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| {{Box|width=45%|min-width=310px|float=left|font-size=14px|[[Brownian Motion]]| | | {{Box|width=45%|min-width=300px|float=left|font-size=14px|[[Actin|Actin Modeling]]| |
| Over the last year my main interest has been the study of synaptic potentiation from an animated, quantitative perspective (read: MCMC methods and simulation). Currently, I'm examining the membrane [[:Category:Diffusion|diffusion]] of neurotransmitter receptors and modeling how these particles swarm and potentiate synapses. It has been an interesting transition into these topics - prior to these projects I worked primarily with brain tissue and mice, but now I find myself spending most of my day programming, running simulations, and working with equations. I'm not sure why, but I find [[:Category:Diffusion|diffusion]] quite interesting. [[:Category:Diffusion|Stochastic diffusion]], like that in [[:Category:Diffusion|Brownian motion]], is a pure actuation of the basic properties of [[:Category:Statistics|statistics]] - probability distributions in particular. Given that synaptic potentiation is directly mediated by stochastic diffusion and synaptic capture of receptors, it seem that neurons have evolved into innate statistical computers. The result of 100 billion of these statistical computers making 100 trillion connections is the human brain.
| | The study of actin dynamics is centrally important to understanding synaptic plasticity. Fortunately, actin research has provided a vast pool of experimental studies, and several quantitative models that provide excellent characterizations of actin polymerization kinetics. To simulate filament scaffolding in a dendritic model, I developed a stochastic 3D model of actin dynamics based on parameters from previously established in steady-state, monte carlo and stochastic models. The ability to simulate the evolution of actin networks in 3D makes this model unique. |
| | | <mediaplayer image='http://www.bradleymonk.com/w/images/d/da/Kasai_GluUncaging_S7.png' width='100%'>http://www.bradleymonk.com/w/images/1/18/Kasai_GluUncaging_S7.mov</mediaplayer> |
| * [[:Category:Diffusion|MY NOTES ON MODELING DIFFUSION]]
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| {{Box|width=45%|min-width=300px|float=left|font-size=14px|[[Actin|Actin Modeling]]| | | {{Box|width=45%|min-width=310px|float=left|font-size=14px|[[Brownian Motion]]| |
| The study of actin dynamics is centrally important to understanding synaptic plasticity. Fortunately, actin research has provided a vast pool of experimental studies, and several quantitative models that provide excellent characterizations of actin polymerization kinetics. To simulate filament scaffolding in a dendritic model, I developed a stochastic 3D model of actin dynamics based on parameters from previously established in steady-state (Bindschadler 2004, Yarmola 2008), monte carlo (Halavatyi 2008) and stochastic (Mogilner 2006) models. The ability to simulate the evolution of actin networks in 3D makes this model unique.
| | Molecular-level synaptic plasticity is among my primary interests. I've studied and quantified membrane [[:Category:Diffusion|diffusion]] properties of excitatory and inhibitory receptors, and have developed models how these particles swarm to potentiate synapses. I find stochastic particle diffusion is intertwined with the first principles of [[:Category:Statistics|statistics and probability]]. Given that synaptic potentiation is dependent on marshalling receptors undergoing stochastic diffusion, it seem that neurons have evolved into innate statistical computers. The result of 100 billion of these statistical computers making 100 trillion connections is the human brain. Here are some of my [[:Category:Diffusion|notes and code for simulating membrane diffusion.]] |
| <mediaplayer image='http://www.bradleymonk.com/w/images/d/da/Kasai_GluUncaging_S7.png' width='100%'>http://www.bradleymonk.com/w/images/1/18/Kasai_GluUncaging_S7.mov</mediaplayer>
| | ---- |
| | [[File: Stochastic-Diffusion.gif]] |
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| {{Box|width=45%|min-width=310px|float=left|font-size=14px|[[Connectome|Brain Functional Connectome Project]]|
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| A [[connectome]] is a comprehensive map of the neural networks within the [[brain]]. It details the [http://en.wikipedia.org/wiki/Efferent_nerve_fiber efferent] and afferent pathways within and between [[brain]] regions. Functional Connectivity refers to the function of a particular [[brain]] region and its information processing role within a distributed neural network. The goal of this project is to create a platform where users can jump into the [[connectome]] at any given [[brain]] region and visually navigate to upstream and downstream regions; along the way, users can learn about the functional role of each [[brain]] region. All information has been collected from empirical sources and scientific databases, in particular, the [http://atlas.brain-map.org Allan Brain Atlas].
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| {{Box|width=45%|min-width=310px|float=right|font-size=14px|[[Brain Molecular Pathways|Brain Molecular Pathways Project]]|
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| This project aims to provide annotated sets of [[Molecular Pathways|molecular pathways]] involved in neural plasticity underlying learning and memory systems. In general, biological pathways display the series of interactions among molecules resulting in functional changes within cells and neural networks. Currently there are large scale projects dedicated to amassing pathway evidence via high-throughput methods. The goal is to translate this unwieldy biopathway data from several [http://www.genome.jp/kegg/ empirical databases] into visually digestible material, by [[Molecular Pathways|characterizing]] the features of molecular cascades most sensitive to an ''event of interest'' (e.g. fear conditioning or amphetamine addiction).
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