Acoustic startle amplitude predicts vulnerability to develop post-traumatic stress hyper-responsivity and associated plasma corticosterone changes in rats.

Following exposure to trauma, a vulnerable sub-population of individuals develops post-traumatic stress disorder (PTSD) with characteristic persistent autonomic hyper-responsivity, associated increased startle response, and commonly altered hypothalamo-pituitary-adrenal regulation. A goal of this investigation was to identify a predictive marker for this vulnerability. Previous investigators have developed a model for PTSD in which male mice were exposed to a single brief episode of inescapable footshock followed by 1-min contextual reminders of this trauma at weekly intervals for 6 weeks. Exposure to these reminders induced a progressive and persistent increase in the amplitude of acoustic startle consistent with the persistently increased acoustic startle of individuals exhibiting PTSD. We adapted this model to adult male Wistar rats, with added characterization of initial (pre-trauma) startle response. After one episode of inescapable footshock (10 s, 2 mA) or control treatment followed by six weekly 1-min contextual reminders, acoustic startle was re-tested. Data were analyzed after dividing rats within each treatment into LOW vs MID vs HIGH (33% in each group) pre-treatment startle responders. Rats which exhibited pre-treatment LOW- and MID-range acoustic startle responses did not develop increased acoustic startle responses following subsequent traumatic stress+reminders ([TS+R]) treatment. However, rats which exhibited HIGH pre-treatment startle responses exhibited further significant (p<0.01) [TS+R]-induced persistent enhancement of this already elevated startle response. Furthermore, rats exhibiting HIGH pre-treatment startle responses were also the only subgroup which exhibited increased basal plasma corticosterone levels following [TS+R] treatment. These results suggest that initial pre-stress acoustic startle response can identify subgroups of rats which are predisposed to, or resistant to, developing a PTSD-like syndrome following subsequent trauma.

Olanzapine-induced weight gain and increased visceral adiposity is blocked by melatonin replacement therapy in rats.

The atypical antipsychotic drug olanzapine increases body weight and visceral adiposity in schizophrenia. In rats, aging-associated increased body weight and visceral adiposity are reversed by administration of the pineal hormone melatonin. We asked if melatonin similarly would reverse olanzapine-induced increased weight and visceral adiposity in rats. Four groups (n=11/group) of female rats (240-250 g) were treated for 8 weeks with olanzapine, melatonin, olanzapine+melatonin, or vehicle alone in drinking water. Body weight and food and water consumption were determined weekly, locomotor activity at weeks 3 and 6, and nocturnal plasma melatonin concentration at week 7. At week 8, the rats were killed and visceral (perirenal, retroperitoneal, omental, and mesenteric) fat pads dissected and weighed. Olanzapine treatment reduced nocturnal plasma melatonin by 55% (p<0.001), which was restored to control levels by olanzapine+melatonin. Body weight increased 18% in rats treated with olanzapine alone, but only 10% with olanzapine+melatonin, 5% with melatonin alone, and 7% with vehicle control. Body weight and visceral fat pad weight increases in rats treated with olanzapine alone were greater than in each of the other three groups (all p<0.01), which were not significantly different. These results suggest that olanzapine-induced increases in body weight and visceral adiposity may be at least in part secondary to olanzapine-induced reduction of plasma melatonin levels, and that melatonin may be useful for the management of olanzapine-induced weight gain in humans.