Inhibitory stabilization and cortical computation

Neuronal networks with strong recurrent connectivity provide the brain with a powerful means to perform complex computational tasks. However, high-gain excitatory networks are susceptible to instability, which can lead to runaway activity, as manifested in pathological regimes such as epilepsy. Inhibitory stabilization offers a dynamic, fast and flexible compensatory mechanism to balance otherwise unstable networks, thus enabling the brain to operate in its most efficient regimes. Here we review recent experimental evidence for the presence of such inhibition-stabilized dynamics in the brain and discuss their consequences for cortical computation. We show how the study of inhibition-stabilized networks in the brain has been facilitated by recent advances in the technological toolbox and perturbative techniques, as well as a concomitant development of biologically realistic computational models. By outlining future avenues, we suggest that inhibitory stabilization can offer an exemplary case of how experimental neuroscience can progress in tandem with technology and theory to advance our understanding of the brain. Inhibitory stabilization is a network mechanism that can enable high-gain excitatory networks to operate without leading to runaway activity. Here Sadeh and Clopath review the evidence for inhibition-stabilized networks in the brain and discuss their implications for cortical computation.

Automated summary

Inhibitory stabilization is a crucial mechanism that enables high-gain excitatory networks to operate without leading to runaway activity, supported by experimental evidence in the brain and influencing cortical computation.