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Team:Sevilla
From 2011.igem.org
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<img style="z-index:-4;margin-left:-45px;margin-top:-30px" src="https://static.igem.org/mediawiki/2011/c/ce/Approach.png" /> | <img style="z-index:-4;margin-left:-45px;margin-top:-30px" src="https://static.igem.org/mediawiki/2011/c/ce/Approach.png" /> | ||
| - | <input type="button" value="Español" onclick="$('#textEng').html(' | + | <input type="button" value="Español" onclick="$('#textEng').html('Nuestro proyecto es bastante ambicioso, pero creemos que es asequible. Vamos a construir circuitos basados en conjuntos de distintas estirpes de bacterias, donde cada estirpe cumpla la función de una puerta lógica (los componentes básicos de un circuito electrónico, como AND, OR o XOR), y cada estirpe intercambie información con las demás. Combinando las estirpes adecuadas, y usando determinadas sustancias químicas como inputs del sistema, podemos hacer que una comunidad bacteriana desempeñe funciones complejas.Para lograr nuestra meta, vamos a definir un estándar de programación de circuitos biológicos modularizado: una comunidad de bacterias (varias estirpes interrelacionas) forman un módulo físicamente independiente. La combinación de varios módulos permite realizar operaciones mucho más complejas de las que jamás se podrían conseguir en un medio continuo, ya que la modularización permite el reciclaje de estirpes y de sustancias. Para implementar este sistema, la clave es estandarizar las sustancias de comunicación intermodulares, y eso es lo que vamos a hacer, definir una sustancia, a la que bautizaremos como Ubbit (de Universal BioBit) que será la sustancia de comunicación entre módulos. Así, cualquier grupo de investigación podrá usar los módulos creados por otro grupo y combinarlos con los suyos propios sin necesidad de conocer su funcionamiento interno, sólo hace falta que ambos se acojan al estándar Ubbit.')"> |
| - | Nuestro proyecto es bastante ambicioso, pero creemos que es asequible. Vamos a construir circuitos basados en conjuntos de distintas estirpes de bacterias, donde cada estirpe cumpla la función de una puerta lógica (los componentes básicos de un circuito electrónico, como AND, OR o XOR), y cada estirpe intercambie información con las demás. Combinando las estirpes adecuadas, y usando determinadas sustancias químicas como inputs del sistema, podemos hacer que una comunidad bacteriana desempeñe funciones complejas.Para lograr nuestra meta, vamos a definir un estándar de programación de circuitos biológicos modularizado: una comunidad de bacterias (varias estirpes interrelacionas) forman un módulo físicamente independiente. La combinación de varios módulos permite realizar operaciones mucho más complejas de las que jamás se podrían conseguir en un medio continuo, ya que la modularización permite el reciclaje de estirpes y de sustancias. Para implementar este sistema, la clave es estandarizar las sustancias de comunicación intermodulares, y eso es lo que vamos a hacer, definir una sustancia, a la que bautizaremos como Ubbit (de Universal BioBit) que será la sustancia de comunicación entre módulos. Así, cualquier grupo de investigación podrá usar los módulos creados por otro grupo y combinarlos con los suyos propios sin necesidad de conocer su funcionamiento interno, sólo hace falta que ambos se acojan al estándar Ubbit. | + | |
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| - | <button type="button" onclick="$('#textEng').html(' | + | <button type="button" onclick="$('#textEng').html('<p>We are going to build circuits based on collections of different bacteria strains, where each strain works as a logic gate. A logic gate is the basic component of an electronic circuit, such as AND, OR or XOR, and it exchanges information with the others.Combining the correct strains and using certain chemical substances as system inputs we can manipulate a bacterial community into performing complex functions.</p><p>To achieve our goal we are going to define a standard of programming modularized biological circuits, where a community of bacteria -from different but interconnected strains- form a physically independent module. Combining different modules in this way makes it possible to recycle strains and substances. To implement this system, the key is to standardise the inter-modular communication substances. This is exactly what we are going to do: we are going to define a substance, which we have named the Ubbit Standard (from Universal BioBit), that will be the element of communication between modules. Just like that, any research group could use the modules created by any other group and combine them with their own without the necessity of knowing how it internally works, just by using the Ubbit standard.</p>')">English</button> |
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| - | We are going to build circuits based on collections of different bacteria strains, where each strain works as a logic gate. A logic gate is the basic component of an electronic circuit, such as AND, OR or XOR, and it exchanges information with the others.Combining the correct strains and using certain chemical substances as system inputs we can manipulate a bacterial community into performing complex functions. | + | |
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| - | <p> | + | |
| - | To achieve our goal we are going to define a standard of programming modularized biological circuits, where a community of bacteria -from different but interconnected strains- form a physically independent module. Combining different modules in this way makes it possible to recycle strains and substances. To implement this system, the key is to standardise the inter-modular communication substances. This is exactly what we are going to do: we are going to define a substance, which we have named the Ubbit Standard (from Universal BioBit), that will be the element of communication between modules. Just like that, any research group could use the modules created by any other group and combine them with their own without the necessity of knowing how it internally works, just by using the Ubbit standard. | + | |
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| - | ')">English</button> | + | |
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Revision as of 14:36, 30 June 2011
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We are going to build circuits based on collections of different bacteria strains, where each strain works as a logic gate. A logic gate is the basic component of an electronic circuit, such as AND, OR or XOR, and it exchanges information with the others.Combining the correct strains and using certain chemical substances as system inputs we can manipulate a bacterial community into performing complex functions.
To achieve our goal we are going to define a standard of programming modularized biological circuits, where a community of bacteria -from different but interconnected strains- form a physically independent module. Combining different modules in this way makes it possible to recycle strains and substances. To implement this system, the key is to standardise the inter-modular communication substances. This is exactly what we are going to do: we are going to define a substance, which we have named the Ubbit Standard (from Universal BioBit), that will be the element of communication between modules. Just like that, any research group could use the modules created by any other group and combine them with their own without the necessity of knowing how it internally works, just by using the Ubbit standard.
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