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Voxel-Based Morphometry with Unified Segmentation
Ged Ridgway Centre for Medical Image Computing University College London Thanks to: John Ashburner and the FIL Methods Group.
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Preprocessing in SPM Realignment Slice-time correction Coregistration
With non-linear unwarping for EPI fMRI Slice-time correction Coregistration Normalisation Segmentation Smoothing SPM5’s unified tissue segmentation and spatial normalisation procedure But first, an introduction to Computational Neuroanatomy
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Aims of computational neuroanatomy
Many interesting and clinically important questions might relate to the shape or local size of regions of the brain For example, whether (and where) local patterns of brain morphometry help to: Distinguish schizophrenics from healthy controls Understand plasticity, e.g. when learning new skills Explain the changes seen in development and aging Differentiate degenerative disease from healthy aging Evaluate subjects on drug treatments versus placebo
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Alzheimer’s Disease example
Baseline Image Standard clinical MRI 1.5T T1 SPGR 1x1x1.5mm voxels Repeat image 12 month follow-up rigidly registered Subtraction image
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Group-wise statistics
SPM for group fMRI Group-wise statistics fMRI time-series Preprocessing Stat. modelling Results query “Contrast” Image spm T Image fMRI time-series Preprocessing Stat. modelling “Contrast” Image Results query fMRI time-series Preprocessing Stat. modelling “Contrast” Image Results query
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Group-wise statistics
SPM for structural MRI Group-wise statistics ? High-res T1 MRI ? High-res T1 MRI ? High-res T1 MRI ?
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The need for tissue segmentation
High-resolution MRI reveals fine structural detail in the brain, but not all of it reliable or interesting Noise, intensity-inhomogeneity, vasculature, … MR Intensity is usually not quantitatively meaningful (in the same way that e.g. CT is) fMRI time-series allow signal changes to be analysed statistically, compared to baseline or global values Regional volumes of the three main tissue types: gray matter, white matter and CSF, are well-defined and potentially very interesting
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Examples of segmentation
GM and WM segmentations overlaid on original images Structural image, GM and WM segments, and brain-mask (sum of GM and WM)
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Segmentation – basic approach
Intensities are modelled by a Gaussian Mixture Model (AKA Mixture Of Gaussians) With a specified number of components Parameterised by means, variances and mixing proportions (prior probabilities for components)
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Non-Gaussian Intensity Distributions
Multiple MoG components per tissue class allow non-Gaussian distributions to be modelled E.g. accounting for partial volume effects Or possibility of deep GM differing from cortical GM
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Tissue Probability Maps
Tissue probability maps (TPMs) can be used to provide a spatially varying prior distribution, which is tuned by the mixing proportions These TPMs come from the segmented images of many subjects, done by the ICBM project
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Class priors The probability of class k at voxel i, given weights γ is then: Where bij is the value of the jth TPM at voxel i.
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Aligning the tissue probability maps
Initially affine-registered using a multi-dimensional form of mutual information Iteratively warped to improve the fit of the unified segmentation model to the data Familiar DCT-basis function concept, as used in normalisation
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MRI Bias Correction MR Images are corupted by smoothly varying intensity inhomogeneity caused by magnetic field imperfections and subject-field interactions Would make intensity distribution spatially variable A smooth intensity correction can be modelled by a linear combination of DCT basis functions
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Summary of the unified model
SPM5 implements a generative model Principled Bayesian probabilistic formulation Combines deformable tissue probability maps with Gaussian mixture model segmentation The inverse of the transformation that aligns the TPMs can be used to normalise the original image Bias correction is included within the model
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Segmentation clean-up
Results may contain some non-brain tissue (dura, scalp, etc.) This can be removed automatically using simple morphological filtering operations Erosion Conditional dilation Lower segmentations have been cleaned up
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Limitations of the current model
Assumes that the brain consists of only GM and WM, with some CSF around it. No model for lesions (stroke, tumours, etc) Prior probability model is based on relatively young and healthy brains Less appropriate for subjects outside this population Needs reasonable quality images to work with No severe artefacts Good separation of intensities Good initial alignment with TPMs...
