spm_templates.man

% 
% SPM templates and other images...
% _______________________________________________________________________
% /TPM/ DIRECTORY
% Contains Tissue probability maps provided by the International
% Consortium for Brain Mapping, John C. Mazziotta and Arthur W. Toga.
% http://www.loni.ucla.edu/ICBM/ICBM_TissueProb.html
%
% The 452 subjects were between 20 and 32 years old, and were
% approximately 50-50 male/female.
%
% The original datasets were affine transformed to match the MNI152
% space (by affine registration of the grey matter with the grey
% matter image in the apriori directory: smosrc=8, smoref=0,
% regtype=mni, cutoff=Inf).
% _______________________________________________________________________
%
% /TEMPLATES/ DIRECTORY
% This directory contains images for use as templates for spatially
% normalising  images to the same stereotactic space.  The space is
% based upon the Talairach system, but does  not  make  assumptions
% about  brain  symmetry,  and  also  includes the cerebellum.  The
% stereotactic  space   is  based  on  152   brains  from  Montréal
% Neurological  Institute,  and  will eventually be replaced in due
% course by a 450-brain version for the entire ICBM consortium.
%
% Subject details:
%    Age: mean=25.0, median=24.0, mode=19.0, stdev=4.9, range=18-44
%    Sex: female=66 (43.4%), male=86 (56.6%)
%    Handedness: right=129 (90.2%), left=14 (9.8%), unknown=9
% 
% In SPM96, we released  a  single  subject  brain  for  use  as  a
% template.   Although  the  MNI  gave  us  this  data,  they never
% recommended that this brain  should  be  used  as  a  stereotaxic
% standard.   This   is  something  that we at the FIL chose to do.
% The official standard  for  the   ICBM   stereotactic  space   is
% the   MNI305  brain  -  which  this was not.  This brain has many
% merits for simulation but it  suffers   from   all   the   single
% brain  criticisms  that apply to Talairach.  In this release, the
% single subject T1 has been replaced by a 152 subject average.  We
% (in  the  SPM  group)  chose  to  use the 152 subject T1-weighted
% average rather than the 305 brain average because there are  also
% T2-,  and  PD-weighted  images of the same subjects.  This should
% allow  much  more  flexibility  in  the  range  of  different  MR
% contrasts   that   can   be  spatially  normalised  to  the  same
% stereotaxic space (by registering  to  a  linear  combination  of
% template images).
% _______________________________________________________________________
% 
% templates/T1.nii
% ----------------
% Image  derived  from   icbm_avg_152_t1_tal_lin.mnc,   which   was
% originally  supplied  by  Alan Evans, MNI, Canada (ICBM, NIH P-20
% project, Principal Investigator John Mazziotta).  The  image  was
% reduced to 2mm isotropic resolution and smoothed with an 8mm FWHM
% Gaussian filter.
% Sequence Details: Spoiled FLASH sequence, TE=10, TR=18, FA=30.
%
% templates/T2.nii
% ----------------
% Image  derived  from   icbm_avg_152_t2_tal_lin.mnc,   which   was
% originally  supplied  by  Alan Evans, MNI, Canada (ICBM, NIH P-20
% project, Principal Investigator John Mazziotta).  The  image  was
% reduced to 2mm isotropic resolution and smoothed with an 8mm FWHM
% Gaussian filter.
% Sequence Details: Dual echo spin echo, TE=120ms, TR=3300ms, FA=90.
% 
% templates/PD.nii
% ----------------
% Image  derived  from   icbm_avg_152_pd_tal_lin.mnc,   which   was
% originally  supplied  by  Alan Evans, MNI, Canada (ICBM, NIH P-20
% project, Principal Investigator John Mazziotta).  The  image  was
% reduced to 2mm isotropic resolution and smoothed with an 8mm FWHM
% Gaussian filter.
% Sequence Details: Dual echo spin echo, TE=35ms, TR=3300ms, FA=90.
% 
% templates/EPI.nii
% -------------
% The image was created from the average of 13 subjects  mean  fMRI
% images.   The  grey matter was segmented from the original images
% using the segmentation in SPM.  This was spatially normalised  by
% matching  to  the  apriori/grey.nii  file  using  a  12-parameter
% affine  registration,  followed   by   a nonlinear   registration
% (using   the   7x8x7   lowest  frequency  DCT  coefficients,  and
% heavy   regularisation).     These    estimated  parameters  were
% then  applied  to the functional images, which were then averaged
% and smoothed with an 8mm FWHM Gaussian kernel.  The  EPI   images
% were  acquired  on  a  Siemens Vision scanner working at 2T.  The
% original resolution of the images was an  isotropic   3mm  (1.8mm
% slice   thickness   +  1.2mm  gap).  A gradient echo sequence was
% used with TE@ms and a TR of about 3s.  Inter echo spacing  is 800
% micro   seconds   with   a   sinusoidal   gradient  waveform  and
% nonlinear ADC sampling.  Nyquist ghost  suppression  is  achieved
% using  a  2  echo  reference  scan  (only 0th and 1st order phase
% correction implemented). Maximum  gradient  strength  is  approx.
