Evaluation of Imidacloprid-induced toxicity and lipid peroxidation in the freshwater bivalve, Lamellidens marginalis

Vinaykamal D. Dethe; Poonam Bhikan Ahire

doi:10.22034/ijab.v11i2.1902

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Vinaykamal D. Dethe
[email protected]
Department of Zoology, MVP’S Arts, Science and Commerce College, Ozar (Mig). Nashik, India.
Poonam Bhikan Ahire Department of Zoology, MVP’S Arts, Science and Commerce College, Ozar (Mig). Nashik, India.

Vol. 11 No. 2 (2023): April

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April 25, 2023

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The toxicity of the neonicotinoid pesticide Imidacloprid was tested on Lamellidens marginalis by 96-hours LC50 test and histopathology. After acute exposure to Imidacloprid, histopathological changes were noted in the gill, mantle, and digestive gland. Exposed gills showed deformed interfilamental space, fused lamellae, disrupted chitenous rod, and vacuolated cytoplasm. In the mantle, damage was observed in the inner and outer mantle epithelium and vacuole in connective tissue. The digestive gland has ruptured the digestive tubule, and basement membrane, the lumen deteriorates, and the cytoplasm appears vacuolated. Lipid peroxidation was also observed after the exposure. These findings suggest that acute exposure to Imidacloprid caused significant histological alterations in vital organs and can affect the non-targeted freshwater bivalve Lamellidens marginalis.

Dethe, V. D., & Bhikan Ahire, P. (2023). Evaluation of Imidacloprid-induced toxicity and lipid peroxidation in the freshwater bivalve, Lamellidens marginalis. International Journal of Aquatic Biology, 11(2), 124–130. https://doi.org/10.22034/ijab.v11i2.1902

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Agrawal A., Ravi S.P., Bechan S. (2010). Water pollution with special reference to pesticide contamination in India. Journal of Water Resource and Protection, 2: 432-447.

Alvim T.T., dos Reis Martinez C.B. (2019). Genotoxic and oxidative damage in the freshwater teleost Prochiloduslineatus exposed to the insecticides lambda-cyhalothrin and imidacloprid alone and in combination. Mutation Research/Genetic Toxicology and Environmental Mutagenesis, 842: 85-93.

Amoatey P., Baawain M.S. (2019). Effects of pollution on freshwater aquatic organisms. Water Environment Research, 91(10): 1272-1287.

Bhalchandra W. (2010). Protective and curative role of L-ascorbic acid on endosulfan induced histopathological changes in the gill of an experimental model, the fresh water bivalve, Parreysia cylindrica. In 2010, 2nd International Conference on Chemical, Biological and Environmental Engineering. pp: 265-269.

Borsuah J.F., Messer T.L., Snow D.D., Comfort S.D., Mittelstet A.R. (2020). Literature review: Global neonicotinoid insecticide occurrence in aquatic environments. Water, 12(12): 1-17.

Cappello T., Mauceri A., Corsaro C., Maisano M., Parrino V., Paro G.L., Fasulo S. (2013). Impact of environmental pollution on caged mussels Mytilus galloprovincialis using NMR-based metabolomics. Marine Pollution Bulletin, 77(1-2): 132-139.

Chakraborty S., Ray M., Ray S. (2008). Sodium arsenite induced alteration of hemocyte density of Lamellidens marginalis – An edible mollusk from India. CLEAN–Soil, Air, Water, 36(2): 195-200.

Giarratano E., Gil M.N., Malanga G. (2014). Biomarkers of environmental stress in gills of ribbed mussel Aulacomya atra atra (Nuevo Gulf, Northern Patagonia). Ecotoxicology and Environmental Safety, 107: 111-119.

Hassan N.A.S., Sheiko E.Y. (2013). Effect of dimetoate insecticide toxicity on the gills of bivalve Pitarrudis as bioindicator (histological study). Banat's Journal of Biotechnology, 4(8): 5-13.

Iturburu F.G., Simoniello M.F., Medici S., Panzeri A.M., Menone M.L. (2018). Imidacloprid causes DNA damage in fish: clastogenesis as a mechanism of genotoxicity. Bulletin of Environmental Contamination and Toxicology, 100: 760-764.

Iturburu F.G., Zömisch M., Panzeri A.M., Crupkin A.C., Contardo?Jara V., Pflugmacher S., Menone M.L. (2017). Uptake, distribution in different tissues, and genotoxicity of imidacloprid in the freshwater fish Australoheros facetus. Environmental Toxicology and Chemistry, 36(3): 699-708.

