Source localization with equivalent current dipole (ECD) fit

This shows how to fit a dipole 1 using mne-python.

For a comparison of fits between MNE-C and mne-python, see this gist.

from os import path as op
import numpy as np
import matplotlib.pyplot as plt

import mne
from mne.forward import make_forward_dipole
from mne.evoked import combine_evoked
from mne.simulation import simulate_evoked

from nilearn.plotting import plot_anat
from nilearn.datasets import load_mni152_template

data_path = mne.datasets.sample.data_path()
subjects_dir = op.join(data_path, 'subjects')
fname_ave = op.join(data_path, 'MEG', 'sample', 'sample_audvis-ave.fif')
fname_cov = op.join(data_path, 'MEG', 'sample', 'sample_audvis-cov.fif')
fname_bem = op.join(subjects_dir, 'sample', 'bem', 'sample-5120-bem-sol.fif')
fname_trans = op.join(data_path, 'MEG', 'sample',
                      'sample_audvis_raw-trans.fif')
fname_surf_lh = op.join(subjects_dir, 'sample', 'surf', 'lh.white')

Let’s localize the N100m (using MEG only)

evoked = mne.read_evokeds(fname_ave, condition='Right Auditory',
                          baseline=(None, 0))
evoked.pick_types(meg=True, eeg=False)
evoked_full = evoked.copy()
evoked.crop(0.07, 0.08)

# Fit a dipole
dip = mne.fit_dipole(evoked, fname_cov, fname_bem, fname_trans)[0]

# Plot the result in 3D brain with the MRI image.
dip.plot_locations(fname_trans, 'sample', subjects_dir, mode='orthoview')
Dipole #7 / 7 @ 0.080s, GOF: 56.9%, 39.7nAm MRI: (-56.9, -19.7, 26.1) mm

Out:

Reading /home/circleci/mne_data/MNE-sample-data/MEG/sample/sample_audvis-ave.fif ...
    Read a total of 4 projection items:
        PCA-v1 (1 x 102) active
        PCA-v2 (1 x 102) active
        PCA-v3 (1 x 102) active
        Average EEG reference (1 x 60) active
    Found the data of interest:
        t =    -199.80 ...     499.49 ms (Right Auditory)
        0 CTF compensation matrices available
        nave = 61 - aspect type = 100
Projections have already been applied. Setting proj attribute to True.
Applying baseline correction (mode: mean)
Removing projector <Projection | Average EEG reference, active : True, n_channels : 60>
MRI transform     : /home/circleci/mne_data/MNE-sample-data/MEG/sample/sample_audvis_raw-trans.fif
Head origin       :   -4.3   18.4   67.0 mm rad =   71.8 mm.
Guess grid        :   20.0 mm
Guess mindist     :    5.0 mm
Guess exclude     :   20.0 mm
Using standard MEG coil definitions.
Noise covariance  : /home/circleci/mne_data/MNE-sample-data/MEG/sample/sample_audvis-cov.fif

Coordinate transformation: MRI (surface RAS) -> head
     0.999310  0.009985 -0.035787      -3.17 mm
     0.012759  0.812405  0.582954       6.86 mm
     0.034894 -0.583008  0.811716      28.88 mm
     0.000000  0.000000  0.000000       1.00
Coordinate transformation: MEG device -> head
     0.991420 -0.039936 -0.124467      -6.13 mm
     0.060661  0.984012  0.167456       0.06 mm
     0.115790 -0.173570  0.977991      64.74 mm
     0.000000  0.000000  0.000000       1.00
0 bad channels total
Read 305 MEG channels from info
99 coil definitions read
Coordinate transformation: MEG device -> head
     0.991420 -0.039936 -0.124467      -6.13 mm
     0.060661  0.984012  0.167456       0.06 mm
     0.115790 -0.173570  0.977991      64.74 mm
     0.000000  0.000000  0.000000       1.00
MEG coil definitions created in head coordinates.
Decomposing the sensor noise covariance matrix...
    Created an SSP operator (subspace dimension = 3)
Computing rank from covariance with rank=None
    Using tolerance 3.3e-13 (2.2e-16 eps * 305 dim * 4.8  max singular value)
    Estimated rank (mag + grad): 302
    MEG: rank 302 computed from 305 data channels with 3 projectors
    Setting small MEG eigenvalues to zero (without PCA)
    Created the whitener using a noise covariance matrix with rank 302 (3 small eigenvalues omitted)

