Forebrain-Cerebellar Interactions During Learning.

The cerebral cortex and cerebellum are high level neural centers that must interact cooperatively to generate coordinated and efficient goal directed movements, including those necessary for a well-timed conditioned response. In this review we describe the progress made in utilizing the forebrain-dependent trace eyeblink conditioning paradigm to understand the neural substrates mediating cerebro-cerebellar interactions during learning and consolidation of conditioned responses. This review expands upon our previous hypothesis that the interaction occurs at sites that project to the pontine nuclei (Weiss & Disterhoft, 1996), by offering more details on the function of the hippocampus and prefrontal cortex during acquisition and the circuitry involved in facilitating pontine input to the cerebellum as a necessary requisite for trace eyeblink conditioning. Our discussion describes the role of the hippocampus, caudal anterior cingulate gyrus, basal ganglia, thalamus, and sensory cortex, including the benefit of utilizing the whisker barrel cortical system. We propose that permanent changes in the sensory cortex, along with input from the caudate and claustrum, and a homologue of the primate dorsolateral prefrontal cortex, serve to bridge the stimulus free trace interval and allow the cerebellum to generate a well-timed conditioned response.

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