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

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The inhibition or excitement of GFP production will be based on a transcriptional regulation mechanism.  The communication between bacterial populations will occur by means of quorum sensing substances and the information (inhibiting or exciting) will be defined by which transcriptional regulator the substance will promote. In summary, at the moment when the connections between the neurons are defined, we hope the system will output a predetermined pattern of answer.
The inhibition or excitement of GFP production will be based on a transcriptional regulation mechanism.  The communication between bacterial populations will occur by means of quorum sensing substances and the information (inhibiting or exciting) will be defined by which transcriptional regulator the substance will promote. In summary, at the moment when the connections between the neurons are defined, we hope the system will output a predetermined pattern of answer.
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In addition to be one of the first Hopfield Network model made in vivo, this project shows different lineages of bacteria communicating with each other using its “systemic memories” in order to establish a balance. This could be used in the production of bio products, such as biofuels, in a way that, for example, inside a reactor, a bio system responsible for the production of a certain compound could auto regulates itself when some parameter changes, such as temperature or nutrients concentration. It would use its systemic memory, communicating within its network and restoring the pattern. In future, self-controlled bio systems will be able to be possible cheap and ecologically friendly alternatives in the industry.
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In addition to be one of the first Hopfield Network model made in vivo, this project shows different lineages of bacteria communicating with each other, establishing balance through their systemic memory. This could be useful in the production of bioproducts, such as biofuels - for instance, a biosystem producing some compound inside a reactor could regulate itself according to specific parameter changes, such as temperature or nutrient concentration - it would perform that by communicating within its network and restoring the pattern stored in its ystemic memory. In the future, self-controlled biosystems will be possible, cheap and ecologically friendly alternatives for the industry.

Revision as of 02:38, 25 September 2012