% 20mT/m.
% Subject numbers: 1285 1286 1287 1291 1314 1379 1381 1399 1479
%                  1514 1589 1644 1646.
% 
% templates/filT1.nii (no longer exists)
% -------------------
% Average of images from 12  subjects  spatially  normalised  to  a
% linear  combination  of  T1.nii,  T2.nii  and  PD.nii using a 12-
% parameter  affine  transformation,   followed  by   a   nonlinear
% registration  (using the 7x8x7 lowest frequency DCT coefficients,
% and medium regularisation).  Images acquired on a 2 Tesla Siemens
% Magnetom  Vision scanner at the FIL,  using a T1 weighted  MPRAGE
% sequence  (TRel=9.7, TEch=4, TInv=600, Fang=12, SThi=1.5).   Same
% subjects    were   also    used    for    templates/PET.nii   and
% templates/Transm.nii.   This image is included  as   it  has  the
% same  contrast as the T1 weighted images from the FIL  (so we can
% use it for spatial normalisation).
% Subject numbers: 617 622 627 630 639 662 817 824 825 826 827 828.
% 
% templates/PET.nii
% -----------------
% Average of images from 12 subjects spatially normalised to  ICBM.
% Images  were  first  registered to the T1-weighted MR images, and
% spatially transformed using the same transformation.  Images were
% acquired  on  a  Siemens  ECAT  HR+  at  the FIL, using Oxygen-15
% labelled water. Averaged images smoothed using 8mm FWHM  Gaussian.
% Subject numbers: 617 622 627 630 639 662 817 824 825 826 827 828.
% 
% templates/Transm.nii
% --------------------
% Average transmission image of 11 subjects.  Template generated in
% similar way to PET.nii.
% Subject numbers: 617 622 627 630 639 662 817 824 825 827 828.
%
% templates/SPECT.nii
% -------------------
% The SPECT template was provided by Leighton Barnden. It is the
% average of 90 normal Tc-99m HMPAO scans. Scatter was subtracted
% using a lower 111-125 keV window. For spatial normalisation, scalp
% was first masked (after an initial affine transformation to the
% SPM2 SPECT template) by weighting with ../spm99/apriori/brainmask.
% These scans were then spatially normalised to the (masked) SPM2
% SPECT template. The same deformations were applied to the scans
% with extra-cerebral activity and these were averaged. The result
% was affine normalised to .../apriori/gray to correct for an
% apparent midline offset in this and earlier SPECT and PET
% templates.
% Here are the ages (years) and sexes (1=F, 0=M) of the subjects...
% age = [ ...
% 46    24    27    42    45    56    51    53    41    44 ...
% 44    46    28    24    30    58    43    45    24    29 ...
% 20    42    47    27    54    21    32    19    19    43 ...
% 29    43    20    28    59    21    60    46    37    23 ...
% 40    50    50    81    48    47    22    79    24    44 ...
% 74    47    54    78    43    35    54    60    57    55 ...
% 59    57    18    52    67    62    57    47    58    67 ...
% 62    67    61    64    38    37    31    48    60    30 ...
% 31    36    32    25    66    40    38    31    37    39];
% sex = [ ...
% 1    1    0    1    0    1    1    0    1    1 ...
% 1    0    1    0    0    1    0    1    1    0 ...
% 0    1    0    0    1    1    0    1    1    0 ...
% 1    0    0    1    1    0    1    1    1    0 ...
% 0    1    1    0    0    1    0    0    1    0 ...
% 1    0    0    0    1    0    1    1    0    0 ...
% 1    0    1    0    1    1    0    1    0    1 ...
% 0    0    1    1    0    1    1    0    1    0 ...
% 1    1    0    1    1    1    1    1    1    1];
%
% _______________________________________________________________________
% _______________________________________________________________________
% /APRIORI/ DIRECTORY
% Images in this directory represent the a priori probabilities of the
% voxels in a spatially normalised (9-parameter affine) brain image
% belonging to a particular tissue type.
