Concetti Chiave
Postsynaptic spiking during spontaneous recurrent network activity is primarily driven by rapid and brief changes in the balance of excitatory and inhibitory synaptic inputs, with a key role for a few strongly connected inhibitory hub neurons.
Sintesi
The study developed a novel experimental platform and analytical procedures to reconstruct the excitatory and inhibitory synaptic input activity experienced by individual neurons during periods of spontaneous spiking in recurrent neuronal networks.
Key findings:
- Spiking of individual neurons was dominantly controlled by a few strong incoming connections, with inhibitory inputs playing a particularly important role.
- Neuronal spiking was partially governed by rapid and brief changes in the balance of excitatory and inhibitory synaptic inputs, with the peak of the E/I ratio increase coinciding precisely with the action potential trigger time.
- The network contained a few key inhibitory hub cells with high spike rates, strong synapses, and fast action potential propagation that exerted a dominant influence on network activity.
- The results suggest that the emergence of favorable dynamical regimes with rapid membrane potential fluctuations is an inherent property of cortical networks, enabled by the specific circuit architecture.
Statistiche
"Neurons typically receive a continuous bombardment by orchestrated excitatory and inhibitory synaptic inputs, which ultimately determines postsynaptic spiking."
"Theoretical work suggests that balanced networks can potentially assume multiple different dynamical states."
"Across a total of 14 patched putatively excitatory cells, 142 incoming connections were identified (mean = 10.1 ± 5.2 s.d.; min = 3, max = 20 connections per cell)."
"Inhibitory cells displayed higher spike rates and conductances and lower onset latencies compared to excitatory cells."
Citazioni
"Balanced network theory predicts dynamical regimes governed by small and rapid input fluctuation and featuring a fast neuronal responsiveness."
"Our findings – obtained in self-organized neuronal cultures – suggest that the emergence of these favorable regimes and associated network architectures is an inherent property of cortical networks in general."
"A few key inhibitory cells were in a unique position to coordinate network activity by exerting fast and strong effects through an extensive network of outgoing connections."