Kamble V.S., Mane B.U., Rao K.R. (2015). Effect of sublethal treatments of organochlorine pesticide thiodan on histopathology of hepatopancreas of lamellibarch molluscs L. Corrianus.Wcs’s National Journal of Interdisciplinary Research, 1: 142-146

Kayis T., Altun M., Coskun M. (2019). Thiamethoxam-mediated alteration in multi-biomarkers of a model organism, Galleria mellonella L. (Lepidoptera: Pyralidae). Environmental Science and Pollution Research, 26: 36623-36633.

Klarich K.L., Pflug N.C., DeWald E.M., Hladik M.L., Kolpin D.W., Cwiertny D.M., LeFevre G.H. (2017). Occurrence of neonicotinoid insecticides in finished drinking water and fate during drinking water treatment. Environmental Science and Technology Letters, 4(5): 168-173.

Köprücü K., Yonar S.M., ?eker E. (2010). Effects of cypermethrin on antioxidant status, oxidative stress biomarkers, behavior, and mortality in the freshwater mussel Unio elongatuluseucirrus. Fisheries Science, 76: 1007-1013.

Krämer F., Mencke N. (2012). Flea biology and control: the biology of the cat flea control and prevention with imidacloprid in small animals. Springer Science and Business Media. 205 p.

Kuchovská E., Morin B., López-Cabeza R., Barré M., Gouffier C., Bláhová L., Gonzalez P. (2021). Comparison of imidacloprid, propiconazole, and nanopropiconazole effects on the development, behavior, and gene expression biomarkers of the Pacific oyster (Magallana gigas). Science of the Total Environment, 764: 1-11.

Kumar S., Kumar R.P., Das S., Das V.K. (2011): Pathological changes in hepatopancreas of freshwater mussel (Lamellidens marginalis Lamarck) exposed to sublethal concentration of Dimethoate. GERF Bulletin of Biosciences, 2(2): 18-23.

Kumar S., Pandey R.K., Das S., Das V.K. (2012). Dimehoate alters respiratory rate and gill histopathology in freshwater mussel Lamellidens marginalis (Lamarck). Journal of Applied Bioscience, 38(2): 154-158.

Lackner R. (1998). Oxidative stress in fish by environmental pollutants. Fish Ecotoxicology, 203-224.

Laxmilatha P. (2015). Status and conservation issues of window pane oyster Placuna placenta (Linnaeus 1758) in Kakinada Bay, Andhra Pradesh, India. Journal of the Marine Biological Association of India, 57(1): 92-95.

Mencke N., Jeschke P. (2002). Therapy and prevention of parasitic insects in veterinary medicine using imidacloprid. Current Topics in Medicinal Chemistry, 2(7): 701-715.

Morrissey C.A., Mineau P., Devries J.H., Sanchez-Bayo F., Liess M., Cavallaro M.C., Liber K. (2015). Neonicotinoid contamination of global surface waters and associated risk to aquatic invertebrates: a review. Environment International, 74: 291-303.

Mundhe A.Y., Pandit S.V. (2014). Assessment of toxicity of monocrotophos in freshwater bivalve, Lamellidens marginalis, using different markers. Toxicology International, 21(1): 51-56.

Natarajan N., Susithira R. (2016): Studies on Growth and Survival Rate of Pearl Freshwater Mussel Lamellidens marginalis during the culture in a pond. IOSR Journal of Pharmacy and Biological Sciences (IOSR-JPBS), 11: 36-42.

Ohkawa H., Ohishi N., Yagi K. (1979). Assay for lipid peroxides in animal tissues by thiobarbituric acid reaction. Analytical Biochemistry, 95(2): 351-8.

Pagano M., Stara A., Aliko V., Faggio C. (2020). Impact of neonicotinoids to aquatic invertebrates—in vitro studies on Mytilus galloprovincialis: A review. Journal of Marine Science and Engineering, 8(10): 1-14.

Patil A. (2019). Thiamethoxam induced histopathological alterations in hepatopancreas of freshwater bivalve Parreysia cylindrica. Journal of Entomology and. Zoology Studies, 7: 1236-1240.

Rane M., Mahajan A.Y., Zambare S.P. (2013). Biochemical alterations in protein contents of freshwater bivalve, Lamellidens marginalis after exposure to thiamethoxam and triazophos. DAV International Journal of Science, 2: 129-133.

Rane M.R., Mahajan A.Y. (2013). Effect of thiamethoxam on oxygen consumption of the freshwater bivalve, Lamellidens marginalis (Lamarck). The Bioscan, 8: 469-472.

