NMDA-driven dendritic modulation enables multitask representation learning in hierarchical sensory processing pathways
While sensory representations in the brain depend on context, it remains unclear how such modulations are implemented at the biophysical level, and how processing layers further in the hierarchy can extract useful features for each possible contex-tual state. Here, we demonstrate that dendritic N-Methyl-D-Aspartate spikes can, within physiological constraints, implement contextual modulation of feedforward processing. Such neuron-specific modulations exploit prior knowledge, encoded in stable feedforward weights, to achieve transfer learning across contexts. In a network of biophysically realistic neuron models with context-independent feedforward weights, we show that modulatory inputs to dendritic branches can solve linearly nonseparable learning problems with a Hebbian, error-modulated learning rule. We also demonstrate that local prediction of whether representations originate either from different inputs, or from different contextual modulations of the same input, results in representation learning of hierarchical feedforward weights across processing layers that accommodate a multitude of contexts.
WOS:001121663700001
2023-08-08
120
32
e2300558120
REVIEWED
Funder | Grant Number |
Helmholtz Portfolio theme Supercomputing and Modeling for the Human Brain | |
Excellence Strategy of the Federal Government | |
Swiss NSF | 785907 |
European Union | 945539 |
JURECA at Forschungszentrum Juelich | |
180316 | |
720270 | |
25241 | |