Difference between revisions of "Seed dipole solutions from cortical images"

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{{BESAInfobox
 
{{BESAInfobox
 
|title = Module information
 
|title = Module information
|module = BESA Research Basic or higher
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|module = BESA Research Standard or higher
 
|version = 5.2 or higher
 
|version = 5.2 or higher
 
}}
 
}}
  
BESA initially was designed to compute comprehensive dipole solution of so called inverse solution. With the advance of neruoinformatics we also incorporated many popular volumetric solutions (i.e. LORETA) and our own algorithms (like CLARA). Since release 6.1 of BESA Research cortical solutions (i.e. Cortical LORETA) are also available.  
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==Overview==
As always both inverse problem solutions (dipole and 3D Imaging methods) has some pros and cons. For example during dipole analysis, number of dipoles has to be assumed by the user. 3D Imaging methods does not need such assumption, but not provide full information of electrical sources (orientation and waveform of the source).
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BESA initially was designed to compute comprehensive dipole solutions using so-called inverse methods. With the advance of neuroinformatics we also incorporated many popular volumetric solutions (e.g. LORETA) and our own algorithms (e.g. CLARA). Since the release of BESA Research 6.1 cortical solutions (e.g. Cortical LORETA) are also available.  
 +
As always both inverse problem solution approaches (dipole and 3D Imaging methods) have some pros and cons. For example, for dipole analysis, the number of dipoles has to be assumed by the user. 3D Imaging methods do not need such assumptions, but need additional constraints such as regularization in order to obtain a solution for the inverse problem. Also, the orientation and wave form of the sources in the (cortical) image solution is not readily available.
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To overcome these limitations, there is the possibility to seed dipole(s) from 3D and cortical images.
  
To overcome such limitation, there is possibility to seed dipole solutions from 3D and cortical images.
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==Seeding dipoles==
 
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When you have a Source Analysis window open and you used a 3D Imaging source analysis of your choice you might end up with something similar to this (the CLARA algorithm was used in this example):
When you have a source analysis window open and you did used 3D Imaging source analysis of your choice you might end with something similar to this (CLARA algorithm was used in this example):
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[[File:DipoleFromSourceArrows.jpg|800px]]
 
[[File:DipoleFromSourceArrows.jpg|800px]]
  
To seed a dipole in exact place where the source is, press button named "Switch to next grid maximum" (button with little M letter, indicated with green arrow in the image). This will place a crosshair in exact place of source maximum designed by 3D image algorithm. You can press this button once again if you want to switch to next maximum. If you press button while holding Ctrl key, you go to previous maximum. When you find the place where you want to seed dipole just press button with dipole on it (indicated with blue arrow in Figure above). Of course you can repeat these steps to seed more than one dipole. For example in presented case you might want to seed two dipoles, as CLARA indicates two potential sources (in both hemispheres in temporal lobe). After doing this we get following result:
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To seed a dipole in the exact place where the source is, click the toolbar button named "Switch to next grid maximum" (the button with the small 'M' letter, indicated by a green arrow in the image). This will place a crosshair in the exact place of the source maximum designated by the 3D image algorithm. You can click this button once again if you want to switch to the next maximum. If you press the button while holding the Ctrl key, you go back to the previous maximum. When you find the place where you want to seed the dipole, just click the button with the dipole symbol on it (indicated with a blue arrow in the Figure above). Of course you can repeat these steps to seed more than one dipole. For example, in the presented case you might want to seed two dipoles, as CLARA indicates two potential sources (in both hemispheres in the temporal lobes). After doing this we get the following result:
  
 
[[File:DipoleFromSource2arrow.jpg|800px]]
 
[[File:DipoleFromSource2arrow.jpg|800px]]
  
To get better approximation of dipoles, we should fit them. Since the dipoles was placed on the basis of 3D image, good idea is to keep their location in the original position (to maintain visual connection between both solutions). So for each dipole we need to change location from "free" to "fixed" by selecting it from the list indicated with red arrow. You can switch between dipoles just by clicking on it. When this is done you can fit all dipoles to data. Press "All fit" button in the middle window to select all dipoles. Now press "Start fit". The result of such operation is presented below. please note that the waveforms and orientation has changed but location not.  
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==Fitting dipoles==
 
