Optogenetic activation of mGluR1 signaling in the cerebellum induces synaptic plasticity
Surdin, T., Preissing, B., Rohr, L., Grömmke, M., Böke, H., Barcik, M., et al.
iScience, 26(1), 105828
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title = {Optogenetic activation of mGluR1 signaling in the cerebellum induces synaptic plasticity},
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2020
Separable gain control of ongoing and evoked activity in the visual cortex by serotonergic input
Azimi, Z., Barzan, R., Spoida, K., Surdin, T., Wollenweber, P., Mark, M. D., et al.
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title = {Separable gain control of ongoing and evoked activity in the visual cortex by serotonergic input},
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2019
CaMello-XR enables visualization and optogenetic control of Gq/11 signals and receptor trafficking in GPCR-specific domains
Eickelbeck, D., Karapinar, R., Jack, A., Suess, S. T., Barzan, R., Azimi, Z., et al.
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2018
Subtraction and division of visual cortical population responses by the serotonergic system
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2015
Visual homeostatic processing in V1: when probability meets dynamics
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The Institut für Neuroinformatik (INI) is a central research unit of the
Ruhr-Universität Bochum. We aim to understand the fundamental principles
through which organisms generate behavior and cognition while linked to
their environments through sensory systems and while acting in those
environments through effector systems. Inspired by our insights into
such natural cognitive systems, we seek new solutions to problems of
information processing in artificial cognitive systems. We draw from a
variety of disciplines that include experimental approaches from
psychology and neurophysiology as well as theoretical approaches from
physics, mathematics, electrical engineering and applied computer
science, in particular machine learning, artificial intelligence, and
computer vision.