Abstract
Fear is an important emotion for survival, and the cerebellum has been found to contribute not only to innate affective and defensive behavior, but also to learned fear responses. Acquisition and retention of fear conditioned bradycardia and freezing have been shown to depend on the integrity of the cerebellar vermis in rodents. There is a considerable number of brain imaging studies, which observe activation of the human cerebellum in fear conditioning paradigms. Different to what one may expect based on the initial cerebellar lesion studies, activations related to the learned prediction of threat go well beyond the vermis, and are most prominent in the lateral cerebellum. Different parts of the cerebellum likely contribute to learning of autonomic, motor, emotional and cognitive responses involved in classical fear conditioning. The neural operation which is performed in the various parts of the cerebellum is frequently assumed to be the same. One hypothesis is that the cerebellum acts as, or is part of, a predictive device. More recent findings will be discussed that the cerebellum may not only be involved in the processing of sensory prediction errors, but also in the processing of reward and reward prediction errors, which may play a central role in emotions and emotional learning. Current knowledge about the intrinsic learning mechanisms underlying fear memory in the cerebellum, and its connections with subcortical and cortical fear circuitry will be presented. The chapter will conclude with a discussion on how disordered cerebellar fear learning may contribute to affective disorders.
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This work was supported by the German Research Foundation (DFG; project number 316803389 – SFB 1280) to DT (subproject A05) and MDM (subproject A21), DFG MA 5806/2-1 (MDM), MA 5806/1-2 (MDM), and Marie-Curie-ITN Cerebellum and Emotional Networks (CEN) (DT).
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Mark, M., Pakusch, J., Ernst, T.M., Timmann, D. (2022). Cerebellum and Emotion Memory. In: Adamaszek, M., Manto, M., Schutter, D.J.L.G. (eds) The Emotional Cerebellum . Advances in Experimental Medicine and Biology, vol 1378. Springer, Cham. https://doi.org/10.1007/978-3-030-99550-8_5
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