How does striatal circuitry contribute to action selection?
Is Long Term Potentiation (LTP) the mechanism whereby striatal neurons learn the best motor action? If so, then LTP should be sensitive to the temporal interval of glutamate and dopamine.
| Research |
This work is a result of an ongoing collaboration with Dietmar
Plenz, Chief, Unit
of Neural Network Physiology, Laboratory of Systems
Neuroscience at the NIMH and Jeanette Hellgren Kotaleski,
Assistant Professor at the Royal Institue of Technology, Stockholm. Our
goal is to discover mechanisms whereby dopamine modulates striatal
activity. This is of critical importance for understanding the
pathophysiology of Parkinson's disease, as well as
reinforcement learning.
How does striatal circuitry contribute to action selection? | |
Is Long Term Potentiation (LTP) the mechanism whereby striatal neurons learn the best motor action? If so, then LTP should be sensitive to the temporal interval of glutamate and dopamine. |
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We have developed new software for modeling stochastic
diffusion. It is analogous to Gillespie's Tau-Leap algorithm. Dendrites and spines are subdivided
into sub-volumes. Pre-calculate the probability that one molecule leaves the compartment
The probability that k out of N molecules leave a compartment is determined using the binomial distribution. These values are stored in a look-up table, and then the number of molecules leaving the compartment is determined with a single uniform random number. This algorithm is being integrated with the tau-leap algorithm, to create Rapid, Approximate, Stochastic reaction-diffusion software. The computational efficiency of the software will allow modeling second messenger pathways in the dendritic spines of an entire neuron.
The figure shows diffusion of IP3 or cAMP in a 20 um x 2 um dendrite with 5 evenly spaced spines. The left panels show the concentration versus time when molecules are initialized in the spine head. On the right, molecules are initialized in the dendrite. |
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I am interested in the biophysical and biochemical mechanisms of long term memory storage. The seaslug Hermissenda crassicornis is a valuable animal model because it can be classically conditioned (similar to Pavlov's dogs). Hermissenda learns to associate light with turbulance; the association is stored in the type B photoreceptor as an increase in membrane resistance mediated by a reduction in potassium channel conductance. We use experimental and modeling techniques to investigate critical issues in Hermissenda classical conditioning , such as which intracellular signals are contributed by conditioned and unconditioned stimuli, and which biochemical reactions require that signals are presented in temporal proximity.
Detailed models of the type B photoreceptor soma, rhabdomere and terminal branches have been developed using the GENESIS software. The models includes the biochemical reactions underlying phototransduction, regulation of intracellular calcium concentration and the second messenger cascade leading from GABAB receptor activation to IP3 production. The model also includes synaptic channels, ligand-gated channels, and voltage-dependent ionic channels. Diffusion, calcium release, and biochemical reactions are implemented using Chemesis libraries written in this laboratory. Calcium-gated and ligand-gated channels also are implemented using Chemesis libraries.
Other useful neural modeling software:
Intracellular recordings in current clamp and voltage clamp mode have been performed to quantitatively characterize the interactions between the light induced signal and the turbulence induced signal that lead to memory storage when these stimuli are presented in temporal proximity. One experiment demonstrated that calcium release through the ryanodine receptor was essential for in vitro classical conditioning. Another experiment measured the light-induced currents, which have a major effect on the excitability of the cell.
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Research | Personnel | Publications | Software | Positions | Avrama Blackwell |
