The temporal paradox of Hebbian learning and homeostatic plasticity

Hebbian plasticity, a synaptic mechanism which detects and amplifies co-activity between neurons, is considered a key ingredient underlying learning and memory in the brain. However, Hebbian plasticity alone is unstable, leading to runaway neuronal activity, and therefore requires stabilization by additional compensatory processes. Traditionally, a diversity of homeostatic plasticity phenomena found in neural circuits is thought to play this role. However, recent modelling work suggests that the slow evolution of homeostatic plasticity, as observed in experiments, is insufficient to prevent instabilities originating from Hebbian plasticity. To remedy this situation, we suggest that homeostatic plasticity is complemented by additional rapid compensatory processes, which rapidly stabilize neuronal activity on short timescales.

The temporal paradox of Hebbian learning and homeostatic plasticity

Long-term plasticity induces sparse and specific synaptic changes in a biophysically detailed cortical model

Principles of Network Plasticity in Neocortical Microcircuits

Modeling and simulation of neocortical micro- and mesocircuitry. Part II: Physiology and experimentation

Long-term plasticity induces sparse and specific synaptic changes in a biophysically detailed cortical model

Principles of Network Plasticity in Neocortical Microcircuits

Modeling and simulation of neocortical micro- and mesocircuitry. Part II: Physiology and experimentation