Learning to predict threat depends on amygdala plasticity and does not require auditory cortex (ACX) when threat predictors (conditioned stimuli, CS) are simple sine tones. However, ACX is required in rodents to learn from some naturally occurring CS. Yet, the precise function of ACX, and whether it differs for different CS types, is unknown. Here, we address how ACX encodes threat predictions during human fear conditioning using functional magnetic resonance imaging (fMRI) with multivariate pattern analysis. As in previous rodent work, CS+ and CS- were defined either by direction of frequency modulation (complex) or by frequency of pure tones (simple). In an instructed non-reinforcement context, different sets of simple and complex sounds ...
Neural representation in the auditory cortex is rapidly modulated by both top-down attention and bot...
Unraveling the neuronal mechanisms of fear learning might allow neuroscientists to make links betwee...
Open Data and Open Materials of: Sperl, M. F. J., Wroblewski, A., Mueller, M., Straube, B., & Muelle...
Learning to predict threat depends on amygdala plasticity and does not require auditory cortex (ACX)...
Auditory cortex is required for discriminative fear conditioning beyond the classical amygdala micro...
During auditory fear conditioning, an animal learns to associate a neutral sound stimulus (CS) with ...
Projections from auditory cortex to the amygdala are thought to contribute to the induction of audit...
Learning to avoid dangerous signals while preserving normal responses to safe stimuli is essential f...
Extensive fear extinction research is guided by the view that there are structures in the brain that...
AbstractSingle neurons were recorded in freely behaving rats during fear conditioning from areas of ...
Animals are capable of evaluating sensory cues for possible threats and adapting their behaviours ac...
The medial prefrontal cortex and the basolateral amygdala (BLA) are essential for discriminating bet...
SummaryThe ability to identify, develop, and exploit conditions of safety and security is central to...
Pavlovian fear conditioning is highly conserved across species, providing a powerful model of aversi...
York, New York 10003 dala in fear conditioning has been debated. Animals can acquire fear conditioni...
Neural representation in the auditory cortex is rapidly modulated by both top-down attention and bot...
Unraveling the neuronal mechanisms of fear learning might allow neuroscientists to make links betwee...
Open Data and Open Materials of: Sperl, M. F. J., Wroblewski, A., Mueller, M., Straube, B., & Muelle...
Learning to predict threat depends on amygdala plasticity and does not require auditory cortex (ACX)...
Auditory cortex is required for discriminative fear conditioning beyond the classical amygdala micro...
During auditory fear conditioning, an animal learns to associate a neutral sound stimulus (CS) with ...
Projections from auditory cortex to the amygdala are thought to contribute to the induction of audit...
Learning to avoid dangerous signals while preserving normal responses to safe stimuli is essential f...
Extensive fear extinction research is guided by the view that there are structures in the brain that...
AbstractSingle neurons were recorded in freely behaving rats during fear conditioning from areas of ...
Animals are capable of evaluating sensory cues for possible threats and adapting their behaviours ac...
The medial prefrontal cortex and the basolateral amygdala (BLA) are essential for discriminating bet...
SummaryThe ability to identify, develop, and exploit conditions of safety and security is central to...
Pavlovian fear conditioning is highly conserved across species, providing a powerful model of aversi...
York, New York 10003 dala in fear conditioning has been debated. Animals can acquire fear conditioni...
Neural representation in the auditory cortex is rapidly modulated by both top-down attention and bot...
Unraveling the neuronal mechanisms of fear learning might allow neuroscientists to make links betwee...
Open Data and Open Materials of: Sperl, M. F. J., Wroblewski, A., Mueller, M., Straube, B., & Muelle...