Author response: Energy efficient synaptic plasticity
(2019)
Other
Li, H. L., & van Rossum, M. C. (2019). Author response: Energy efficient synaptic plasticity
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Energy efficient synaptic plasticity (2019)
Other
Li, H. L., & van Rossum, M. C. W. Energy efficient synaptic plasticityMany aspects of the brain’s design can be understood as the result of evolutionary drive towards efficient use of metabolic energy. In addition to the energetic costs of neural computation and transmission, experimental evidence indicates that synapt... Read More about Energy efficient synaptic plasticity.
Self-organised reactivation maintains and reinforces memories despite synaptic turnover (2019)
Journal Article
Fauth, M. J., & van Rossum, M. C. (2019). Self-organised reactivation maintains and reinforces memories despite synaptic turnover. eLife, 2019(8), Article e43717. https://doi.org/10.7554/eLife.43717Long-term memories are believed to be stored in the synapses of cortical neuronal networks. However, recent experiments report continuous creation and removal of cortical synapses, which raises the question how memories can survive on such a variable... Read More about Self-organised reactivation maintains and reinforces memories despite synaptic turnover.
Slowdown of BCM plasticity with many synapses (2019)
Journal Article
Froc, M., & van Rossum, M. C. W. (2019). Slowdown of BCM plasticity with many synapses. Journal of Computational Neuroscience, 46(2), 141-144. https://doi.org/10.1007/s10827-019-00715-7During neural development sensory stimulation induces long-term changes in the receptive field of the neurons that encode the stimuli. The Bienenstock-Cooper-Munro (BCM) model was introduced to model and analyze this process computationally, and it r... Read More about Slowdown of BCM plasticity with many synapses.
Author response: Self-organized reactivation maintains and reinforces memories despite synaptic turnover (2019)
Other
Fauth, M. J., & van Rossum, M. C. (2019). Author response: Self-organized reactivation maintains and reinforces memories despite synaptic turnover