% _______________________________________________________________________
% 
% apriori/grey.nii, apriori/white.nii & apriori/csf.nii
% ----------------  -----------------   ---------------
% Images supplied by  Alan  Evans,  MNI,  Canada  (ICBM,  NIH  P-20
% project,  Principal  Investigator  John Mazziotta).  Original 1mm
% resolution images were  icbm_avg_151_gm.mnc,  icbm_avg_151_wm.mnc
% and    icbm_avg_151_csf.mnc.     Images    were    masked   using
% average_305_mask_1mm.mnc, reduced to 2mm resolution and  smoothed
% using   an   8mm  FWHM  Gaussian.   These  images  represent  the
% probabilities of finding grey matter, white  matter  or  cerebro-
% spinal  fluid  at  any  point. These volumes are used largely for
% image segmentation, although they can be used  as  templates  for
% spatial  normalisation.  151  subjects  were  used to create each
% volume.
% 
% apriori/brainmask
% -----------------
% Image derived from average_305_mask_1mm.mnc, which was originally
% supplied  by  Alan  Evans,  MNI,  Canada (ICBM, NIH P-20 project,
% Principal  Investigator  John  Mazziotta).   The  original  image
% contained ones and zeros, where ones represented voxels that were
% part of the brain.  It was subsequently  smoothed  using  an  8mm
% FWHM  Gaussian.   This  volume  can be used to weight the spatial
% normalisation so that the final solution  is  not  influenced  by
% voxels outside the brain.
% 
% _______________________________________________________________________
% _______________________________________________________________________
% /CANONICAL/ DIRECTORY
% Images in this  directory are intended for superimposing results
% on to.
% _______________________________________________________________________
% 
% canonical/avg305T1.nii
% ----------------------
% Image derived from norm_avg_305_mri_1mm.mnc, which was originally
% supplied  by  Alan  Evans,  MNI,  Canada (ICBM, NIH P-20 project,
% Principal Investigator John Mazziotta).  The image which  defines
% the  305  space,  and  is intended for superimposing blobs on to.
% See:  AC Evans, DL Collins, SR Mills, ED Brown,  RL  Kelly  &  TM
% Peters (1993) "3D statistical neuroanatomical models from 305 MRI
% volumes" Proc. IEEE-Nuclear Science Symposium and Medical Imaging
% Conference pages 1813-1817
% 
% canonical/avg152T1.nii, avg152T2.nii & avg152PD.nii
% ----------------------  ------------   ------------
% These  images  were  derived  from   icbm_avg_152_t1_tal_lin.mnc,
% icbm_avg_152_t2_tal_lin.mnc  and icbm_avg_152_pd_tal_lin.mnc res-
% pectively, which were originally supplied by  Alan  Evans,   MNI,
% Canada   (ICBM,   NIH  P-20  project, Principal Investigator John
% Mazziotta).   See  templates/T1.nii, T2.nii and PD.nii.
% 
% canonical/single_subj_T1.nii
% ----------------------------
% A T1 weighted MRI of  a  representative  male  individual.   This
% image  was  used  for  the  T1  template supplied with SPM96.  It
% should be noted that the MNI never recommended this  brain  as  a
% stereotactic  standard.   This  is  something  that we at the FIL
% chose to do.  The official standard  for  the  ICBM  stereotactic
% space  is  the  MNI305 brain - which this is not.  This brain has
% many merits for simulation but it suffers  from  all  the  single
% brain criticisms that apply to Talairach.
% The same dataset was used for the  brain  simulation  project  at
% Montreal,     details     of    which    can    be    found    at
% http://www.bic.mni.mcgill.ca/brainweb The simulator is  described
% in:   RK-S  Kwan,  AC  Evans,  GB  Pike (1996) "An Extensible MRI
% Simulator  for  Post-Processing  Evaluation"   Visualisation   in
% Biomedical   Computing   (VBC'96).   Lecture  Notes  in  Computer
% Science, vol. 1131. Springer-Verlag. 135-140.  and:  DL  Collins,
% AP  Zijdenbos,  V  Kollokian,  JG  Sled, NJ Kabani, CJ Holmes, AC
% Evans (June 1998) "Design and Construction of a Realistic Digital
% Brain  Phantom"  IEEE  Transactions  on  Medical Imaging, vol.17,
% No.3, p.463-468.
% 
% =======================================================================
% Note that the images are in neurological orientation, whereby the
% left  side  of  the  image  refers to the left side of the brain.
% This is contrary to the orientation that Analyze  expects  images
% to be in.
% 
% To generate your own templates which fill the same volume, use  a
% bounding  box of -90:90 -126:90 -72:108, and voxel sizes of 2x2x2
% mm.
%
% =======================================================================
% The images were converted from the .img format of SPM99 to resolve
% confusion about left- versus right-handedness of co-ordinate systems.
% _______________________________________________________________________
% Copyright (C) 2008 Wellcome Trust Centre for Neuroimaging

% John Ashburner
% $Id: spm_templates.man 2025 2008-08-28 17:48:19Z john $