示例#1
0
    def test_construct(self):

        file_handler = chaste.core.OutputFileHandler(
            "Python/TestMeshBasedCellPopulation")

        mesh_generator = chaste.mesh.HoneycombMeshGenerator(2, 2)
        mesh = mesh_generator.GetMesh()

        # Make the cells
        proliferative_type = chaste.cell_based.DefaultCellProliferativeType()
        cell_generator = chaste.cell_based.CellsGeneratorUniformCellCycleModel_2(
        )
        cells = cell_generator.GenerateBasicRandom(mesh.GetNumNodes(),
                                                   proliferative_type)

        # Make the cell population
        cell_population = chaste.cell_based.MeshBasedCellPopulation2_2(
            mesh, cells)
        cell_population.AddPopulationWriterVoronoiDataWriter()

        # Set up the visualizer
        scene = chaste.visualization.VtkScene2()
        scene.SetCellPopulation(cell_population)
        scene.SetSaveAsAnimation(True)
        scene.SetOutputFilePath(file_handler.GetOutputDirectoryFullPath() +
                                "/cell_population")

        modifier = chaste.cell_based.VtkSceneModifier2()
        modifier.SetVtkScene(scene)

        # Set up the simulation
        simulator = chaste.cell_based.OffLatticeSimulation2_2(cell_population)
        simulator.SetOutputDirectory("Python/TestMeshBasedCellPopulation")
        simulator.SetEndTime(5.0)
        simulator.SetSamplingTimestepMultiple(12)

        force = chaste.cell_based.GeneralisedLinearSpringForce2_2()
        simulator.AddForce(force)
        simulator.AddSimulationModifier(modifier)
        simulator.Solve()
    def test_monolayer(self):

        # JUPYTER_SETUP

        ## Next, we generate a mutable mesh. To create a `MutableMesh`, we can use the `HoneycombMeshGenerator`.
        ## This generates a honeycomb-shaped mesh, in which all nodes are equidistant. Here the first and second arguments define the size of the mesh -
        ## we have chosen a mesh that is 4 nodes (i.e. cells) wide, and 4 nodes high.

        chaste.core.OutputFileHandler(
            "Python/TestMeshBasedCellSimulationsTutorial")
        generator = chaste.mesh.HoneycombMeshGenerator(4, 4)
        mesh = generator.GetMesh()

        ## Having created a mesh, we now create some cells. To do this, we use the `CellsGenerator` helper class,
        ## which is specialized by the type of cell cycle model required (here `UniformCellCycleModel`) and the dimension.
        ## For a list of possible cell cycle models see subclasses of `AbstractCellCycleModel`.
        ## Note that some of these models will require information on the surrounding medium such as Oxygen concentration to work,
        ## see specific class documentation for details. We create an empty vector of cells and pass this into the method along with the mesh.
        ## The second argument represents the size of that the list of cells should become - one cell for each node,
        ## the third argument specifies the proliferative type of the cell.

        transit_type = chaste.cell_based.TransitCellProliferativeType()
        cell_generator = chaste.cell_based.CellsGeneratorUniformCellCycleModel_2(
        )
        cells = cell_generator.GenerateBasicRandom(mesh.GetNumNodes(),
                                                   transit_type)

        ## Now we have a mesh and a set of cells to go with it, we can create a `CellPopulation`.
        ## In general, this class associates a collection of cells with a mesh. For this test, because we have a `MutableMesh`,
        ## we use a particular type of cell population called a `MeshBasedCellPopulation`.

        cell_population = chaste.cell_based.MeshBasedCellPopulation2_2(
            mesh, cells)

        ## To view the results of this and the next test in Paraview it is necessary to explicitly
        ## generate the required .vtu files.

        cell_population.AddPopulationWriterVoronoiDataWriter()

        ## We can set up a `VtkScene` to do a quick visualization of the population before running the analysis.

        scene = chaste.visualization.VtkScene2()
        scene.SetCellPopulation(cell_population)
        # JUPYTER_SHOW_FIRST
        scene.Start()  # JUPYTER_SHOW

        ## We then pass in the cell population into an `OffLatticeSimulation`, and set the output directory and end time.

        simulator = chaste.cell_based.OffLatticeSimulation2_2(cell_population)
        simulator.SetOutputDirectory(
            "Python/TestMeshBasedCellSimulationsTutorial")
        simulator.SetEndTime(10.0)