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Possible future work (guesses)
Multispectral modelling NB Tasks>Tools>Old Segment still useful for this in SPM5 Deeper Bayesian philosophy E.g. priors over means and variances Marginalisation of nuisance variables Model comparison Groupwise model (enormous!) Combination with DARTEL (see later) More tissue priors e.g. deep grey, meninges, etc. Imaging physics See Fischl et al. 2004, as cited in A&F introduction
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Voxel-Based Morphometry
In essence VBM is Statistical Parametric Mapping of segmented tissue density The exact interpretation of gray matter concentration or density is complicated, and depends on the preprocessing steps used It is not interpretable as neuronal packing density or other cytoarchitectonic tissue properties, though changes in these microscopic properties may lead to macro- or mesoscopic VBM-detectable differences
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A brief history of VBM A Voxel-Based Method for the Statistical Analysis of Gray and White Matter Density… Wright, McGuire, Poline, Travere, Murrary, Frith, Frackowiak and Friston. NeuroImage 2(4), 1995 (!) Rigid reorientation (by eye), semi-automatic scalp editing and segmentation, 8mm smoothing, SPM statistics, global covars. Voxel-Based Morphometry – The Methods. Ashburner and Friston. NeuroImage 11(6 pt.1), 2000 Non-linear spatial normalisation, automatic segmentation Thorough consideration of assumptions and confounds
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A brief history of VBM A Voxel-Based Morphometric Study of Ageing… Good, Johnsrude, Ashburner, Henson and Friston. NeuroImage 14(1), 2001 Optimised GM-normalisation (“a half-baked procedure”), modulation of segments with Jacobian determinants Unified Segmentation. Ashburner and Friston. NeuroImage 26(3), 2005 Principled generative model for segmentation using deformable priors A Fast Diffeomorphic Image Registration Algorithm. Ashburner. Neuroimage 38(1), 2007 Large deformation normalisation to average shape templates …
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VBM overview Unified segmentation and spatial normalisation
Optional modulation with Jacobian determinant Optional computation of tissue totals/globals Gaussian smoothing Voxel-wise statistical analysis
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VBM in pictures Segment Normalise
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VBM in pictures Segment Normalise Modulate (?) Smooth
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VBM in pictures Segment Normalise Modulate (?) Smooth
Voxel-wise statistics
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VBM in pictures Segment Normalise Modulate (?) Smooth
Voxel-wise statistics
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VBM Subtleties Whether to modulate
Adjusting for total GM or Intracranial Volume How much to smooth Limitations of linear correlation Statistical validity
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Modulation Native intensity = tissue density Multiplication of the warped (normalised) tissue intensities so that their regional or global volume is preserved Can detect differences in completely registered areas Otherwise, we preserve concentrations, and are detecting mesoscopic effects that remain after approximate registration has removed the macroscopic effects Flexible (not necessarily “perfect”) registration may not leave any such differences Modulated Unmodulated Clarify, modulation not a step (as spm2) but an option in the segment and the normalise GUIs
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“Globals” for VBM Shape is really a multivariate concept
Dependencies among volumes in different regions SPM is mass univariate Combining voxel-wise information with “global” integrated tissue volume provides a compromise Using either ANCOVA or proportional scaling Above: (ii) is globally thicker, but locally thinner than (i) – either of these effects may be of interest to us. Note globals don’t help distinguish the thickened or folded cortex... Below: The two “cortices” on the right both have equal volume… Figures from: Voxel-based morphometry of the human brain… Mechelli, Price, Friston and Ashburner. Current Medical Imaging Reviews 1(2), 2005.