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To get a better approximation of dipole locations and orientations, we should fit them. Since the dipoles were placed on the basis of 3D image, a good idea is to keep their location in the original position. So, for each dipole it is advisable to change the location from "free" to "fixed" by selecting this entry from the list indicated by the red arrow in the image above. You can switch between dipoles just by clicking on them. After this is done you can fit all dipoles to the data. Click the "All fit" button in the central window to select all dipoles for fitting. Now press "Start fit". The result of this operation is presented below. Please note that the waveforms and orientations have changed but location has not.  
  
 
[[File:DipoleFromSourceFinal.JPG|800px]]
 
[[File:DipoleFromSourceFinal.JPG|800px]]
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==Dipole seeding from cortical solution example==
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As mentioned above, dipoles can be seeded also from cortical solutions (see example below). This approach allows evaluating sources very precisely. Because of brain physiology and the neocortex structure dipoles would be expected to be oriented approximately perpendicular to the brain surface.
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[[File:DipoleFromSourceCortical.JPG|800px]]
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[[Category:Source Analysis]]

Latest revision as of 16:37, 20 February 2017

Module information
Modules BESA Research Standard or higher
Version 5.2 or higher

Overview

BESA initially was designed to compute comprehensive dipole solutions using so-called inverse methods. With the advance of neuroinformatics we also incorporated many popular volumetric solutions (e.g. LORETA) and our own algorithms (e.g. CLARA). Since the release of BESA Research 6.1 cortical solutions (e.g. Cortical LORETA) are also available. As always both inverse problem solution approaches (dipole and 3D Imaging methods) have some pros and cons. For example, for dipole analysis, the number of dipoles has to be assumed by the user. 3D Imaging methods do not need such assumptions, but need additional constraints such as regularization in order to obtain a solution for the inverse problem. Also, the orientation and wave form of the sources in the (cortical) image solution is not readily available. To overcome these limitations, there is the possibility to seed dipole(s) from 3D and cortical images.

Seeding dipoles

When you have a Source Analysis window open and you used a 3D Imaging source analysis of your choice you might end up with something similar to this (the CLARA algorithm was used in this example):

DipoleFromSourceArrows.jpg

To seed a dipole in the exact place where the source is, click the toolbar button named "Switch to next grid maximum" (the button with the small 'M' letter, indicated by a green arrow in the image). This will place a crosshair in the exact place of the source maximum designated by the 3D image algorithm. You can click this button once again if you want to switch to the next maximum. If you press the button while holding the Ctrl key, you go back to the previous maximum. When you find the place where you want to seed the dipole, just click the button with the dipole symbol on it (indicated with a blue arrow in the Figure above). Of course you can repeat these steps to seed more than one dipole. For example, in the presented case you might want to seed two dipoles, as CLARA indicates two potential sources (in both hemispheres in the temporal lobes). After doing this we get the following result:

DipoleFromSource2arrow.jpg

Fitting dipoles

To get a better approximation of dipole locations and orientations, we should fit them. Since the dipoles were placed on the basis of 3D image, a good idea is to keep their location in the original position. So, for each dipole it is advisable to change the location from "free" to "fixed" by selecting this entry from the list indicated by the red arrow in the image above. You can switch between dipoles just by clicking on them. After this is done you can fit all dipoles to the data. Click the "All fit" button in the central window to select all dipoles for fitting. Now press "Start fit". The result of this operation is presented below. Please note that the waveforms and orientations have changed but location has not.

DipoleFromSourceFinal.JPG

Dipole seeding from cortical solution example

As mentioned above, dipoles can be seeded also from cortical solutions (see example below). This approach allows evaluating sources very precisely. Because of brain physiology and the neocortex structure dipoles would be expected to be oriented approximately perpendicular to the brain surface.

DipoleFromSourceCortical.JPG