        ## For longer simulations, we may not want to output the results every time step. In this case we can use the following method,
        ## to print results every 12 time steps instead. As the default time step used by the simulator is 30 seconds,
        ## this method will cause the simulator to print results every 6 minutes (or 0.1 hours).

        simulator.SetSamplingTimestepMultiple(12)

        ## We must now create one or more force laws, which determine the mechanics of the centres of each cell in a cell population.
        ## For this test, we use one force law, based on the spring based model, and pass it to the `OffLatticeSimulation`.
        ## For a list of possible forces see subclasses of `AbstractForce`. Note that some of these forces are not compatible with mesh-based simulations,
        ## see the specific class documentation for details. If you try to use an incompatible class then you will receive a warning.

        force = chaste.cell_based.GeneralisedLinearSpringForce2_2()
        simulator.AddForce(force)

        ## Save snapshot images of the population during the simulation

        scene_modifier = chaste.cell_based.VtkSceneModifier2()
        scene_modifier.SetVtkScene(scene)
        scene_modifier.SetUpdateFrequency(100)
        simulator.AddSimulationModifier(scene_modifier)

        ## To run the simulation, we call `Solve()`. We can again do a quick rendering of the population at the end of the simulation

        scene.Start()
        simulator.Solve()
        scene.End()
    def test_monolayer(self):

        # JUPYTER_SETUP

        ## The first thing we do is generate a nodes only mesh. To do this we first create a `MutableMesh` to use as a generating mesh.
        ## To do this we can use the `HoneycombMeshGenerator`. This generates a honeycomb-shaped mesh, in which all nodes are equidistant.
        ## Here the first and second arguments define the size of the mesh - we have chosen a mesh that is 2 nodes (i.e. cells) wide, and 2 nodes high.

        chaste.core.OutputFileHandler(
            "Python/TestNodeBasedCellSimulationsTutorial")
        generator = chaste.mesh.HoneycombMeshGenerator(2, 2)
        generating_mesh = generator.GetMesh()

        ## Once we have a MutableMesh we can generate a NodesOnlyMesh from it using the following commands.
        ## Note you can also generate the NodesOnlyMesh from a collection of nodes.

        mesh = chaste.mesh.NodesOnlyMesh2()

        ## To run node-based simulations you need to define a cut off length (second argument in `ConstructNodesWithoutMesh`),
        ## which defines the connectivity of the nodes by defining a radius of interaction.

        mesh.ConstructNodesWithoutMesh(generating_mesh, 1.5)

        ## Having created a mesh, we now create a (wrapped) vector of CellPtrs. To do this, we use the `CellsGenerator` helper class,
        ## which is specialized for the type of cell model required (here `UniformCellCycleModel`) and the dimension.
        ## We create an empty vector of cells and pass this into the method along with the mesh.
        ## The second argument represents the size of that the vector cells should become - one cell for each node,
        ## the third argument specifies the proliferative type of the cell.

        transit_type = chaste.cell_based.TransitCellProliferativeType()
        cell_generator = chaste.cell_based.CellsGeneratorUniformCellCycleModel_2(
        )
        cells = cell_generator.GenerateBasicRandom(mesh.GetNumNodes(),
                                                   transit_type)

        ## Now we have a mesh and a set of cells to go with it, we can create a `CellPopulation`.
        ## In general, this class associates a collection of cells with a mesh. For this test,
        ## because we have a `NodesOnlyMesh`, we use a particular type of cell population called a `NodeBasedCellPopulation`.

        cell_population = chaste.cell_based.NodeBasedCellPopulation2(
            mesh, cells)

        ## We can set up a `VtkScene` to do a quick visualization of the population before running the analysis.

        scene = chaste.visualization.VtkScene2()
        scene.SetCellPopulation(cell_population)
        # JUPYTER_SHOW_FIRST
        scene.Start()  # JUPYTER_SHOW

        ## We then pass in the cell population into an `OffLatticeSimulation`, and set the output directory, output multiple and end time

        simulator = chaste.cell_based.OffLatticeSimulation2_2(cell_population)
        simulator.SetOutputDirectory(
            "Python/TestNodeBasedCellSimulationsTutorial")
        simulator.SetSamplingTimestepMultiple(100)
        simulator.SetEndTime(10.0)

        ## We now pass a force law to the simulation.

        force = chaste.cell_based.GeneralisedLinearSpringForce2_2()
        simulator.AddForce(force)