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Total Intracranial Volume (TIV/ICV)
“Global” integrated tissue volume may be correlated with interesting regional effects Correcting for globals in this case may overly reduce sensitivity to local differences Total intracranial volume integrates GM, WM and CSF, or attempts to measure the skull-volume directly Not sensitive to global reduction of GM+WM (cancelled out by CSF expansion – skull is fixed!) Correcting for TIV in VBM statistics may give more powerful and/or more interpretable results
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Smoothing The analysis will be most sensitive to effects that match the shape and size of the kernel The data will be more Gaussian and closer to a continuous random field for larger kernels Results will be rough and noise-like if too little smoothing is used Too much will lead to distributed, indistinct blobs
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Smoothing Between 7 and 14mm is probably best
(lower is okay with better registration, e.g. DARTEL) The results below show two fairly extreme choices, 5mm on the left, and 16mm, right
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Nonlinearity Caution may be needed when looking for linear relationships between grey matter concentrations and some covariate of interest. Circles of uniformly increasing area. Plot of intensity at circle centres versus area Smoothed
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VBM’s statistical validity
Residuals are not normally distributed Little impact on uncorrected statistics for experiments comparing reasonably sized groups Probably invalid for experiments that compare single subjects or tiny groups with a larger control group Need to use nonparametric tests that make less assumptions, e.g. permutation testing with SnPM
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VBM’s statistical validity
Correction for multiple comparisons RFT correction based on peak heights should be OK Correction using cluster extents is problematic SPM usually assumes that the smoothness of the residuals is spatially stationary VBM residuals have spatially varying smoothness Bigger blobs expected in smoother regions Toolboxes are now available for non-stationary cluster-based correction
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Variations on VBM “All modulation, no gray matter”
Jacobian determinant “Tensor” Based Morphometry Davatzikos et al. (1996) JCAT 20:88-97 Deformation field morphometry Cao and Worsley (1999) Ann Stat 27: Ashburner et al (1998) Hum Brain Mapp 6: Other variations on TBM Chung et al (2001) NeuroImage 14:
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Deformation and shape change
Figures from Ashburner and Friston, “Morphometry”, Ch.6 of Human Brain Function, 2nd Edition, Academic Press
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Deformation fields and Jacobians
Deformation vector field Original Warped Template Determinant of Jacobian Matrix encodes voxel’s volume change Jacobian Matrix
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Longitudinal VBM Intra-subject registration over time much more accurate than inter-subject normalisation Imprecise inter-subject normalisation Spatial smoothing required Different methods have been developed to reduce the danger of expansion and contraction cancelling out…
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Longitudinal VBM variations
Voxel Compression mapping separates expansion and contraction before smoothing Scahill et al (2002) PNAS 99: Longitudinal VBM multiplies longitudinal volume change with baseline or average grey matter density Chételat et al (2005) NeuroImage 27:
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Longitudinal VBM variations
Late Early Warped early Difference Early CSF Late CSF Relative volumes CSF “modulated” by relative volume Late CSF - Early CSF Late CSF - modulated CSF Smoothed
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Nonrigid registration developments
Large deformation concept Regularise velocity not displacement (syrup instead of elastic) Leads to concept of geodesic Provides a metric for distance between shapes Geodesic or Riemannian average = mean shape If velocity assumed constant computation is fast Ashburner (2007) NeuroImage 38:95-113 DARTEL toolbox in SPM5 Currently initialised from unified seg_sn.mat files
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DARTEL exponentiates a velocity flow field to get a deformation field
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Example geodesic shape average
Average on Riemannian manifold Linear Average (Not on Riemannian manifold)
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DARTEL average template evolution
Grey matter average of 452 subjects – affine Iterations 471 subjects – DARTEL
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Questioning Intersubject normalisation
Registration algorithms might find very different correspondences to human experts Crum et al. (2003) NeuroImage 20: Higher dimensional warping improves image similarity but not necessarily landmark correspondence Hellier et al. (2003) IEEE TMI 22:
