Differential effects of environment-induced changes in body temperature on modafinil's actions against methamphetamine-induced striatal toxicity in mice

MARIANA RAINERI; BETINA GONZALEZ ; CELESTE RIVERO ECHETO; JAVIER A. MUÑIZ; CAROLINA I. GHANEM ; MARÍA LAURA GUTIÉRREZ; JEAN LUD CADET ; EDGAR GARCÍA-RILL ; FRANCISCO J. URBANO; VERONICA BISAGNO

NEUROTOXICITY RESEARCH

SPRINGER

Año: 2015

1029-8428

Rationale Methamphetamine (METH) exposure can produce hyperthermia that might lead to toxicity and death. Modafinil is a wake-promoting compound that is also been prescribed off-label to treat METH dependence. Modafinil has shown neuroprotective properties against METH harmful effects in animal models. Objective The objective of the present study was to test if the prevention of hyperthermia might play a role on the neuroprotective actions of modafinil against METH toxicity using various ambient temperatures. Methods METH was administered to female C57BL/6 mice in a binge regimen: 4 x 5 mg/kg , 2h apart; modafinil (90mg/kg) was injected twice, 1h before first and fourth METH injections. Drugs were given at cold ambient temperature (14 °C) or hot ambient temperature (29 °C). Body temperature was measured during treatments. Brains were dissected out six days after treatments and processed for TH, DAT, GFAP and c-Fos immunohistochemistry. Results Exposure to hot ambient temperature exacerbated METH toxicity evidenced by sriatal reductions in TH and DAT and increased GFAP immmunoreactivity. Modafinil counteracted reductions in TH and DAT, but failed to block astroglial activation. At both ambient temperatures tested modafinil did induce increments in GFAP, but the magnitude was significantly lower than the one induced by METH. Both drugs induced increases in c-Fos positive nuclei; modafinil did not block this effect. Conclusion Our results suggest that protective effects of modafinil against METH-induced neurotoxicity may be dependent, in part, to its hypothermic effects. Nevertheless, modafinil maintained some protective properties on METH-induced alterations in the striatum at different ambient temperatures.