Effects of pyrethroids on the cerebellum and related mechanisms: a narrative review

Pyrethroids (PYRs) are a group of synthetic organic chemicals that mimic natural pyrethrins. Due to their low toxicity and persistence in mammals, they are widely used today. PYRs exhibit higher lipophilicity than other insecticides, which allows them to easily penetrate the blood-brain barrier and directly induce toxic effects on the central nervous system. Several studies have shown that the cerebellum appears to be one of the regions with the largest changes in biomarkers. The cerebellum, which is extremely responsive to PYRs, functions as a crucial region for storing motor learning memories. Exposure to low doses of various types of PYRs during rat development resulted in diverse long-term effects on motor activity and coordination functions. Reduced motor activity may result from developmental exposure to PYRs in rats, as indicated by delayed cerebellar morphogenesis and maturation. PYRs also caused adverse histopathological and biochemical changes in the cerebellum of mothers and their offspring. By some studies, PYRs may affect granule cells and Purkinje cells, causing damage to cerebellar structures. Destruction of cerebellar structures and morphological defects in Purkinje cells are known to be directly related to functional impairment of motor coordination. Although numerous data support that PYRs cause damage to cerebellar structures, function and development, the mechanisms are not completely understood and require further in-depth studies. This paper reviews the available evidence on the relationship between the use of PYRs and cerebellar damage and discusses the mechanisms of PYRs.

Automated summary

Pyrethroids (PYRs) are widely used synthetic organic chemicals that mimic natural pyrethrins due to their low toxicity and persistence in mammals. However, they possess higher lipophilicity than other insecticides, allowing them to easily cross the blood-brain barrier and directly affect the central nervous system. Studies have shown that the cerebellum, a crucial region for motor learning memories, exhibits significant changes in biomarkers when exposed to PYRs. Developmental exposure to low doses of PYRs in rats resulted in diverse long-term effects on motor activity and coordination, possibly due to delayed cerebellar morphogenesis and maturation. PYRs also caused adverse histopathological and biochemical changes in both mothers and their offspring's cerebellum, potentially damaging cerebellar structures and impairing motor coordination. While data support PYRs' harmful effects on cerebellar structures, function, and development, further research is needed to fully understand the mechanisms involved.