#!/bin/sh # bet - wrapper script for lots of different bet functionality # # Stephen Smith, FMRIB Image Analysis Group # SIENA eye cleanup option by Marco Battaglini and Nicola De Stefano, Siena # # Copyright (C) 2005-2007 University of Oxford # # Part of FSL - FMRIB's Software Library # http://www.fmrib.ox.ac.uk/fsl # fsl@fmrib.ox.ac.uk # # Developed at FMRIB (Oxford Centre for Functional Magnetic Resonance # Imaging of the Brain), Department of Clinical Neurology, Oxford # University, Oxford, UK # # # LICENCE # # FMRIB Software Library, Release 4.0 (c) 2007, The University of # Oxford (the "Software") # # The Software remains the property of the University of Oxford ("the # University"). # # The Software is distributed "AS IS" under this Licence solely for # non-commercial use in the hope that it will be useful, but in order # that the University as a charitable foundation protects its assets for # the benefit of its educational and research purposes, the University # makes clear that no condition is made or to be implied, nor is any # warranty given or to be implied, as to the accuracy of the Software, # or that it will be suitable for any particular purpose or for use # under any specific conditions. 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Contact details are: # innovation@isis.ox.ac.uk quoting reference DE/1112. # {{{ Usage() Usage() { cat < [options] Main bet2 options: -o generate brain surface outline overlaid onto original image -m generate binary brain mask -s generate approximate skull image -n don't generate segmented brain image output -f fractional intensity threshold (0->1); default=0.5; smaller values give larger brain outline estimates -g vertical gradient in fractional intensity threshold (-1->1); default=0; positive values give larger brain outline at bottom, smaller at top -r head radius (mm not voxels); initial surface sphere is set to half of this -c centre-of-gravity (voxels not mm) of initial mesh surface. -t apply thresholding to segmented brain image and mask -e generates brain surface as mesh in .vtk format Variations on default bet2 functionality (mutually exclusive options): (default) just run bet2 -R robust brain centre estimation (iterates BET several times) -S eye & optic nerve cleanup (can be useful in SIENA) -B bias field & neck cleanup (can be useful in SIENA) -Z improve BET if FOV is very small in Z (by temporarily padding end slices) -F apply to 4D FMRI data (uses -f 0.3 and dilates brain mask slightly) -A run bet2 and then betsurf to get additional skull and scalp surfaces (includes registrations) -A2 as with -A, when also feeding in non-brain-extracted T2 (includes registrations) Miscellaneous options: -v verbose (switch on diagnostic messages) -h display this help, then exits -d debug (don't delete temporary intermediate images) EOF exit 1 } # }}} # {{{ get_dims() get_dims() { xdim=`${FSLDIR}/bin/fslval $1 dim1 | sed 's/-//g'` ydim=`${FSLDIR}/bin/fslval $1 dim2 | sed 's/-//g'` zdim=`${FSLDIR}/bin/fslval $1 dim3 | sed 's/-//g'` xpixdim=`${FSLDIR}/bin/fslval $1 pixdim1 | sed 's/-//g'` ypixdim=`${FSLDIR}/bin/fslval $1 pixdim2 | sed 's/-//g'` zpixdim=`${FSLDIR}/bin/fslval $1 pixdim3 | sed 's/-//g'` #echo $xdim $ydim $zdim $xpixdim $ypixdim $zpixdim } # }}} # {{{ find_centre_in_mm() # find_centre_in_mm() { # centre=`${FSLDIR}/bin/fslstats $1 -l 0.001 -C` # x=`echo $centre $xpixdim | awk '{print "10 k " $1 " " $4 " * p"}' | dc -` # y=`echo $centre $ypixdim | awk '{print "10 k " $2 " " $4 " * p"}' | dc -` # z=`echo $centre $zpixdim | awk '{print "10 k " $3 " " $4 " * p"}' | dc -` # #echo $x $y $z # } # }}} # {{{ find_centre_in_voxels() find_centre_in_voxels() { centre=`${FSLDIR}/bin/fslstats $1 -l 0.001 -C` x=`echo $centre | awk '{print $1}'` y=`echo $centre | awk '{print $2}'` z=`echo $centre | awk '{print $3}'` #echo $x $y $z } # }}} # {{{ parse IN and OUT options [ "$2" = "" ] && Usage IN=`${FSLDIR}/bin/remove_ext $1` OUT=`${FSLDIR}/bin/remove_ext $2` shift 2 if [ `${FSLDIR}/bin/imtest $IN` = 0 ] ; then echo "" echo "Error: input image $IN not valid" echo "" exit 1 fi # }}} # {{{ setup variable defaults debug=0 verbose=0 variation=0 bet2opts="" # }}} # {{{ parse options while [ _$1 != _ ] ; do if [ $1 = -o ] || [ $1 = -m ] || [ $1 = -s ] || [ $1 = -n ] || [ $1 = -t ] || [ $1 = -e ] ; then bet2opts="$bet2opts $1" shift elif [ $1 = -f ] || [ $1 = -g ] || [ $1 = -r ] ; then [ "$2" = "" ] && Usage bet2opts="$bet2opts $1 $2" shift 2 elif [ $1 = -c ] ; then [ "$4" = "" ] && Usage bet2opts="$bet2opts $1 $2 $3 $4" shift 4 elif [ $1 = -R ] ; then variation=1 shift elif [ $1 = -S ] ; then variation=2 shift elif [ $1 = -Z ] ; then variation=3 shift elif [ $1 = -F ] ; then variation=4 shift elif [ $1 = -A ] ; then variation=5 shift elif [ $1 = -A2 ] ; then [ "$2" = "" ] && Usage variation=6 IN2=$2 shift 2 elif [ $1 = -B ] ; then variation=7 shift elif [ $1 = -v ] ; then verbose=1 bet2opts="$bet2opts -v" shift elif [ $1 = -d ] ; then debug=1 shift else Usage fi done if [ $verbose = 1 ] ; then echo IN=$IN echo OUT=$OUT echo bet2opts="${bet2opts}" echo verbose=$verbose echo debug=$debug echo variation=$variation fi # }}} # {{{ process variations if [ $variation = 0 ] ; then ${FSLDIR}/bin/bet2 $IN $OUT $bet2opts elif [ $variation = 1 ] ; then # {{{ BET robust bet2opts=`echo $bet2opts | sed 's/-n//g'` get_dims $IN i=1 while [ $i -gt 0 ] ; do #echo $i if [ $i = 1 ] ; then ${FSLDIR}/bin/bet2 $IN $OUT $bet2opts find_centre_in_voxels $OUT else ${FSLDIR}/bin/bet2 $IN $OUT $bet2opts -c $x $y $z ox=$x; oy=$y; oz=$z; find_centre_in_voxels $OUT diffsq=`echo "0 k $ox $x - 2 ^ $oy $y - 2 ^ + $oz $z - 2 ^ + 1 / p" | dc -` #echo $diffsq if [ $diffsq -lt 1 ] || [ $i -gt 10 ] ; then i=_10 fi fi i=`echo "$i 1 + p" | dc -` done # }}} elif [ $variation = 2 ] ; then # {{{ SIENA eye cleanup #### get the raw brain and skull images ${FSLDIR}/bin/bet2 $IN ${OUT}_tmp_betraw -s $bet2opts #### run betpremask (keep intermediate files around using -d) and feed it into bet ${FSLDIR}/bin/standard_space_roi $IN ${OUT}_tmp_premask -b -d ${FSLDIR}/bin/bet2 ${OUT}_tmp_premask ${OUT}_tmp_premask_bet -n -m -f 0.4 $bet2opts #### bring eye mask from standard space into native and dilate, mostly in 2D and then invert ${FSLDIR}/bin/flirt -ref $IN -in ${FSLDIR}/data/standard/MNI152_T1_2mm_eye_mask -applyxfm -init ${OUT}_tmp_premask_tmp_to_std_inv.mat -datatype float -out ${OUT}_tmp_eye_mask ${FSLDIR}/bin/fslmaths ${OUT}_tmp_eye_mask -thr 0.5 -bin -dilF -kernel 2D -dilF -dilF -dilF -dilF -dilF -dilF -dilF ${OUT}_tmp_eyes7dil -odt short ${FSLDIR}/bin/fslmaths ${OUT}_tmp_eyes7dil -mul -1 -add 1 ${OUT}_tmp_eyes7dil_inv #### mask original brain mask with inverted-eye-mask, ADD betpremask_bet_mask and X by original brain ${FSLDIR}/bin/fslmaths ${OUT}_tmp_betraw -bin -mas ${OUT}_tmp_eyes7dil_inv -add ${OUT}_tmp_premask_bet_mask -bin -mul ${OUT}_tmp_betraw ${OUT}_tmp_prebrain #### find upper threshold used to delete eyes Mean=`${FSLDIR}/bin/fslstats ${OUT}_tmp_prebrain -M` SD=`${FSLDIR}/bin/fslstats ${OUT}_tmp_prebrain -S` thr=`echo "10 k 3.5 $SD * $Mean + p" | dc -` #### apply threshold and a little morphology (twice) to cleanup further and produce final brain image ${FSLDIR}/bin/fslmaths ${OUT}_tmp_prebrain -uthr $thr -bin -ero -dilF -dilF -ero -mul ${OUT}_tmp_prebrain -uthr $thr -bin -kernel 2D -ero -dilF -mul ${OUT}_tmp_betraw $OUT ${FSLDIR}/bin/fslmaths $OUT -bin ${OUT}_mask #### remove eyes from original skull to produce final skull image ${FSLDIR}/bin/fslmaths ${OUT}_tmp_eyes7dil -ero -kernel 2D -ero -mul -1 -add 1 ${OUT}_tmp_eyes5dil_inv ${FSLDIR}/bin/fslmaths ${OUT}_tmp_betraw_skull -mas ${OUT}_tmp_eyes5dil_inv ${OUT}_skull # }}} elif [ $variation = 3 ] ; then # {{{ small FOV in Z MINZFOV=100.0 get_dims $IN npad=`echo "$MINZFOV $zpixdim / $zdim - 2 / 1 + p" | dc -` if [ $npad -le 0 ] ; then echo "Image already has a greater Z FOV than $MINZFOV so not using padding" ${FSLDIR}/bin/bet2 $IN $OUT $bet2opts exit fi ${FSLDIR}/bin/fslroi $IN ${OUT}_tmp_bottom 0 $xdim 0 $ydim 0 1 ${FSLDIR}/bin/fslroi $IN ${OUT}_tmp_top 0 $xdim 0 $ydim `echo "$zdim 1 - p" | dc -` 1 n=1 while [ $n -le $npad ] ; do bottomlist="$bottomlist ${OUT}_tmp_bottom" toplist="$toplist ${OUT}_tmp_top" n=`echo "$n 1 + p" | dc -` done ${FSLDIR}/bin/fslmerge -z ${OUT}_tmp $bottomlist $IN $toplist ${FSLDIR}/bin/bet2 ${OUT}_tmp $OUT $bet2opts for f in `imglob ${OUT}*` ; do ${FSLDIR}/bin/fslroi $f $f 0 $xdim 0 $ydim $npad $zdim done # }}} elif [ $variation = 4 ] ; then # {{{ FMRI ${FSLDIR}/bin/fslroi $IN ${OUT}_tmp 0 1 ${FSLDIR}/bin/bet2 ${OUT}_tmp ${OUT}_tmp_brain -m -n -f 0.3 $bet2opts ${FSLDIR}/bin/fslmaths ${OUT}_tmp_brain_mask -dilF ${OUT}_mask ${FSLDIR}/bin/fslmaths $IN -mas ${OUT}_mask $OUT # }}} elif [ $variation = 5 ] ; then # {{{ bet2 + betsurf (T1 only) # register T1 to standard space ${FSLDIR}/bin/flirt -ref ${FSLDIR}/data/standard/MNI152_T1_2mm -in $IN -omat ${OUT}_tmp_T1_to_std.mat # run brain extraction and save brain mesh ${FSLDIR}/bin/bet2 $IN $OUT -e $bet2opts # find other surfaces ${FSLDIR}/bin/betsurf --t1only -o -m -s $IN ${OUT}_mesh.vtk ${OUT}_tmp_T1_to_std.mat $OUT # }}} elif [ $variation = 6 ] ; then # {{{ bet2 + betsurf (T1 & T2) # register T2 to T1 ${FSLDIR}/bin/flirt -in $IN2 -ref $IN -out ${OUT}_tmp_T2_to_T1 -omat ${OUT}_tmp_T2_to_T1.mat -interp sinc # register T1 to standard space ${FSLDIR}/bin/flirt -ref ${FSLDIR}/data/standard/MNI152_T1_2mm -in $IN -omat ${OUT}_tmp_T1_to_std.mat # run brain extraction and save brain mesh ${FSLDIR}/bin/bet2 $IN $OUT -e $bet2opts # find other surfaces ${FSLDIR}/bin/betsurf -o -m -s $IN ${OUT}_tmp_T2_to_T1 ${OUT}_mesh.vtk ${OUT}_tmp_T1_to_std.mat $OUT # }}} elif [ $variation = 7 ] ; then # {{{ SIENA bias field & neck cleanup #### run betpremask ${FSLDIR}/bin/standard_space_roi $IN ${OUT}_tmp_premask -b -d #### run FAST to get bias field ${FSLDIR}/bin/fast -b ${OUT}_tmp_premask >/dev/null 2>&1 #### apply bias correction to original ${FSLDIR}/bin/fslmaths $IN -div ${OUT}_tmp_premask_bias ${OUT}_tmp_unbiased #### re-run betpremask ${FSLDIR}/bin/standard_space_roi ${OUT}_tmp_unbiased ${OUT}_tmp_unbiased_premask -b -d #### re-run in robust mode ${FSLDIR}/bin/bet ${OUT}_tmp_unbiased_premask $OUT -m $bet2opts -R -d # }}} fi # }}} # {{{ cleanup temporary files if [ $debug = 0 ] ; then /bin/rm -f ${OUT}_tmp* fi # }}}