---- Computing the forward solution for the guesses...
Guess surface (inner skull) is in MRI (surface RAS) coordinates
Filtering (grid =     20 mm)...
Surface CM = (   0.7  -10.0   44.3) mm
Surface fits inside a sphere with radius   91.8 mm
Surface extent:
    x =  -66.7 ...   68.8 mm
    y =  -88.0 ...   79.0 mm
    z =  -44.5 ...  105.8 mm
Grid extent:
    x =  -80.0 ...   80.0 mm
    y = -100.0 ...   80.0 mm
    z =  -60.0 ...  120.0 mm
900 sources before omitting any.
396 sources after omitting infeasible sources not within 20.0 - 91.8 mm.
Source spaces are in MRI coordinates.
Checking that the sources are inside the surface and at least    5.0 mm away (will take a few...)
    Skipping interior check for 42 sources that fit inside a sphere of radius   43.6 mm
    Skipping solid angle check for 186 points using Qhull
    195 source space points omitted because they are outside the inner skull surface.
    45 source space points omitted because of the    5.0-mm distance limit.
156 sources remaining after excluding the sources outside the surface and less than    5.0 mm inside.
Go through all guess source locations...
[done 156 sources]
---- Fitted :    69.9 ms, distance to inner skull : 10.7185 mm
---- Fitted :    71.6 ms, distance to inner skull : 10.6265 mm
---- Fitted :    73.3 ms, distance to inner skull : 10.5323 mm
---- Fitted :    74.9 ms, distance to inner skull : 10.2121 mm
---- Fitted :    76.6 ms, distance to inner skull : 10.0605 mm
---- Fitted :    78.3 ms, distance to inner skull : 9.7517 mm
---- Fitted :    79.9 ms, distance to inner skull : 9.4769 mm
Projections have already been applied. Setting proj attribute to True.
7 time points fitted

Plot the result in 3D brain with the MRI image using Nilearn In MRI coordinates and in MNI coordinates (template brain)

trans = mne.read_trans(fname_trans)
subject = 'sample'
mni_pos = mne.head_to_mni(dip.pos, mri_head_t=trans,
                          subject=subject, subjects_dir=subjects_dir)

mri_pos = mne.head_to_mri(dip.pos, mri_head_t=trans,
                          subject=subject, subjects_dir=subjects_dir)

t1_fname = op.join(subjects_dir, subject, 'mri', 'T1.mgz')
fig_T1 = plot_anat(t1_fname, cut_coords=mri_pos[0], title='Dipole loc.')

template = load_mni152_template()
fig_template = plot_anat(template, cut_coords=mni_pos[0],
                         title='Dipole loc. (MNI Space)')
  • plot dipole fit
  • plot dipole fit

Calculate and visualise magnetic field predicted by dipole with maximum GOF and compare to the measured data, highlighting the ipsilateral (right) source

fwd, stc = make_forward_dipole(dip, fname_bem, evoked.info, fname_trans)
pred_evoked = simulate_evoked(fwd, stc, evoked.info, cov=None, nave=np.inf)

