mideface - a tool for minimally invasive defacing of MRI images
MRI images of the brain inevitably include the head and so the face. These images can be processed in a way to reconstruct the outside of the head which can often yield a near-photo quality image of the face (see image; displayed with permission of the subject). Before sharing such MRIs, it is usually a good idea to remove the information about the face so as to protect the subject's privacy. However, removing too much information could degrade the utility of the MRIs. This page describes a tool for defacing MRI images in a way that is both minimally invasive and achieves goals of privacy. Here, "minimally invasive" means changing the image in the smallest way to still be private.
First, the head is segmented from the input volume and a head surface created. mideface then runs Samseg on the input image. Samseg will register the input to a template as well as segment the brain, skull, eyeballs, and other structures. An average face surface in the template space is then mapped into the native space. The average face has several labels including lower face, upper face without eyes, eyes, forehead, ears, and back of head. The average face surface within a label is projected inwards by a distance just far enough until it intersects with at least 95% of the true face in that area. The average face is also projected outwards by a constant distance just far enough to include all of the true face. The distance is the same for all vertices within a label. Voxels in the input volume are segmented into four labels (see image above): (1) inside both the true and average faces ("InnerTissue", blue), (2) outside the true face but inside the average face (green, "InnerBackground"), (3) inside the true face but outside the average face (red, "OuterTissue"), (4) outside both the true and average face ("OuterBackground"). By default, voxels in #1 and #2 are replaced with random intensities set to the mean of voxels in #1 (tissue mean); voxels in #3 and #4 are replaced with random intensities with mean equal to the mode of voxels in #4 (background mean). The result is that the voxels at the tissue mean form the average face resulting in the average face surface if reconstructed. The true face is essentially encompassed by the face mask which assures privacy in that the true face is reduced to a few parameters (12 from the affine registration, and two distances for each label). The true face is private assuming that it cannot be reconstructed from this hand full of parameters. The invasiveness is minimized by projecting the average surface the minimal distance and by excluding voxels labeled by samseg as brain or skull or eyeball. The ears are removed by default, and there are options to remove the forehead and the back of the head (back of the head can be useful if there is wrap-around). Note that the average face has waves in it and a "MIDEFACE" watermark across the eyes. These are there to assure the user that this is indeed an average face and not a true face. Note that the face segmentation DOES have information about the true face and so should not be distributed.
In the basic usage, one passes the MRI volume to mideface and specifies an output volume
mideface --i volume.mgz --o volume.defaced.mgz --samseg-fast
This should take roughly 15min to run. The original and defaced volumes can be viewed with freeview:
freeview volume.mgz volume.defaced.mgz
Quality Assurance (QA)
One can run the above freeview command to verify that the voxels of the face have been replaced with random values, but a more extensive QA is possible by adding and output folder:
mideface --i volume.mgz --o volume.defaced.mgz --samseg-fast --odir qa
The qa folder will have many files in it that can be used for QA, but the most important will be head.surf and head.defaced.surf which can be viewed with
freeview volume.mgz volume.defaced.mgz -f qa/head.surf:edgecolor=yellow -f qa/head.defaced.surf:edgecolor=red:visible=0
In the surface view, you will see head.surf. This is a rendering of the entire original head, including the face. Hit the Alt-C button to turn off head.surf and display head.defaced.surf. This is the head after defacing. You should see something like image where the face now has a wave in it and you may be able to read the "MIDEFACE" watermark across the eyes. This is the replacement face. If you see the wave and the watermark, then you know that the face has been replaced. Hit Alt-C a few times to switch back and forth. Rotate the head to verify that the ears have been removed.
Creating Pictures for Quality Assurance
Viewing the face surfaces above can be quite tedious if the number of subjects to deface is large. To make QA easier, mideface has the ability to take snapshots which can then be arranged in a slide show or animation or movie.
mideface --i volume.mgz --o volume.defaced.mgz --samseg-fast --odir qa --pics --code codename
Adding --pics will trigger the taking of pictures which will be saved as codename.face-before.png, codename.face-after.png, and codename.before+after.gif, where codenmae is a unique codename for this case. There are several practical details that may need to be addressed. mideface will call freeview to take the picture. This may result in freeview appearing and disappearing from your display, which can be quite annoying. If you have Xvfb installed, it will try to use that. Xvfb is a frame buffer virtual display, meaning that a freeview window will not show up on your display. mideface will use the ImageMagik convert program to crop the images, add the codename to the image, and create the gif. mideface expects this program to be in /usr/bin/convert. If it is not there, you can pass it the path with --imconvert /path/to/convert. If convert is not found or specified, then just the pngs are created. If a codename is not supplied, then the file names and the images will not have the codename. The codename.before+after.gif file is an animated gif switching between the true face and the defaced. To create a slide show, just copy the pngs or the gifs to a folder and go to that folder with your slide viewing program (note that you will need to specify a codename for this otherwise all the files will have the same name).