        ## Save snapshot images of the population during the simulation

        scene_modifier = chaste.cell_based.VtkSceneModifier2()
        scene_modifier.SetVtkScene(scene)
        scene_modifier.SetUpdateFrequency(100)
        simulator.AddSimulationModifier(scene_modifier)

        ## To run the simulation, we call `Solve()`. We can again do a quick rendering of the population at the end of the simulation

        scene.Start()
        simulator.Solve()
        scene.End()

        ## The next two lines are for test purposes only and are not part of this tutorial.
        ## If different simulation input parameters are being explored the lines should be removed.

        self.assertEqual(cell_population.GetNumRealCells(), 8)
        self.assertAlmostEqual(
            chaste.cell_based.SimulationTime.Instance().GetTime(), 10.0, 6)
    def test_spheroid_on_sphere(self):

        # JUPYTER_SETUP

        ## In the third test we run a node-based simulation restricted to the surface of a sphere.

        chaste.core.OutputFileHandler(
            "Python/TestNodeBasedCellSimulationsRestrictedSpheroidTutorial")
        nodes = []
        nodes.append(chaste.mesh.Node3(0, False, 0.5, 0.0, 0.0))
        nodes.append(chaste.mesh.Node3(1, False, -0.5, 0.0, 0.0))
        nodes.append(chaste.mesh.Node3(2, False, 0.0, 0.5, 0.0))
        nodes.append(chaste.mesh.Node3(3, False, 0.0, -0.5, 0.0))
        mesh = chaste.mesh.NodesOnlyMesh3()

        ## To run node-based simulations you need to define a cut off length (second argument in ConstructNodesWithoutMesh),
        ## which defines the connectivity of the nodes by defining a radius of interaction.

        mesh.ConstructNodesWithoutMesh(nodes, 1.5)

        transit_type = chaste.cell_based.TransitCellProliferativeType()
        cell_generator = chaste.cell_based.CellsGeneratorUniformCellCycleModel_3(
        )
        cells = cell_generator.GenerateBasicRandom(mesh.GetNumNodes(),
                                                   transit_type)
        cell_population = chaste.cell_based.NodeBasedCellPopulation3(
            mesh, cells)

        ## We can set up a `VtkScene` to do a quick visualization of the population before running the analysis.

        scene = chaste.visualization.VtkScene3()
        scene.SetCellPopulation(cell_population)
        scene.Start()  # JUPYTER_SHOW

        simulator = chaste.cell_based.OffLatticeSimulation3_3(cell_population)
        simulator.SetOutputDirectory(
            "Python/TestNodeBasedCellSimulationsRestrictedSpheroidTutorial")
        simulator.SetSamplingTimestepMultiple(12)
        simulator.SetEndTime(10.0)

        ## We now pass a force law to the simulation.

        force = chaste.cell_based.GeneralisedLinearSpringForce3_3()
        simulator.AddForce(force)

        ## This time we create a CellPopulationBoundaryCondition and pass this to the OffLatticeSimulation.
        ## Here we use a SphereGeometryBoundaryCondition which restricts cells to lie on a sphere (in 3D) or circle (in 2D).
        ## For a list of possible boundary conditions see subclasses of AbstractCellPopulationBoundaryCondition.
        ## Note that some of these boundary conditions are not compatible with node-based simulations see the specific class documentation
        ## for details, if you try to use an incompatible class then you will receive a warning.
        ## First we set the centre (0,0,1) and radius of the sphere (1).

        centre = np.array([0.0, 0.0, 1.0])
        radius = 5.0
        point2 = chaste.mesh.ChastePoint3(centre)
        boundary_condition = chaste.cell_based.SphereGeometryBoundaryCondition3(
            cell_population, point2.rGetLocation(), radius)
        simulator.AddCellPopulationBoundaryCondition(boundary_condition)

        ## Save snapshot images of the population during the simulation
        scene_modifier = chaste.cell_based.VtkSceneModifier3()
        scene_modifier.SetVtkScene(scene)
        scene_modifier.SetUpdateFrequency(100)
        simulator.AddSimulationModifier(scene_modifier)

        ## To run the simulation, we call `Solve()`. We can again do a quick rendering of the population at the end of the simulation

        scene.Start()
        simulator.Solve()
        scene.End()

        ## The next two lines are for test purposes only and are not part of this tutorial.
        ## If different simulation input parameters are being explored the lines should be removed.

        self.assertEqual(cell_population.GetNumRealCells(), 8)
        self.assertAlmostEqual(
            chaste.cell_based.SimulationTime.Instance().GetTime(), 10.0, 6)
    def test_spheroid(self):

