Friedemann Zenke
@fzenke.bsky.social
Computational neuroscientist at the FMI.
www.zenkelab.org
www.zenkelab.org
6/6 BCP does not only work. Trained networks also replicate in-vivo dynamics of SOM and VIP interneurons during motor learning and fear conditioning experiments. Our model takes a step toward linking neuronal circuits with plasticity and behavior.
May 27, 2025 at 7:51 AM
6/6 BCP does not only work. Trained networks also replicate in-vivo dynamics of SOM and VIP interneurons during motor learning and fear conditioning experiments. Our model takes a step toward linking neuronal circuits with plasticity and behavior.
5/6 In multi-layer networks, BCP enables online learning without separate training phases and segregated dendrites, while only using feedback-driven E/I balance perturbations.
May 27, 2025 at 7:50 AM
5/6 In multi-layer networks, BCP enables online learning without separate training phases and segregated dendrites, while only using feedback-driven E/I balance perturbations.
4/6 We formalize this idea as Balance-Controlled Plasticity (BCP), a plasticity framework grounded in adaptive control theory, which simplifies to a Hebbian-like learning rule modulated by recurrent inhibition. This learning rule is both biologically plausible yet powerful.
May 27, 2025 at 7:50 AM
4/6 We formalize this idea as Balance-Controlled Plasticity (BCP), a plasticity framework grounded in adaptive control theory, which simplifies to a Hebbian-like learning rule modulated by recurrent inhibition. This learning rule is both biologically plausible yet powerful.
3/6 We propose feedback signals may target interneurons to transiently disrupt E/I balance. These controlled deviations can efficiently encode local error signals, allowing to guide plasticity without the need for special dendritic morphology.
May 27, 2025 at 7:50 AM
3/6 We propose feedback signals may target interneurons to transiently disrupt E/I balance. These controlled deviations can efficiently encode local error signals, allowing to guide plasticity without the need for special dendritic morphology.
1/6 Why does the brain maintain such precise excitatory-inhibitory balance?
Our new preprint explores a provocative idea: Small, targeted deviations from this balance may serve a purpose: to encode local error signals for learning.
www.biorxiv.org/content/10.1...
led by @jrbch.bsky.social
Our new preprint explores a provocative idea: Small, targeted deviations from this balance may serve a purpose: to encode local error signals for learning.
www.biorxiv.org/content/10.1...
led by @jrbch.bsky.social
May 27, 2025 at 7:49 AM
1/6 Why does the brain maintain such precise excitatory-inhibitory balance?
Our new preprint explores a provocative idea: Small, targeted deviations from this balance may serve a purpose: to encode local error signals for learning.
www.biorxiv.org/content/10.1...
led by @jrbch.bsky.social
Our new preprint explores a provocative idea: Small, targeted deviations from this balance may serve a purpose: to encode local error signals for learning.
www.biorxiv.org/content/10.1...
led by @jrbch.bsky.social