Directed information transmission is paramount for many social, physical, and biological systems. For neural systems, scientists have studied this problem under the paradigm of feedforward networks for decades. In most models of feedforward networks, activity is exclusively driven by excitatory neurons and the wiring patterns between them, while inhibitory neurons play only a stabilizing role for the network dynamics. Motivated by recent experimental discoveries of hippocampal circuitry, cortical circuitry, and the diversity of inhibitory neurons throughout the brain, here we illustrate that one can construct such networks even if the connectivity between the excitatory units in the system remains random. This is achieved by endowing inhibi...
Recent experimental and computational evidence suggests that several dynamical prop-erties may chara...
SummaryThe mammalian brain exhibits profuse interregional connectivity. How information flow is rapi...
ISBN : 978-2-9532965-0-1Neurons receive a large number of excitatory and inhibitory synaptic inputs ...
Directed information transmission is paramount for many social, physical, and biological systems. Fo...
Directed information transmission is paramount for many social, physical, and biological systems. Fo...
Directed information transmission is paramount for many social, physical, and biological systems. Fo...
Cell assemblies are considered to be physiological as well as functional units in the brain. A repe...
Balanced networks of inhibitory and excitatory neurons with homogeneously random recurrent connectiv...
Neural circuits in the brain have distinct and highly conserved ratios of excitatory and inhibitory ...
Repetitive activation of subpopulations of neurons leads to the formation of neuronal assemblies, wh...
SummaryModels of cortical dynamics often assume a homogeneous connectivity structure. However, we sh...
Feedforward inhibition and synaptic scaling are important adaptive processes that control the total ...
The neurons in the mammalian brain can be classified into two broad categories: excitatory and inhib...
Inhibitory neurons, although relatively few in number, exert powerful control over brain circuits. T...
http://deepblue.lib.umich.edu/bitstream/2027.42/134564/1/12868_2015_Article_4162.pd
Recent experimental and computational evidence suggests that several dynamical prop-erties may chara...
SummaryThe mammalian brain exhibits profuse interregional connectivity. How information flow is rapi...
ISBN : 978-2-9532965-0-1Neurons receive a large number of excitatory and inhibitory synaptic inputs ...
Directed information transmission is paramount for many social, physical, and biological systems. Fo...
Directed information transmission is paramount for many social, physical, and biological systems. Fo...
Directed information transmission is paramount for many social, physical, and biological systems. Fo...
Cell assemblies are considered to be physiological as well as functional units in the brain. A repe...
Balanced networks of inhibitory and excitatory neurons with homogeneously random recurrent connectiv...
Neural circuits in the brain have distinct and highly conserved ratios of excitatory and inhibitory ...
Repetitive activation of subpopulations of neurons leads to the formation of neuronal assemblies, wh...
SummaryModels of cortical dynamics often assume a homogeneous connectivity structure. However, we sh...
Feedforward inhibition and synaptic scaling are important adaptive processes that control the total ...
The neurons in the mammalian brain can be classified into two broad categories: excitatory and inhib...
Inhibitory neurons, although relatively few in number, exert powerful control over brain circuits. T...
http://deepblue.lib.umich.edu/bitstream/2027.42/134564/1/12868_2015_Article_4162.pd
Recent experimental and computational evidence suggests that several dynamical prop-erties may chara...
SummaryThe mammalian brain exhibits profuse interregional connectivity. How information flow is rapi...
ISBN : 978-2-9532965-0-1Neurons receive a large number of excitatory and inhibitory synaptic inputs ...