        # JUPYTER_SETUP

        ## First, we generate a nodes only mesh. This time we specify the nodes manually by first creating a vector of nodes

        chaste.core.OutputFileHandler(
            "Python/TestNodeBasedCellSimulationsSpheroidTutorial")
        nodes = []
        nodes.append(chaste.mesh.Node3(0, False, 0.5, 0.0, 0.0))
        nodes.append(chaste.mesh.Node3(1, False, -0.5, 0.0, 0.0))
        nodes.append(chaste.mesh.Node3(2, False, 0.0, 0.5, 0.0))
        nodes.append(chaste.mesh.Node3(3, False, 0.0, -0.5, 0.0))

        ## Finally a NodesOnlyMesh is created and the vector of nodes is passed to the ConstructNodesWithoutMesh method.

        mesh = chaste.mesh.NodesOnlyMesh3()

        ## To run node-based simulations you need to define a cut off length (second argument in ConstructNodesWithoutMesh),
        ## which defines the connectivity of the nodes by defining a radius of interaction.

        mesh.ConstructNodesWithoutMesh(nodes, 1.5)

        ## Having created a mesh, we now create a std::vector of CellPtrs.
        ## As before, we do this with the CellsGenerator helper class (this time with dimension 3).

        transit_type = chaste.cell_based.TransitCellProliferativeType()
        cell_generator = chaste.cell_based.CellsGeneratorUniformCellCycleModel_3(
        )
        cells = cell_generator.GenerateBasicRandom(mesh.GetNumNodes(),
                                                   transit_type)

        ## Now we have a mesh and a set of cells to go with it, we can create a `CellPopulation`.
        ## In general, this class associates a collection of cells with a mesh. For this test,
        ## because we have a `NodesOnlyMesh`, we use a particular type of cell population called a `NodeBasedCellPopulation`.

        cell_population = chaste.cell_based.NodeBasedCellPopulation3(
            mesh, cells)

        ## We can set up a `VtkScene` to do a quick visualization of the population before running the analysis.

        scene = chaste.visualization.VtkScene3()
        scene.SetCellPopulation(cell_population)
        scene.Start()  # JUPYTER_SHOW

        ## We then pass in the cell population into an `OffLatticeSimulation`, and set the output directory, output multiple and end time

        simulator = chaste.cell_based.OffLatticeSimulation3_3(cell_population)
        simulator.SetOutputDirectory(
            "Python/TestNodeBasedCellSimulationsSpheroidTutorial")
        simulator.SetSamplingTimestepMultiple(12)
        simulator.SetEndTime(10.0)

        ## We now pass a force law to the simulation.

        force = chaste.cell_based.GeneralisedLinearSpringForce3_3()
        simulator.AddForce(force)

        ## Save snapshot images of the population during the simulation

        scene_modifier = chaste.cell_based.VtkSceneModifier3()
        scene_modifier.SetVtkScene(scene)
        scene_modifier.SetUpdateFrequency(100)
        simulator.AddSimulationModifier(scene_modifier)

        ## To run the simulation, we call `Solve()`. We can again do a quick rendering of the population at the end of the simulation

        scene.Start()
        simulator.Solve()
        scene.End()

        ## The next two lines are for test purposes only and are not part of this tutorial.
        ## If different simulation input parameters are being explored the lines should be removed.

        self.assertEqual(cell_population.GetNumRealCells(), 8)
        self.assertAlmostEqual(
            chaste.cell_based.SimulationTime.Instance().GetTime(), 10.0, 6)
示例#6
0
 def test_construct(self):
     generator = chaste.mesh.PottsMeshGenerator3(10, 0, 0, 10, 0, 0, 10, 0, 0)
     mesh = generator.GetMesh()
     self.assertEqual(mesh.GetNumNodes(), 1000)
示例#7
0
    def test_spheroid(self):

        # JUPYTER_SETUP

        ## This time we will use on off-lattice `MeshBased` cell population. Cell centres are joined with
        ## springs with a Delauney Triangulation used to identify neighbours. Cell area is given by the dual
        ## (Voronoi Tesselation). We start off with a small number of cells. We use a `MutableMesh` which
        ## can change connectivity over time and a `HoneycombMeshGenerator` to set it up with a simple
        ## honeycomb pattern. Here the first and second arguments define the size of the mesh -
        ## we have chosen a mesh that is 5 nodes (i.e. cells) wide, and 5 nodes high. The extra '2' argument puts
        ## two layers of non-cell elements around the mesh, which help to form a nicer voronoi tesselation
        ## for area calculations.

