The effect of chronic administration of oxycodone on the behavioral functions and histopathology in the cerebellum and striatum of adult male rats.
Farzin BaneiAbbas AliaghaeiGholam Hossein MeftahiPublished in: 3 Biotech (2024)
Oxycodone is widely used for pain management and acts via binding to mu- and kappa opioid receptors. It was shown that extended oxycodone usage can result from the demyelination and degeneration of neurons through the stress response, which triggers apoptotic signaling pathways. The striatum and cerebellum are recognized as significant contributors to addiction; however, there is no report on the effect of oxycodone on the cerebellum and striatum and motor coordination. We treated rats daily with oxycodone at 15 mg/kg doses for thirty days. Motor performance and electromyography activity were then evaluated. Stereological methods were performed to assess the number of neurons in the cerebellum and striatum as well as immunohistochemistry for microgliosis and astrogliosis. Furthermore, the Sholl analysis method was utilized to evaluate the cellular structure of both microglia and astrocytes. Results of the rotarod test for motor coordination show no significant ( P < 0.05) difference between the oxycodone subjects and those in the control group. In addition, open-field assessments indicated that the application of oxycodone did not alter the amount of distance covered (as an indicator of locomotion) or time spent in the central area (as an indicator of anxiety) ( P < 0.001). The electromyography (EMG) test result showed that oxycodone caused a delay in the reaction of the muscular nerves ( P < 0.001). Data and results from our experiment revealed that administering oxycodone did not affect astrogliosis and the number of neurons in the cerebellum and striatum ( P < 0.05). In contrast, it altered neuromuscular function. In addition, oxycodone administration activated microglia in the cerebellum and striatum. In conclusion, we encourage more research on the adverse effects of oxycodone on the brain.
Keyphrases
- pain management
- chronic pain
- prefrontal cortex
- signaling pathway
- oxidative stress
- inflammatory response
- emergency department
- magnetic resonance
- magnetic resonance imaging
- physical activity
- cell proliferation
- immune response
- big data
- sleep quality
- minimally invasive
- resting state
- deep learning
- artificial intelligence
- electronic health record
- functional connectivity
- pi k akt
- blood brain barrier
- drug induced
- subarachnoid hemorrhage