Team:ETHZ Basel/InformationProcessing

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(Difference between revisions)
(Information Processing Overview)
(Information Processing Overview)
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Although the synthetic network we implemented makes the tumbling frequency of an E. coli cells dependent on red and far-red light, the biological part alone is not sufficient to control the swimming direction of the E. lemming. Thus, it is complemented by an in-silico network realizing a controller which automatically sends the light signals and, by thus time-dependently changing the tumbling frequency, forces the cell to swim in a desired direction. The interface between the two sub-networks, the genetic network and the in-silico network, is defined as the current microscope image (in-vivo -> in-silico) and the red and far-red light signals (in-silico -> in-vivo). By interconnecting both sub-networks, we thus can close the loop and obtain the overall network, which allows us to increase the information processing capabilities significantly compared to traditional synthetic networks completely realized in-vivo.
Although the synthetic network we implemented makes the tumbling frequency of an E. coli cells dependent on red and far-red light, the biological part alone is not sufficient to control the swimming direction of the E. lemming. Thus, it is complemented by an in-silico network realizing a controller which automatically sends the light signals and, by thus time-dependently changing the tumbling frequency, forces the cell to swim in a desired direction. The interface between the two sub-networks, the genetic network and the in-silico network, is defined as the current microscope image (in-vivo -> in-silico) and the red and far-red light signals (in-silico -> in-vivo). By interconnecting both sub-networks, we thus can close the loop and obtain the overall network, which allows us to increase the information processing capabilities significantly compared to traditional synthetic networks completely realized in-vivo.
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In this section we will describe in detail the in-silico part of the network. For the in-vivo part, we refer to the [[Team:ETHZ_Basel/Biology | Biology & Wet Laboratory]] section.
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In this section we will describe in detail the in-silico part of the network. For the in-vivo part, we refer to the [[Team:ETHZ_Basel/Biology | Biology & Wet Laboratory]] section.<br clear="all" />
== Short Overview ==
== Short Overview ==
The cells are placed in a 50 &mu;m (?) high flow channel restricting their movement to the x/y-plane, thus preventing them from swimming out of focus. They are imaged in bright field by an automatized microscope with 40x magnification approximately every 0.3s. The image is send via a local network or the internet to the controller workstation, which forwards them to Matlab/Simulink. There, the images are pre-processed by the Lemming Toolbox and the cells are detected and tracked in real-time. From the change of position between the microscope frames the current direction of the E. lemming is estimated. Furthermore, the Toolbox is connected to a joystick with which the user can choose the cell he wants to control and interactively define the reference direction for the E. lemming. Together with the actual direction of the cell the reference direction forms the input of the actual control algorithm. This algorithm decides, based on the actual and previous directions of the cell and the difference to the reference direction, when to send red or far-red light. This decision is then send back through the network to the microscope computer, which activates or deactivates the respective diodes, thus closing the loop between the in-silico and in-vivo part of the network. Furthermore the controller detects if a cell is swimming out of the field of vision of the microscope and automatically adjusts the position of the x/y-stage. Finally, the microscope image is post-processed to show the position of all cells, the selected cell and its current and reference direction, and visualized on the computer screen or with a beamer.
The cells are placed in a 50 &mu;m (?) high flow channel restricting their movement to the x/y-plane, thus preventing them from swimming out of focus. They are imaged in bright field by an automatized microscope with 40x magnification approximately every 0.3s. The image is send via a local network or the internet to the controller workstation, which forwards them to Matlab/Simulink. There, the images are pre-processed by the Lemming Toolbox and the cells are detected and tracked in real-time. From the change of position between the microscope frames the current direction of the E. lemming is estimated. Furthermore, the Toolbox is connected to a joystick with which the user can choose the cell he wants to control and interactively define the reference direction for the E. lemming. Together with the actual direction of the cell the reference direction forms the input of the actual control algorithm. This algorithm decides, based on the actual and previous directions of the cell and the difference to the reference direction, when to send red or far-red light. This decision is then send back through the network to the microscope computer, which activates or deactivates the respective diodes, thus closing the loop between the in-silico and in-vivo part of the network. Furthermore the controller detects if a cell is swimming out of the field of vision of the microscope and automatically adjusts the position of the x/y-stage. Finally, the microscope image is post-processed to show the position of all cells, the selected cell and its current and reference direction, and visualized on the computer screen or with a beamer.

Revision as of 19:59, 14 October 2010

Information Processing Overview

Information processing principle of E. lemming. Tumbling / directed movement rates are monitored by image processing algorithms, which are linked to the light-pulse generator. This means that E. coli tumbling is induced or suppressed simply by pressing a light switch! This synthetic network enables control of single E. coli cells.
Although the synthetic network we implemented makes the tumbling frequency of an E. coli cells dependent on red and far-red light, the biological part alone is not sufficient to control the swimming direction of the E. lemming. Thus, it is complemented by an in-silico network realizing a controller which automatically sends the light signals and, by thus time-dependently changing the tumbling frequency, forces the cell to swim in a desired direction. The interface between the two sub-networks, the genetic network and the in-silico network, is defined as the current microscope image (in-vivo -> in-silico) and the red and far-red light signals (in-silico -> in-vivo). By interconnecting both sub-networks, we thus can close the loop and obtain the overall network, which allows us to increase the information processing capabilities significantly compared to traditional synthetic networks completely realized in-vivo.

In this section we will describe in detail the in-silico part of the network. For the in-vivo part, we refer to the Biology & Wet Laboratory section.

Short Overview

The cells are placed in a 50 μm (?) high flow channel restricting their movement to the x/y-plane, thus preventing them from swimming out of focus. They are imaged in bright field by an automatized microscope with 40x magnification approximately every 0.3s. The image is send via a local network or the internet to the controller workstation, which forwards them to Matlab/Simulink. There, the images are pre-processed by the Lemming Toolbox and the cells are detected and tracked in real-time. From the change of position between the microscope frames the current direction of the E. lemming is estimated. Furthermore, the Toolbox is connected to a joystick with which the user can choose the cell he wants to control and interactively define the reference direction for the E. lemming. Together with the actual direction of the cell the reference direction forms the input of the actual control algorithm. This algorithm decides, based on the actual and previous directions of the cell and the difference to the reference direction, when to send red or far-red light. This decision is then send back through the network to the microscope computer, which activates or deactivates the respective diodes, thus closing the loop between the in-silico and in-vivo part of the network. Furthermore the controller detects if a cell is swimming out of the field of vision of the microscope and automatically adjusts the position of the x/y-stage. Finally, the microscope image is post-processed to show the position of all cells, the selected cell and its current and reference direction, and visualized on the computer screen or with a beamer.