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	=== Part 2 ===		=== Part 2 ===
		+	In a neuronal communication system, the cells have specific locations and the information is sent by a direct physical connection(the axon of the neuron). To replicate this dinamic in a moving cells system, would be necessary to stablish a way to give an specific adressing to the exchange of informations between the components of the system. An important aspect of the specific location of the neurons is the chance to observe the neuronal activation, which occurs always in the same area. This process in a bacteria network is in way more complex than that, because theres no communication between only two cells in a specific point of the space, but between various populations of bacterias that have movement , in other words, there is no specific point in  space where you can observe the same phenomenon in different moments.
		+	In order to give an specific addressing to the bacterial population, a system will be constructed in a way to make 9 different E. coli populations communicate with each other and keep their positions. The system allow communications not only between neighbors, integrating signal coming from the hole system, activating or inhibiting the answer of the cell according to the specific memory established. (figura)
-		+	This system have 96 cavities with permeable membranes that allows the exchange of signals by "quorun sense" substances, but keeps the populations in a specific location. In other words, in allows the communication, but not the mix of different populations, keeping the signals uniform accordingly to its origins.
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	=== The Experiments ===		=== The Experiments ===

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Revision as of 23:51, 25 July 2012

Contents 1 Overall project - Associative Memory Network Using Bacteria 1.1 Associative Memory Network Using Bacteria 2 Project Details 2.1 Part 2 2.2 The Experiments 2.3 Part 3 3 Results

Overall project - Associative Memory Network Using Bacteria

Since we are a big team and it's our first participation on iGEM, we have two projects going on at the same time. The first one is "Associative Memory Network Using Bacteria" and "Plug&Play Plasmid"

Associative Memory Network Using Bacteria

The memory storage in biological systems has a critical role in biotechnology development. A systemic way of storing a specific memory that can be recovered and used at any moment is studied in several experiments and mathematical models involving neural networks. One of these models, known by “Hopfield Network”, considers the memory storage as a neurons association that shares a characteristic pattern of “communication intensity” – the “measure unity” of a neuron network . This model is notorious for allowing systems the recognizing of patterns.

In this project we propose the genesis of aa communication network using E.coli populations, in order to create a system with associative memory ,like a Hopfield Model. Genetically different populations will be generated and isolated from each other, keeping contact by means of Quorum Sensing Substances (QSS). These QSS will be responsible by inhibition or excitation of pre-determined populations, measuring the amount of excitation by means of GFP fluorescent level. The final objective is to achieve a specific complete pattern of excited and inhibited populations by means of the interactions between bacteria populations, based on an given incomplete pattern. The network will behave in way of recognizing this pattern and choose between two systemic memories inserted on the communication network.

Project Details

Part 2

In a neuronal communication system, the cells have specific locations and the information is sent by a direct physical connection(the axon of the neuron). To replicate this dinamic in a moving cells system, would be necessary to stablish a way to give an specific adressing to the exchange of informations between the components of the system. An important aspect of the specific location of the neurons is the chance to observe the neuronal activation, which occurs always in the same area. This process in a bacteria network is in way more complex than that, because theres no communication between only two cells in a specific point of the space, but between various populations of bacterias that have movement , in other words, there is no specific point in space where you can observe the same phenomenon in different moments.

In order to give an specific addressing to the bacterial population, a system will be constructed in a way to make 9 different E. coli populations communicate with each other and keep their positions. The system allow communications not only between neighbors, integrating signal coming from the hole system, activating or inhibiting the answer of the cell according to the specific memory established. (figura)

This system have 96 cavities with permeable membranes that allows the exchange of signals by "quorun sense" substances, but keeps the populations in a specific location. In other words, in allows the communication, but not the mix of different populations, keeping the signals uniform accordingly to its origins.

The Experiments

Part 3

Results