul-Malik M. A. (2022) Crystal structure and Hirshfeld surface analysis of ethyl (3E)-5-(4-chlorophenyl)-3-{[(4-chlorophenyl)formamido]imino}-7-methyl-2H,3H,5H-[1,3]thiazolo[3,2-a]pyrimidine-6-carboxylate. Acta Cryst., 78 (8) 846-850.
60. Kaid M., Ali A. E., Shamsan A. Q. S., Salem W. M., Younes S. M., Abdel-Raheem Sh. A. A., and Abdul-Malik M. A. (2022) Efficiency of maturation oxidation ponds as a post-treatment technique of wastewater. Curr. Chem. Lett., 11 (4) 415-422.
61. Elhady O. M., Mansour E. S., Elwassimy M. M., Zawam S. A., Drar A. M., and Abdel-Raheem Sh. A. A. (2022) Selective synthesis, characterization, and toxicological activity screening of some furan compounds as pesticidal agents. Curr. Chem. Lett., 11 (3) 285-290.
62. Abd-Ella A. A., Metwally S. A., Abdul-Malik M. A., El-Ossaily Y. A., Abd Elrazek F. M., Aref S. A., Naffea Y. A., and Abdel-Raheem Sh. A. A. (2022) A review on recent advances for the synthesis of bioactive pyrazolinone and pyrazolidinedione derivatives. Curr. Chem. Lett., 11 (2) 157-172.
63. Tolba M. S., Sayed M., Kamal El-Dean A. M., Hassanien R., Abdel-Raheem Sh. A. A., and Ahmed M. (2021) Design, synthesis and antimicrobial screening of some new thienopyrimidines. Org. Commun., 14 (4) 334-345.
64. Abdel-Raheem Sh. A. A., Kamal El-Dean A. M., Abdul-Malik M. A., Hassanien R., El-Sayed M. E. A., Abd-Ella A. A., Zawam S. A., and Tolba M. S. (2022) Synthesis of new distyrylpyridine analogues bearing amide substructure as effective insecticidal agents. Curr. Chem. Lett., 11 (1) 23-28.
65. Abdelhamid A. A., Elsaghier A. M. M., Aref S. A., Gad M. A., Ahmed N. A., and Abdel-Raheem Sh. A. A. (2021) Preparation and biological activity evaluation of some benzoylthiourea and benzoylurea compounds. Curr. Chem. Lett., 10 (4) 371-376.
66. Tolba M. S., Abdul-Malik M. A., Kamal El-Dean A. M., Geies A. A., Radwan Sh. M., Zaki R. M., Sayed M., Mohamed S. K., and Abdel-Raheem Sh. A. A. (2022) An overview on synthesis and reactions of coumarin based compounds. Curr. Chem. Lett., 11 (1) 29-42.
67. Abdel-Raheem Sh. A. A., Kamal El-Dean A. M., Abdul-Malik M. A., Abd-Ella A. A., Al-Taifi E. A., Hassanien R., El-Sayed M. E. A., Mohamed S. K., Zawam S. A., and Bakhite E. A. (2021) A concise review on some synthetic routes and applications of pyridine scaffold compounds. Curr. Chem. Lett., 10 (4) 337-362.
68. Abdelhafeez I. A., El-Tohamy S. A., Abdul-Malik M. A., Abdel-Raheem Sh. A. A., and El-Dars F. M. S. (2022) A review on green remediation techniques for hydrocarbons and heavy metals contaminated soil. Curr. Chem. Lett., 11 (1) 43-62.
69. Abdel-Raheem Sh. A. A., Kamal El-Dean A. M., Abd ul-Malik M. A., Marae I. S., Bakhite E. A., Hassanien R., El-Sayed M. E. A., Zaki R. M., Tolba M. S., Sayed A. S. A., and Abd-Ella A. A. (2022) Facile synthesis and pesticidal activity of substituted heterocyclic pyridine compounds. Rev. Roum. Chem., 67 (4-5) 305-309.
70. Tolba M. S., Kamal El-Dean A. M., Ahmed M., Hassanien R., Sayed M., Zaki R. M., Mohamed S. K., Zawam S. A., and Abdel-Raheem Sh. A. A. (2022) Synthesis, reactions, and applications of pyrimidine derivatives. Curr. Chem. Lett., 11 (1) 121-138.
71. Abdel-Raheem Sh. A. A., Kamal El-Dean A. M., Zaki R. M., Hassanien R., El-Sayed M. E. A., Sayed M., and Abd-Ella A. A. (2021) Synthesis and toxicological studies on distyryl-substituted heterocyclic insecticides. Eur. Chem. Bull., 10 (4) 225-229.
72. Abdel-Raheem Sh. A. A., Kamal El-Dean A. M., Hassanien R., El-Sayed M. E. A., Sayed M., and Abd-Ella A. A. (2021) Synthesis and spectral characterization of selective pyridine compounds as bioactive agents. Curr. Chem. Lett., 10 (3) 255-260.
73. Shamsan A. Q. S., Fouad M. R., Yacoob W. A. R. M., Abdul-Malik M. A., and Abdel-Raheem Sh. A. A. (2023) Performance of a variety of treatment processes to purify wastewater in the food industry. Curr. Chem. Lett., Accepted Manuscript (DOI: 10.5267/j.ccl.2022.11.003).‏
74. El-Aswad A. F., Fouad M. R., Badawy M. E., and Aly M. I. (2022) Effect of Calcium Carbonate Content on Potential Pesticide Adsorption and Desorption in Calcareous Soil. Commun. Soil Sci. Plant Anal., Accepted Manuscript (DOI: 10.1080/00103624.2022.2146131).‏
75. Fouad M. R., El-Aswad A. F., and Aly M. I. (2022) Acute toxicity, biochemical and histological of fenitrothion and thiobencarb on fish Nile tilapia (Oreochromis niloticus). Nusantara bioscie., 14 (2) 217-226.‏

Journal: Current Chemistry Letters | Year: 2023 | Volume: 12 | Issue: 2 | Views: 674 | Reviews: 0

Related Articles:

Add Reviews

Name:*
E-Mail:
Review:
Bold Italic Underline Strike | Align left Center Align right | Insert smilies Insert link URLInsert protected URL Select color | Add Hidden Text Insert Quote Convert selected text from selection to Cyrillic (Russian) alphabet Insert spoiler
Security Code: *

® 2010-2024 GrowingScience.Com