GFtbox Tutorial pages: Difference between revisions
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Basic interaction function | Basic interaction function | ||
The '''Mesh''' was setup using the GUI and ''' | The '''Mesh''' was setup using the GUI and code articulating the regulatory model was edited into the ''''interaction function''' as follows: | ||
if (Steps(m)==0) && m.globalDynamicProps.doinit % Initialisation code. | if (Steps(m)==0) && m.globalDynamicProps.doinit % Initialisation code. | ||
id_a_p(m.nodes(:,1)<-0.03)=1; % setup region for A where identity factor A is represented by id_a_p | id_a_p(m.nodes(:,1)<-0.03)=1; % setup region for A where identity factor A is represented by id_a_p |
Revision as of 11:22, 1 June 2011
Three ways to use GFtbox
1) Doing everything from the Graphical User Interface (GUI). See here for the best way to start working with GFtbox
2) Do only some things from the GUI. See here for the best way to develop ideas on the growth of shape. Use the GUI to generate the mesh (canvas) and create growth factors (morphogens - in other words declare the variables) but capturing your ideas on how the regulatory processes work in, what we call, the interaction function.
For an introduction to the output and results, see here.
3) Without the GUI. Running models without the GUI, see here. For example, run many examples (instances) of a pre-existing project on a cluster. This is the best way to explore the parameter space of a model for comparison with biological observations. We use this extensively once we have roughed out the basic ideas interactively.
1 Modelling using the Graphical User Interface
Isotropic growth
1 A
For tutorial on uniform growth click here. Consider a disc shaped canvas (tissue) in which the specified growth is uniform, isotropic and on both sides. Into what shape will the disc grow? This model is as simple as it gets. Notice that, during growth, the mesh is automatically subdivided. Notice also that the final surface is not quite flat. This is because, to allow it to deform in 3D, it is not flat initially. There are options to initialise a flat mesh and others to force it to remain flat - see options on the GUI (hover over controls to get prompts). In the absence of a polariser (there is no polariser in this example) growth will be isotropic, in other words growth in the plane of the canvas will be the average of what is specified for Kapar and Kaper (A side) and Kbpar and Kbper (B side). |
<wikiflv width="300" height="300" logo="false" loop="true" background="white">GPT_tut_uniform_20110527-0003.flv|GPT_tut_uniform_20110527-0003_Last.png</wikiflv> |
1 B
For tutorial on non-uniform growth click here Consider a disc shaped canvas (tissue) in which the non-uniform specified growth increases in proportion to the distance from the centre. Into what shape will the disc grow? Already we are into the realms of modelling biological systems. Compare this result with the discussion of Lily petals and Gaussian curvature (Lianga and Mahadevana,Sharon, Marder and Swinney,Nath, Crawford, Carpenter and Coen ). |
<wikiflv width="300" height="300" logo="false" loop="true" background="white">GPT_tut_uniform_20110527-0006.flv|GPT_tut_uniform_20110527-0006_First.png</wikiflv>
Note: this model should have many more finite elements |
Adding polariser
1 C
For tutorial on uniform growth non-uniform polariser click here In the presence of polariser, GFtbox growth will be anisotropic, in other words growth in the plane of the canvas can be different parallel and perpendicular to the axis of the polariser: Kapar and Kaper (A side) and Kbpar and Kbper (B side). |
<wikiflv width="300" height="300" logo="false" loop="true" background="white">GPT_in_the_beginning_2_20110510-0003.flv|GPT_in_the_beginning_2_20110510-0003_First.png</wikiflv>Note: the gradient of the polariser, green to cyan, is shown using the arrows. Specified growth rate parallel to the arrows, red, is uniform. |
2 Modelling using a combination of GUI and interaction function
Interaction functions - programmatic modelling.
The full specification of a GFtbox model is stored in a combination of the mesh data structure (Mesh) and the interaction function. The Mesh stores all the physical properties of the system: spatial structure, mechanical properties, etc. It is usually set up using the GUI. The Mesh is stored on disc as a Matlab data file (.mat) and in memory as a data structure (m). The interaction function (a Matlab program file .m) contains all the details of the growth regulation system: morphogen concentrations, signal interactions etc.
When a new project is first edited the interaction function is generated automatically. Thereafter, it is automatically kept in synchrony with the GUI. It is divided into several sections. Some are generated automatically and should not be edited. Others are set aside for the user to specify the model. To ensure that the automatic and manual edits are synchronised always invoke the Editor from the GUI (Panel: Interaction Function: Edit).
2 A
Basic interaction function The Mesh was setup using the GUI and code articulating the regulatory model was edited into the 'interaction function as follows:
if (Steps(m)==0) && m.globalDynamicProps.doinit % Initialisation code. id_a_p(m.nodes(:,1)<-0.03)=1; % setup region for A where identity factor A is represented by id_a_p id_b_p(m.nodes(:,2)<-0.01)=1; % setup region for B else % @@KRN Growth Regulatory Network kapar_p(:) = id_a_l .* inh(1,id_b_l); % growth rate kaper_p(:) = kapar_p; % isotropic growth kbpar_p(:) = kapar_p; % same on both sides of the sheet kbper_p(:) = kapar_p; % same knor_p(:) = 0; % thickness not growing end
For tutorial on a basic interaction function click here The tutorial explains how the code shown above appears in the interaction function. |
<wikiflv width="300" height="300" logo="false" loop="true">GPT_why_matlab-2011-05-05-0005.flv|GPT_why_matlab-2011-05-05-0005_First.png</wikiflv> |
Details |
2 B
Interaction function in detail (A newly created, empty, interaction function is shown here.)
Tutorial on the interaction function details click here |
<wikiflv width="300" height="300" logo="false" loop="true">GPT_why_matlab-2011-05-05-0005.flv|GPT_why_matlab-2011-05-05-0005_First.png</wikiflv> |
Submodel 2 | <wikiflv width="300" height="300" logo="false" loop="true">GPT_why_matlab-2011-05-05-0005.flv|GPT_why_matlab-2011-05-05-0005_First.png</wikiflv> |
Output and Results
2 C Illustrating two independent ways to form shapes and the use of submodels.
Conclusion: interesting shapes can be generated either by patterns of differential growth or patterns of local growth axes.
Tutorial on two romatic hearts click here
Submodel 1.Uniform specified polariser (no polariser gradient). Creating a shape using a specified pattern of isotropic growth. Result: simple patterns can readily produce blobby shapes. |
<wikiflv width="300" height="300" logo="false" loop="true">GPT_TwoWayHeart_20110531-0001.flv|GPT_TwoWayHeart_20110531-0001_Last.png</wikiflv> |
Submodel 2.Uniform specified growth. Creating a shape using a specified pattern of diffusable polariser. Result: simple patterns can readily produce sharp shapes. |
<wikiflv width="300" height="300" logo="false" loop="true">GPT_TwoWayHeart_20110531-0002.flv|GPT_TwoWayHeart_20110531-0002_Last.png</wikiflv> |
3 Running models without the GUI
Having developed the concepts underpinning a pattern of growth in an interaction function it is often desirable to explore a range of model parameters. Given that each run of the model can take between 5 minutes and hour it is appropriate to run the models in parallel on a computing cluster. (Each node of the cluster to be used by GFtbox needs to be licensed to run Matlab - however for the purpose of running on a cluster without the GUI we are exploring the possibility of making GFtbox compatible with Octave.)