Rane M.S., Kolhe B.G. (2019). Histopathological alterations in gills of freshwater bivalve, Lamellidens marginalis (Lamarck) after acute exposure to thiamethoxam and triazophos. International Journal of Life Sciences (Amravati), (Special Issue A13): 23-28.

Ray A., Gautam A., Das S., Pal K., Das S., Karmakar P., Ray S. (2020). Effects of copper oxide nanoparticle on gill filtration rate, respiration rate, hemocyte associated immune parameters and oxidative status of an Indian freshwater mussel. Comparative Biochemistry and Physiology Part C: Toxicology and Pharmacology, 237: 1-15.

Selvam V., Srinivasan S. (2019). Neonicotinoid Poisoning and Management. Indian Journal of critical care medicine: peer-reviewed, official publication of Indian Society of Critical Care Medicine, 23(Suppl 4): S260-S262.

Shaikh F.I., Ustand I.R., Ansari N.T. (2010). Effect of heavy metal on the ovary fresh water fishes O. massambicus (westwood). The Biocan, 5: 335-338.

Shan Y., Yan S., Hong X., Zha J., Qin J. (2020). Effect of Imidacloprid on the behavior, antioxidant system, multixenobiotic resistance, and histopathology of Asian freshwater clams (Corbicula fluminea). Aquatic Toxicology, 218: 1-42.

Sparks T.C., Crossthwaite A.J., Nauen R., Banba, S., Cordova D., Earley F., Wessels F.J. (2020). Insecticides, biologics and nematicides: Updates to IRAC’s mode of action classification-a tool for resistance management. Pesticide Biochemistry and Physiology, 167: 1-33.

Stalin A., Sayadmusthafa M., Amanullah B. (2011). Histopathological alteration in the gills of freshwater mussel Lamellidens marginalis exposed to sub-lethal concentration of organophosphorus insecticide, Chlorpyrifos. Asian Journal of Microbiology, Biotech and Environmental Science, 13: 125-128.

Stanneck D., Ebbinghaus-Kintscher U., Schoenhense E., Kruedewagen E.M., Turberg A., Leisewitz A., Krieger K.J. (2012). The synergistic action of imidacloprid and flumethrin and their release kinetics from collars applied for ectoparasite control in dogs and cats. Parasites and Vectors, 5: 1-18.

Stara A., Pagano M., Capillo G., Fabrello J., Sandova M., Vazzana I., Faggio C. (2020). Assessing the effects of neonicotinoid insecticide on the bivalve mollusc Mytilus galloprovincialis. Science of Total Environment 700: 1-12.

Strayer D.L. (2008). Freshwater mussel ecology. University of California Press. ? 216 p.

Sula E., Aliko V., Marku E., Nuro A., Faggio C. (2020). Evaluation of kidney histopathological alterations in Crucian Carp, Carassius carassius, from a pesticide and PCB-contaminated freshwater ecosystem, using light microscopy and organ index mathematical model. International Journal of Aquatic Biology, 8(3): 154-165.

Vieira C.E.D., Pérez M.R., Acayaba R.D.A., Raimundo C.C.M., dos Reis Martinez C.B. (2018). DNA damage and oxidative stress induced by imidacloprid exposure in different tissues of the Neotropical fish Prochilodus lineatus. Chemosphere, 195: 125-134.

Yancheva V., Mollov I., Georgieva E., Stoyanova S., Tsvetanova V., Velcheva I. (2017). Ex situ effects of chlorpyrifos on the lysosomal membrane stability and respiration rate in Zebra mussel (Dreissena polymorpha Pallas, 1771). Acta Zoologica Bulgarica S8: 85-90.

Yava?o?lu A., Özkan D., Güner A., Katalay S., Oltulu F., Yava?o?lu N.Ü.K. (2016). Histopathological and apoptotic changes on marine mussels Mytilus galloprovincialis (Lamark, 1819) following exposure to environmental pollutants. Marine Pollution Bulletin, 109(1): 184-191.

Yolo?lu E. (2019). Alterations in some biochemical responses of freshwater mussels in acute imidacloprid exposure. Ad?yaman University Journal of Science, 9(2): 213-229.

Yusufzai S.I., Singh H., Shirdhankar M.M. (2010). An evaluation of different methods for transportation of the freshwater mussel Lamellidens corrianus (Lea 1834). Aquaculture International, 18: 679-692.

Zhang H., Hong X., Yan S., Zha J., Qin J. (2020). Environmentally relevant concentrations of bifenthrin induce changes in behaviour, biomarkers, histological characteristics, and the transcriptome in Corbicula fluminea. Science of The Total Environment, 728: 1-40.