Cypermethrin toxicity in the environment: analytical insight into detection methods and microbial degradation pathways

Abstract

The unrestricted utilization of xenobiotic compounds has sparked widespread concern by the world's growing population. A synthetic pyrethroid called cypermethrin (CP) is commonly utilized as an insecticide in horticulture, agriculture, and pest control. The high toxicity levels of accumulated CP have prompted environmental concerns; it damages soil fertility, and an ecosystem of essential bacteria, and causes allergic reactions and tremors in humans by affecting their nervous systems. The damage caused by CP to groundwater, food, and health makes it imperative that new effective and sustainable alternatives are investigated. Microbial degradation has been established as a reliable technique for mineralizing CP into less toxic chemicals. Among the many enzymes produced by bacteria, carboxylesterase enzymes are determined to be the most efficient in the CP breakdown process. High-performance liquid chromatography (HPLC) and gas chromatography-mass spectrometry (GC-MS) have been reported as the best methods for determining CP and its metabolized products, with detection limits as low as ppb from diverse environmental samples. The current study describes the ecotoxicological impact of CP and innovative analytical techniques for their detection. The newly isolated CP-degrading bacterial strains have been evaluated in order to develop an efficient bioremediation strategy. The proposed pathways and the associated critical enzymes in the bacterial mineralization of CP have also been highlighted. Additionally, the strategic action to control CP toxicity has been discussed.