The bidirectional interaction between ventral tegmental rewarding and hindbrain aversive stimulation effects in the rat.

We used the curve-shift procedure in self-stimulating rats to examine the interaction of aversive and rewarding electrical stimuli in terms of duration and direction. The subjects were implanted with two moveable electrodes, one in a region supporting self-stimulation (the ventral tegmental area, VTA) and another in a region supporting escape (the nucleus reticularis gigantocellularis, Gi). The function relating self-stimulation rate to pulse frequency (RF function) was first obtained and then replicated in a condition where each VTA pulse was followed 0.2 or 2.0 ms later by a Gi pulse. The intensity of Gi pulses was set at a value previously found to elicit escape within less than 5 sec. The following observations were made: (1) rats self-stimulated consistently, despite the presence of Gi pulses, (2) the presence of Gi pulses shifted the RF function rightward (decreased the rewarding efficacy of VTA stimulation), with little effect on the maximum rate, (3) after 2 to 5 VTA-Gi self-stimulation sessions, the Gi pulses progressively lost their ability to shift the RF function, and (4) at the end of testing, escape was no longer detectable using Gi pulses alone. It was concluded that (1) the interaction between rewarding VTA and aversive Gi stimulation effects is bidirectional, thus suggesting the presence of algebraic summation; (2) the effect of Gi on VTA reward is transient whereas that of VTA on Gi aversion cumulates and eventually results in total abolition of Gi aversion. The present study represents the first account of cumulative and long-lasting suppression of aversion following brain stimulation in the rat.