DocumentCode
663072
Title
Modeling of topology-dependent neural network plasticity induced by activity-dependent electrical stimulation
Author
Ni, Ronggang ; Ledbetter, Noah M. ; Barbour, Dennis L.
Author_Institution
Dept. of Biomed. Eng., Washington Univ. in St. Louis, St. Louis, MO, USA
fYear
2013
fDate
6-8 Nov. 2013
Firstpage
831
Lastpage
834
Abstract
Activity-dependent electrical stimulation can induce cerebrocortical reorganization in vivo by activating brain areas using stimulation derived from the statistics of neural or muscular activity. Due to the nature of synaptic plasticity, network topology is likely to influence the effectiveness of this type of neuromodulation, yet its effect under different network topologies is unclear. To address this issue, we simulated small-scale three-neuron networks to explore topology-dependent network plasticity. The induced neuroplastic changes were evaluated by network coherence and unit-pair mutual information measures. We demonstrated that involvement of monosynaptic feedforward and reciprocal connections is more likely to lead to persistent decreased network coherence and increased network mutual information independent of the global network topology. On the contrary, disynaptic feedforward connections exhibit heterogeneous coherence and unit-pair mutual information sensitivity that depends strongly upon the network context.
Keywords
bioelectric potentials; brain; cellular biophysics; feedforward neural nets; neurophysiology; patient treatment; physiological models; topology; activity-dependent electrical stimulation; brain area activation; cerebrocortical reorganization; disynaptic feedforward connections; monosynaptic feedforward connections; muscular activity; network coherence; neural activity; neuromodulation; neuroplastic change evaluation; small-scale three-neuron network simulation; statistics; synaptic plasticity; topology-dependent neural network plasticity; unit-pair mutual information measures; unit-pair mutual information sensitivity; Artificial neural networks; Biological neural networks; Coherence; Electrical stimulation; Feedforward neural networks; Joining processes; Neurons;
fLanguage
English
Publisher
ieee
Conference_Titel
Neural Engineering (NER), 2013 6th International IEEE/EMBS Conference on
Conference_Location
San Diego, CA
ISSN
1948-3546
Type
conf
DOI
10.1109/NER.2013.6696063
Filename
6696063
Link To Document