The role of spike-timing-dependent plasticity (STDP) in shaping the strength of a synapse located on the dendritic tree has gained recent interest. Previous theoretical studies using STDP have mostly used simplified integrate-and-fire models to investigate the evolution of synaptic efficacy with time. Such studies usually show that the final weight distribution is unimodal or bimodal resulting from a multiplicative or additive STDP rule, respectively. However, very little is known about how STDP shapes the spatial organization of synaptic efficacies. Here, for the first time, we demonstrate that spatial clustering of synaptic efficacies can occur on the dendrite via STDP, where changes in synaptic efficacy are driven by timing differences b...
<div><p>Finding the rules underlying how axons of cortical neurons form neural circuits and modify t...
Neurons are the computational building blocks of our brains. They form complicated net- works that p...
In this thesis we are concerned with activity-dependent neuronal plasticity in the nervous system, i...
While it has been appreciated for decades that synapse location in the dendritic tree has a powerful...
Previous studies focusing on the temporal rules governing changes in synaptic strength during spike ...
[5th International Workshop on Neural Coding Aula, Italy, September 20-23, 2003]In spike-timing-depe...
CNS*2010 : Nineteenth Annual Computational Neuroscience Meeting, San Antonio, TX, USA, 24-30 July 20...
Recent experimental results suggest that dendritic and back-propagating spikes can influence synapti...
Recent experimental results suggest that dendritic and back-propagating spikes can influence synapti...
Recent experimental results suggest that dendritic and back-propagating spikes can influence synapti...
Synaptic plasticity is thought to be the principal neuronal mechanism underlying learning. Models of...
Spike Timing-Dependent Plasticity has been found to assume many different forms. The classic STDP cu...
Finding the rules underlying how axons of cortical neurons form neural circuits and modify their cor...
<div><p>Spike timing-dependent plasticity (STDP) modifies synaptic strengths based on timing informa...
Finding the rules underlying how axons of cortical neurons form neural circuits and modify their cor...
<div><p>Finding the rules underlying how axons of cortical neurons form neural circuits and modify t...
Neurons are the computational building blocks of our brains. They form complicated net- works that p...
In this thesis we are concerned with activity-dependent neuronal plasticity in the nervous system, i...
While it has been appreciated for decades that synapse location in the dendritic tree has a powerful...
Previous studies focusing on the temporal rules governing changes in synaptic strength during spike ...
[5th International Workshop on Neural Coding Aula, Italy, September 20-23, 2003]In spike-timing-depe...
CNS*2010 : Nineteenth Annual Computational Neuroscience Meeting, San Antonio, TX, USA, 24-30 July 20...
Recent experimental results suggest that dendritic and back-propagating spikes can influence synapti...
Recent experimental results suggest that dendritic and back-propagating spikes can influence synapti...
Recent experimental results suggest that dendritic and back-propagating spikes can influence synapti...
Synaptic plasticity is thought to be the principal neuronal mechanism underlying learning. Models of...
Spike Timing-Dependent Plasticity has been found to assume many different forms. The classic STDP cu...
Finding the rules underlying how axons of cortical neurons form neural circuits and modify their cor...
<div><p>Spike timing-dependent plasticity (STDP) modifies synaptic strengths based on timing informa...
Finding the rules underlying how axons of cortical neurons form neural circuits and modify their cor...
<div><p>Finding the rules underlying how axons of cortical neurons form neural circuits and modify t...
Neurons are the computational building blocks of our brains. They form complicated net- works that p...
In this thesis we are concerned with activity-dependent neuronal plasticity in the nervous system, i...