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| mri_watershed [<options>] <input volume> <brain volume> | mri_watershed [<options>] [input volume] [brain volume] |
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| ||[input volume]|| || ||[output volume]|| || |
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| None | |
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| || -atlas || use the atlas information to correct the segmentation. When the segmented brain is not correct, this option might help you. || || -surf [surfname] || save the BEM surfaces. In order to get the surfaces consistent with tkmedit, you have to use the option -useSRAS. || || -useSRAS || use the surface RAS coordinates (not the scanner RAS) for surfaces. || || -noT1 || don't do T1 analysis. (Useful when running out of memory) || || -less || shrink the surface || || -more || expand the surface || || -wat || use only the watershed algorithm || || -T1 || specify T1 input volume (T1 grey value = 110) || || -wat+temp || watershed algo and first template smoothing || || -first_temp || use only the first template smoothing + local matching || || -surf_debug || visualize the surfaces onto the output volume || || -brainsurf surfname || save the brain surface || || -shk_br_surf int_h surfname || to save the brain surface shrank inward of int_h mm || || -s int_i int_j int_k || add a seed point || || -c int_i int_j int_k || specify the center of the brain (in voxel unit) || || -r int_r || specify the radius of the brain (in voxel unit) || || -t int_threshold || change the threshold in the watershed analyze process || || -h int_hpf || precize the preflooding height (in percent) || || -n || not use the watershed analyze process || || -LABEL || labelize the output volume into scalp, skull, csf, gray and white || || -man int_csf int_trn int_gray || to change the different parameters csf_max, transition_intensity and GM_intensity || || -mask || mask a volume with the brain mask || || --help || show this usage message || || --version || show the current version || |
|| -atlas || use the atlas information to correct the segmentation.|| When the segmented brain is not correct, this option might help you. || || -surf [surfname] || save the BEM surfaces.|| In order to get the surfaces consistent with tkmedit, you have to use the option -useSRAS. || || -useSRAS || use the surface RAS coordinates (not the scanner RAS) for surfaces. || || || -noT1 || don't do T1 analysis. (Useful when running out of memory) || || || -less || shrink the surface || || || -more || expand the surface || || || -wat || use only the watershed algorithm || || || -T1 || specify T1 input volume (T1 grey value = 110) || || || -wat+temp || watershed algo and first template smoothing || || || -first_temp || use only the first template smoothing + local matching || || || -surf_debug || visualize the surfaces onto the output volume || || || -brainsurf [surfname] || save the brain surface || || || -shk_br_surf [int_h surfname] || to save the brain surface shrank inward of int_h mm || || || -s [int_i int_j int_k] || add a seed point || || || -c [int_i int_j int_k] || specify the center of the brain (in voxel unit) || || || -r int_r || specify the radius of the brain (in voxel unit) || || || -t int_threshold || change the threshold in the watershed analyze process || || || -h int_hpf || precize the preflooding height (in percent) || || || -n || not use the watershed analyze process || || || -LABEL || labelize the output volume into scalp, skull, csf, gray and white || || || -man [int_csf int_trn int_gray] || to change the different parameters csf_max, transition_intensity and GM_intensity || || || -mask || mask a volume with the brain mask || || || --help || show usage message || || || --version || show the current version || || |
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| || <brain volume> || skull stripped brain volume || | || [brain volume] || skull stripped brain volume || |
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| It will try to figure out whether the volume is T1 volume or not by checking the number of grey value 110. Under the standard processing like recon-all script, |
Produce the brain volume from T1 volume or the scanned volume. |
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| mri-watershed foo -i f -o out | mri-watershed -atlas T1 brain |
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| description | where T1 is the T1 volume and brain is the output brain volume. When the cerebellum is cut-off from the brain or getting the left/right asymmetric brain, you should first try this -atlas option. |
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| mri-watershed foo -i f -o out -f fvalue | mri-watershed T1 brain |
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| description | The same as the first example, but no correction is applied to the intermediate result. = Bugs = None |
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| ["othercommand1"], ["othercommand2"] | ["mri_normalize"] |
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| description description |
The "watershed" segmentation algorithm was used to dertermine the intensity values for white matter, grey matter, and CSF. A force field was then used to fit a spherical surface to the brain. The shape of the surface fit was then evaluated against a previously derived template. If you used -atlas option, then { The template was used to correct the surface. } The finely grained sphere was fit to the brain. (Segonne 2004) |
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| ["References/Lastname###"] | ["References/Segonne2004"] |
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| Report bugs to <analysis-bugs@nmr.mgh.harvard.edu> | Report bugs to <freesurfer@nmr.mgh.harvard.edu> |
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| JaneSmith | YasunariTosa |
Name
mri_watershed - strips skull and other outer non-brain voxels from an acquired volume (usually T1).
Synopsis
mri_watershed [<options>] [input volume] [brain volume]
Positional Arguments
[input volume] |
|
[output volume] |
|
Required Flagged Arguments
None
Optional Flagged Arguments
-atlas |
use the atlas information to correct the segmentation. |
When the segmented brain is not correct, this option might help you. |
-surf [surfname] |
save the BEM surfaces. |
In order to get the surfaces consistent with tkmedit, you have to use the option -useSRAS. |
-useSRAS |
use the surface RAS coordinates (not the scanner RAS) for surfaces. |
|
-noT1 |
don't do T1 analysis. (Useful when running out of memory) |
|
-less |
shrink the surface |
|
-more |
expand the surface |
|
-wat |
use only the watershed algorithm |
|
-T1 |
specify T1 input volume (T1 grey value = 110) |
|
-wat+temp |
watershed algo and first template smoothing |
|
-first_temp |
use only the first template smoothing + local matching |
|
-surf_debug |
visualize the surfaces onto the output volume |
|
-brainsurf [surfname] |
save the brain surface |
|
-shk_br_surf [int_h surfname] |
to save the brain surface shrank inward of int_h mm |
|
-s [int_i int_j int_k] |
add a seed point |
|
-c [int_i int_j int_k] |
specify the center of the brain (in voxel unit) |
|
-r int_r |
specify the radius of the brain (in voxel unit) |
|
-t int_threshold |
change the threshold in the watershed analyze process |
|
-h int_hpf |
precize the preflooding height (in percent) |
|
-n |
not use the watershed analyze process |
|
-LABEL |
labelize the output volume into scalp, skull, csf, gray and white |
|
-man [int_csf int_trn int_gray] |
to change the different parameters csf_max, transition_intensity and GM_intensity |
|
-mask |
mask a volume with the brain mask |
|
--help |
show usage message |
|
--version |
show the current version |
|
Outputs
[brain volume] |
skull stripped brain volume |
[BEM surfaces] |
when you specify the option -brainsurf surfname |
Description
Produce the brain volume from T1 volume or the scanned volume.
Example 1
mri-watershed -atlas T1 brain
where T1 is the T1 volume and brain is the output brain volume. When the cerebellum is cut-off from the brain or getting the left/right asymmetric brain, you should first try this -atlas option.
Example 2
mri-watershed T1 brain
The same as the first example, but no correction is applied to the intermediate result.
Bugs
None
See Also
["mri_normalize"]
Links
Methods Description
The "watershed" segmentation algorithm was used to dertermine the intensity values for white matter, grey matter, and CSF.
A force field was then used to fit a spherical surface to the brain. The shape of the surface fit was then evaluated against a previously derived template.
If you used -atlas option, then { The template was used to correct the surface. }
The finely grained sphere was fit to the brain.
(Segonne 2004)
References
["References/Segonne2004"]
Reporting Bugs
Report bugs to <freesurfer@nmr.mgh.harvard.edu>