Long-term effects of clomipramine and fluoxetine on dorsal periaqueductal grey-evoked innate defensive behaviours of the rat.

RATIONALE: The defensive responses induced by electrical stimulation of dorsal periaqueductal grey (DPAG) of the rat have been proposed as a model of panic attacks in humans. OBJECTIVE: The present experiments were carried out to evaluate the long-term effects of clinically effective panicolytics on these responses. METHODS: Rats that had electrodes implanted into the DPAG were treated for 21 days with clomipramine (CLM; 5, 10 and 20 mg/kg), fluoxetine (FLX; 1 and 5 mg/kg) or saline. Long-term effects were assessed prior to the treatment to avoid acute drug effects. Threshold logistic functions of defensive responses were compared by likelihood ratio coincidence tests. RESULTS: CLM attenuated DPAG-evoked defensive behaviours at a time-course similar to that observed in panic therapy. Administration of 10 mg/kg CLM for 21 days produced significant increases in the thresholds of immobility (24%), running (49%) and jumping (45%). Splitting of running into single responses disclosed selective threshold increases of galloping (75%) and trotting (138%) with 5 and 10 mg/kg, respectively. Thresholds of micturition were markedly increased (87%) by 5 mg/kg CLM. In turn, FLX (1 mg/kg) virtually abolished the galloping response. No threshold changes were observed following the long-term administration of the higher dose of either CLM or FLX. Saline-treated rats had a significant increase (35%) in galloping thresholds only. CONCLUSIONS: The present data partially validate the DPAG-evoked defence reaction of the rat as a model of panic attacks in humans. Attenuation of galloping by lower doses of FLX and CLM also suggests the prominent modulation of this response by serotonin.

Modeling panic attacks.

The isomorphism of dorsal periaqueductal gray-evoked defensive behaviors and panic attacks was appraised in the present study. Thresholds of electrically induced immobility, trotting, galloping, jumping, exophthalmus, micturition and defecation were recorded before and after acute injections of anxiolytic, anxiogenic and antidepressant drugs. Antidepressant effects were further assessed 24h after injections of 7-14- and 21-day treatments. Chronic administration of clomipramine (CLM, 5-10mg/kg) a clinically effective antipanic drug increased the thresholds of immobility (24%), trotting (138%) galloping (75%), jumping (45%) and micturition (85%). The 21-day treatment with fluoxetine (FLX, 1mg/kg) virtually abolished galloping without changing the remaining responses. Galloping thresholds were also increased by 5mg/kg acute injections of CLM (19%) and FLX (25%). In contrast, chronically administered maprotiline (10mg/kg), a noradrenaline (NE) selective reuptake inhibitor, selectively increased the thresholds of immobility (118%). Diazepam (1.8mg/kg) and midazolam (MDZ, 2.5mg/kg) failed in attenuating the somatic defensive responses. Yet, the sedative dose of MDZ (5mg/kg) attenuated immobility. The panicogenic drug, pentylenetetrazole (50mg/kg), markedly decreased the thresholds of galloping (-51%) and micturition (-66%). These results suggest that whereas immobility is a NE-mediated attentional response, galloping is the panic-like behavior best candidate.

Micturition and defensive behaviors are controlled by distinct neural networks within the dorsal periaqueductal gray and deep gray layer of the superior colliculus of the rat.

Electrical stimulation of the dorsal periaqueductal gray (DPAG) or the deep gray layer of the superior colliculus (DGSC) of rats placed in an open-field elicited either a display of tense immobility, accompanied by exophthalmus and/or defecation and micturition, or running and jumping responses. Threshold curves of each response were obtained for each structure by the logistic fitting of accumulated response frequencies. DPAG and DGSC threshold curves were compared by likelihood-ratio coincidence tests. The output of micturition was significantly higher following the stimulation of DPAG (P < 0.0005). In contrast, no differences were found for the remaining responses. These data support previous studies in anaesthetized cats suggesting the critical involvement of DPAG in the control of micturition. Furthermore, they also suggest that topographically distinct neural networks within the DPAG and DGSC control micturition and the other defensive behaviors.