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Questioning Intersubject normalisation
Subjects can have fundamentally different sulcal/gyral morphological variants Caulo et al. (2007) Am. J. Neuroradiol. 28: Sulcal landmarks don’t always match underlying cytoarchitectonics Amunts, et al. (2007) NeuroImage 37(4):1061-5
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Intersubject normalisation opportunities
High-field high-resolution MR may have potential to image cytoarchitecture Will registration be better or worse at higher resolution? More information to use More severe discrepancies? Need rougher deformations Non-diffeomorphic? 4.7T FSE De Vita et al (2003) Br J Radiol 76:631-7
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Intersubject normalisation opportunities
Regions of interest for fMRI can be defined from functional localisers or orthogonal SPM contrasts No obvious equivalent for single-subject structural MR Potential to include diffusion-weighted MRI information in registration ? Zhang et al. (2006) Med. Image Analysis 10:
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Summary of key points VBM performs voxel-wise statistical analysis on smoothed (modulated) normalised segments SPM5 performs segmentation and spatial normalisation in a unified generative model Intersubject correspondence is imperfect Smoothing alleviates this problem to some extent Also improves statistical validity Some current research is focussed on more sophisticated registration models
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Unified segmentation in detail
An alternative explanation to the paper and to John’s slides from London ‘07
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Unified segmentation from the GMM upwards… The standard Gaussian mixture model
Voxel i, class k Assumes independence (but spatial priors later...) Could solve with EM (1-5)
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Unified segmentation from the GMM upwards… Spatially modify mean and variance with bias field
Note spatial dependence (on voxel i), [coefficients for linear combination of DCT basis functions] (10)
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Unified segmentation from the GMM upwards… Anatomical priors through mixing coefficients
Note spatial dependence (on voxel i) Basic idea Implementation prespecified: estimated: (12)
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Unified segmentation from the GMM upwards… Aside: MRF Priors (A&F, Gaser’s VBM5 toolbox)
probable number of neighbours in class m, for voxel i (45)
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Unified segmentation from the GMM upwards… Spatially deformable priors (inverse of normalisation)
Prior for voxel i depends on some general transformation model, parameterised by α Simple idea! Optimisation is tricky… SPM5’s model is affine + DCT warp With ~1000 DCT basis functions (13)
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Unified segmentation from the GMM upwards… Spatially deformable priors (inverse of normalisation)
(14, pretty much)
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Unified segmentation from the GMM upwards… Objective function so far…
(14, I think...)
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Unified segmentation from the GMM upwards… Objective function with regularisation
Assumes priors independent gives deformation’s bending energy (15,16)
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Unified segmentation from the GMM upwards… Optimisation approach
Maximising: With respect to is very difficult… Iterated Conditional Modes is used – this alternately optimises certain sets of parameters, while keeping the rest fixed at their current best solution
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Unified segmentation from the GMM upwards… Optimisation approach
EM used for mixture parameters Levenberg Marquardt (LM) used for bias and warping parameters Note unified segmentation model with Gaussian assumptions has a “least-squares like” log(objective) making it ideal for Gauss-Newton or LM optimisation Local opt, so starting estimates must be good May need to manually reorient troublesome scans
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Unified segmentation from the GMM upwards… Optimisation approach
Figure from C. Gaser Repeat until convergence… Hold γ, μ, σ2 and α constant, and minimise E w.r.t. b Levenberg-Marquardt strategy, using dE/dβ and d2E/dβ2 Hold γ, μ, σ2 and β constant, and minimise E w.r.t. α Levenberg-Marquardt strategy, using dE/dα and d2E/dα2 Hold α and β constant, and minimise E w.r.t. γ, μ and σ2 Expectation Maximisation
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Note ICM steps
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Results of the Generative model
Key flaw, lack of neighbourhood correlation – “whiteness” of noise Motivates (H)MRF priors, which should encourage contiguous tissue classes (Note, MRF prior is not equivalent to smoothing each resultant tissue segment, but differences in eventual SPMs may be minor…)
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