Conditioned Excitation And Inhibition of Short Latency Gamma Band Oscillations In Early Visual Cortex During Fear Learning In Humans

Over the course of evolution the human brain has been shaped to prioritize cues that signal potential danger. Thereby, the brain does not only favor specie-specific prepared stimulus sets such as snakes or spiders, but can learn associations between new cues and aversive outcomes. One important mechanism to achieve this is associated with learning induced plasticity changes in sensory cortex that optimizes the representation of motivationally relevant sensory stimuli. Animal studies have shown that the modulation of gamma band oscillations predicts cholinergic driven plasticity changes in sensory cortices shifting neurons’ responses to fear relevant features as acquired by Pavlovian fear conditioning. Here, we report conditioned excitatory and inhibitory gamma band modulations in humans during fear conditioning of orthogonally oriented sinus gratings representing fear relevant and irrelevant conditioned cues, respectively. Thereby, pairing of a sinus grating with an aversive loud noise not only increased short latency (during the first 180 ms) evoked visual gamma band responses, but was also accompanied by strong gamma power reductions for the fear irrelevant control grating. The current findings will be discussed in the light of recent neurobiological models of cholinergic driven plasticity changes in sensory cortices and classic learning models such as the Rescorla-Wagner framework.