= Tutorial 3: Display the anatomy = ''Authors: Francois Tadel, Elizabeth Bock, Sylvain Baillet'' <> == Anatomy files == Description of the files in the anatomy folder == MRI visualization == * The ''Display options'' panel allows to hide some of the components. If the ''MIP/Anatomy ''checkbox is selected, the Maximum Intensity Power is displayed instead of the regular slices: At each point, the value displayed is the maximum value across all the slices. * The ''Coordinates ''panel shows the (x,y,z) coordinates in the coordinate systems managed by Brainstorm: MRI and SCS. * Once you're done, click on ''Cancel ''(unless you really want to save all your experiments). * There are many different ways to display the MR volumes. Right click on the ''T1-MRI'' in ''Default anatomy'', menu ''Display''. Just click everywhere and try all the options by yourself, it is the best way to learn.<
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> {{attachment:popupMri.gif}} ==== MRI Viewer ==== Already introduced in this tutorial<
>It is the default visualization mode; when you double-click on the MRI file, it brings up the MRI Viewer. ==== Axial / coronal / sagittal slices ==== {{attachment:mriSlicesContact.gif||height="231",width="210"}} * '''Zoom''': mouse wheel (or two finger-move on a MacBook pad) * '''Move '''in zoomed image: click + move * '''Adjust contrast''': right click + move up/down * Colormap selection in menu * Save as image in menu ==== 3D orthogonal slices ==== || {{attachment:mriSlices3d.gif||height="229",width="292"}} || {{attachment:menuShortcut.gif}} || * Simple mouse operations * '''Rotate''': click + move * '''Zoom''': mouse wheel (two finger-move on a MacBook pad) * '''Move object''': left+right click + move * '''Move MRI slices''': right click + move along direction of the slice<
>(or use the ''Resect ''panel in the ''Surface ''tab) * '''Colormap contrast/brightness''': click on the colorbar, and move up/down (brightness) or left/right (contrast) * '''Reset view''': double click * '''Reset colormap''': double-click on the colorbar * Popup operations (right-click on the figure) * '''Colormap''': Full ''Anatomy ''colormap edition (detailed in next tutorial) * '''MRI Display''': For now, contains only the MIP option (Maximum Intensity Power). If checked, for each orientation: displays the maximum along all the slices instead of the proper slice. * '''Get coordinates''': Pick a point in any 3D view and get its coordinates * '''Snapshots''': save images or movies from this figure * '''Figure''': change background color, display axes and menus for an advanced figure editing and management using Matlab tools. * '''Views''': configure camera position with predefined settings. * Keyboard shortcuts: * Notice the indications in the right part of the popup menu (''CTRL+A'' in front of ''Figures>Axes'', ''"1"'' in front of ''Views>Left''), they represent the keyboard shortcut for each menu. * '''Views shortcuts (0,1,2...9 and "=")''': Remember them, they will be very useful when exploring the cortical sources. It is much faster to press a key to switch from left to right hemisphere, than having to rotate the brain with the mouse. * Surfaces tab (in the Brainstorm main window): * This panel is primarily dedicated to the surfaces display, but some controls can also be useful for the 3D MRI view. * ''Transparency ''slider * ''Smooth ''slider: it changes the threshold applied to the MRI slices. If you set it zero, you will see the full slices, as extracted from the volume. * ''Resect ''panel: you can change the position of the slices with the three sliders. == Surfaces visualization == There is only one way to display the surfaces: in 3D figures. To display a surface you can either double-click on it or right-click > Display. * The mouse and keyboard operations are the same described for the 3D MRI display also apply here. * If you display two surfaces from the same subject, they will be displayed on the same figure. * Surfaces tab: more options are available<
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> {{attachment:panelSurfaces.gif}} * Open the ''Cortex ''surface and try all the buttons and sliders. Then do the same with the ''Scalp ''surface (''Head''). All the controls should have some effect on the display, except the sliders in the "''Data options''" panel. They are useful only when some additional data is mapped on the surfaces. * Multiple surfaces: If you have more than one surface in a figure, you need to select the surface you want to edit before changing its properties. The list of the available surfaces is displayed on top of the ''Surfaces ''tab. * You can also quickly add or remove surfaces in any 3D figure with the top-right buttons of the ''Surfaces ''tab. == Coordinates tab == * Close all the figures. Open the cortex surface again. * Right-click on the 3D figure, select "Get coordinates". A new window appears. * Click anywhere on the cortex surface: a big yellow cross appears, and the coordinates of the point are displayed in all the available coordinates systems (see page: CoordinateSystems) * MRI: MR volume, in millimeters (multiplied with the Voxsize field in the MRI file). * SCS: Subject Coordinates System, in millimeters * MNI: Montreal Neurological Institute standard coordinates * You can click on "View / MRI" to see where this point is located in the MRI, using the MRI Viewer. <
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> {{attachment:panelCoord.gif}} {{attachment:panelCoordPt.gif}} == Check registration with MRI == Your Subject01 anatomy is ready for source estimation. But before going further, you should '''always''' check that surfaces and MRI are well registered. When performing those steps a bit too fast, it is really easy to end up with a cortex envelope that is not aligned with the MRI. None of the following steps in source estimation will check that for you, and the sources estimated would be completely wrong. * Right-click on the ''Cortex ''surface ''> MRI Registration > Check MRI/surface registration''... . {{http://neuroimage.usc.edu/brainstorm/Tutorials/TutImportAnatomy?action=AttachFile&do=get&target=checkMriRegistration.gif|checkMriRegistration.gif|height="265px",width="332px",class="attachment"}} * The calculation of the interpolation MRI-surface takes a few seconds, but it is then saved in the database and will be reused later. * The yellow lines represent the re-interpolation of the surface in the MRI volume. The computation may take a while, but the result will be stored in the surface file, and will be useful for other operations anyway. <> <>