        chaste.core.OutputFileHandler("Python/TestSpheroidTutorial")
        generator = chaste.mesh.HoneycombMeshGenerator(5, 5)
        mesh = generator.GetMesh()

        ## We create some cells next, with a stem-like proliferative type. This means they will continually
        ## proliferate if there is enough oxygen, similar to how a tumour spheroid may behave.

        stem_type = chaste.cell_based.StemCellProliferativeType()
        cell_generator = chaste.cell_based.CellsGeneratorSimpleOxygenBasedCellCycleModel_2(
        )
        cells = cell_generator.GenerateBasicRandom(mesh.GetNumNodes(),
                                                   stem_type)

        ## Define when cells become apoptotic

        for eachCell in cells:
            cell_cycle_model = eachCell.GetCellCycleModel()
            eachCell.GetCellData().SetItem("oxygen", 30.0)
            cell_cycle_model.SetDimension(2)
            cell_cycle_model.SetStemCellG1Duration(4.0)
            cell_cycle_model.SetHypoxicConcentration(0.1)
            cell_cycle_model.SetQuiescentConcentration(0.3)
            cell_cycle_model.SetCriticalHypoxicDuration(8)
            g1_duration = cell_cycle_model.GetStemCellG1Duration()
            sg2m_duration = cell_cycle_model.GetSG2MDuration()
            rnum = chaste.core.RandomNumberGenerator.Instance().ranf()
            birth_time = -rnum * (g1_duration + sg2m_duration)
            eachCell.SetBirthTime(birth_time)

        ## Now we have a mesh and a set of cells to go with it, we can create a `CellPopulation` as before.

        cell_population = chaste.cell_based.MeshBasedCellPopulation2_2(
            mesh, cells)

        ## To view the results of this and the next test in Paraview it is necessary to explicitly generate the required .vtu files.

        cell_population.AddPopulationWriterVoronoiDataWriter()

        ## We then pass in the cell population into an `OffLatticeSimulation`, and set the output directory and end time.

        simulator = chaste.cell_based.OffLatticeSimulation2_2(cell_population)
        simulator.SetOutputDirectory("Python/TestSpheroidTutorial")
        simulator.SetEndTime(5.0)

        ## We ask for output every 12 increments

        simulator.SetSamplingTimestepMultiple(100)

        ## We define how the springs between cells behave using a force law.

        force = chaste.cell_based.GeneralisedLinearSpringForce2_2()
        simulator.AddForce(force)

        ## We set up a PDE for oxygen diffusion and consumption by cells, setting the rate of consumption to 0.1

        pde = chaste.cell_based.CellwiseSourceEllipticPde2(
            cell_population, -0.5)

        ## We set a constant amount of oxygen on the edge of the spheroid

        bc = chaste.pde.ConstBoundaryCondition2(1.0)
        is_neumann_bc = False

        ## Set up a pde modifier to solve the PDE at each simulation time step

        #pde_modifier = chaste.cell_based.EllipticGrowingDomainPdeModifier2(pde, bc, is_neumann_bc)
        #pde_modifier.SetDependentVariableName("oxygen")
        #simulator.AddSimulationModifier(pde_modifier)

        ## As before, we set up a scene modifier for real-time visualization

        scene = chaste.visualization.VtkScene2()
        scene.SetCellPopulation(cell_population)
        scene.GetCellPopulationActorGenerator().SetColorByCellData(True)
        scene.GetCellPopulationActorGenerator().SetDataLabel("oxygen")
        scene.GetCellPopulationActorGenerator().SetShowCellCentres(True)
        scene.GetCellPopulationActorGenerator().SetShowVoronoiMeshEdges(False)
        # JUPYTER_SHOW_FIRST

        scene_modifier = chaste.cell_based.VtkSceneModifier2()
        scene_modifier.SetVtkScene(scene)
        scene_modifier.SetUpdateFrequency(100)
        simulator.AddSimulationModifier(scene_modifier)

        ## Eventually remove apoptotic cells

        killer = chaste.cell_based.ApoptoticCellKiller2(cell_population)
        simulator.AddCellKiller(killer)

        ## To run the simulation, we call `Solve()`. We can again do a quick rendering of the population at the end of the simulation

        scene.Start()
        simulator.Solve()