Team:USP-UNESP-Brazil/Associative Memory/Background

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(Biological Mechanism)
(Biological Mechanism)
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===Biological Mechanism===
===Biological Mechanism===
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In a neuronal communication system, the cells of the network occupy a specific place of space and the information is addressed through a direct physical contact - the neuron axonal projections. To replicate this in a cell system that moves constantly it would be also necessary some way to specifically address the information flow between the system’s components, otherwise it will not be possible to attach a meaning to a communication without specificity. Furthermore, is possible to verify the neuronal activity [1.4] because of the fixed spatial position of the cells, which conserves the signal observation of a neuron in a specific local.
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In a neuronal communication system, the cells of the network occupy a specific place of space and the information is addressed through a direct physical contact - the neuron axonal projections. To replicate this in a cell system that moves constantly it would be also necessary some way to specifically address the information flow between the system’s components, otherwise it would not be possible to attach a meaning to a communication without specificity. Furthermore, is possible to verify the neuronal activity because of the fixed spatial position of the cells, which conserves the signal observation of a neuron in a specific local.
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It is much more complicated to observe the dynamics of this cell communicating system using bacteria. Unlike static single cells communicating with each other (see figure 3), we aim to observe the communication between many genetically distinct bacterial populations. And these cells don’t stop moving! In other words: there’s no specific point in space which can be always observed the same phenomenon.
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It is much more complicated to observe the dynamics of this cell communicating system using bacteria. Unlike static single cells communicating with each other (see figure 3), we aim to observe the communication between many genetically distinct bacterial populations. And these cells do not stop moving! In other words: there’s no specific point in space which can be always observed the same phenomenon.
[[File:Figura0020.jpg|center|500px|caption|]]
[[File:Figura0020.jpg|center|500px|caption|]]
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"Figure 3"
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To solve this information addressing problem, it would be necessary that each bacterial population (like neurons) communicate with themselves in a unique way so a receiving signal can be distinguished between populations. We chose the quorum sensing (QS) communication mechanism for this task, using different quorum systems for each “point” (population) in the network. With different QS molecules, it’s possible to build a communication system with unique signals like neurons in a network, where the information addressing specificity is present by the axonal ligation.  
To solve this information addressing problem, it would be necessary that each bacterial population (like neurons) communicate with themselves in a unique way so a receiving signal can be distinguished between populations. We chose the quorum sensing (QS) communication mechanism for this task, using different quorum systems for each “point” (population) in the network. With different QS molecules, it’s possible to build a communication system with unique signals like neurons in a network, where the information addressing specificity is present by the axonal ligation.  

Revision as of 23:53, 25 September 2012