# find time point with highest GOF to plot
best_idx = np.argmax(dip.gof)
best_time = dip.times[best_idx]
print('Highest GOF %0.1f%% at t=%0.1f ms with confidence volume %0.1f cm^3'
      % (dip.gof[best_idx], best_time * 1000,
         dip.conf['vol'][best_idx] * 100 ** 3))
# remember to create a subplot for the colorbar
fig, axes = plt.subplots(nrows=1, ncols=4, figsize=[10., 3.4],
                         gridspec_kw=dict(width_ratios=[1, 1, 1, 0.1],
                                          top=0.85))
vmin, vmax = -400, 400  # make sure each plot has same colour range

# first plot the topography at the time of the best fitting (single) dipole
plot_params = dict(times=best_time, ch_type='mag', outlines='skirt',
                   colorbar=False, time_unit='s')
evoked.plot_topomap(time_format='Measured field', axes=axes[0], **plot_params)

# compare this to the predicted field
pred_evoked.plot_topomap(time_format='Predicted field', axes=axes[1],
                         **plot_params)

# Subtract predicted from measured data (apply equal weights)
diff = combine_evoked([evoked, pred_evoked], weights=[1, -1])
plot_params['colorbar'] = True
diff.plot_topomap(time_format='Difference', axes=axes[2:], **plot_params)
fig.suptitle('Comparison of measured and predicted fields '
             'at {:.0f} ms'.format(best_time * 1000.), fontsize=16)
fig.tight_layout()
Comparison of measured and predicted fields at 80 ms, Measured field, Predicted field, Difference, fT

Out:

Positions (in meters) and orientations
7 sources
Source space          : <SourceSpaces: [<discrete, n_used=7>] head coords, ~3 kB>
MRI -> head transform : /home/circleci/mne_data/MNE-sample-data/MEG/sample/sample_audvis_raw-trans.fif
Measurement data      : instance of Info
Conductor model   : /home/circleci/mne_data/MNE-sample-data/subjects/sample/bem/sample-5120-bem-sol.fif
Accurate field computations
Do computations in head coordinates
Free source orientations

Read 1 source spaces a total of 7 active source locations

Coordinate transformation: MRI (surface RAS) -> head
     0.999310  0.009985 -0.035787      -3.17 mm
     0.012759  0.812405  0.582954       6.86 mm
     0.034894 -0.583008  0.811716      28.88 mm
     0.000000  0.000000  0.000000       1.00

Read 305 MEG channels from info
99 coil definitions read
Coordinate transformation: MEG device -> head
     0.991420 -0.039936 -0.124467      -6.13 mm
     0.060661  0.984012  0.167456       0.06 mm
     0.115790 -0.173570  0.977991      64.74 mm
     0.000000  0.000000  0.000000       1.00
MEG coil definitions created in head coordinates.
Source spaces are now in head coordinates.

Setting up the BEM model using /home/circleci/mne_data/MNE-sample-data/subjects/sample/bem/sample-5120-bem-sol.fif...

Loading surfaces...

Loading the solution matrix...

Homogeneous model surface loaded.
Loaded linear_collocation BEM solution from /home/circleci/mne_data/MNE-sample-data/subjects/sample/bem/sample-5120-bem-sol.fif
Employing the head->MRI coordinate transform with the BEM model.
BEM model sample-5120-bem-sol.fif is now set up

Source spaces are in head coordinates.
Checking that the sources are inside the surface (will take a few...)
    Skipping interior check for 0 sources that fit inside a sphere of radius   43.6 mm
    Skipping solid angle check for 0 points using Qhull

Setting up compensation data...
    No compensation set. Nothing more to do.

Composing the field computation matrix...
Computing MEG at 7 source locations (free orientations)...

Finished.
    Changing to fixed-orientation forward solution with surface-based source orientations...
    [done]
Projecting source estimate to sensor space...
[done]
Highest GOF 56.9% at t=79.9 ms with confidence volume 8.1 cm^3
/home/circleci/project/tutorials/source-modeling/plot_dipole_fit.py:100: UserWarning: This figure includes Axes that are not compatible with tight_layout, so results might be incorrect.
  fig.tight_layout()

Estimate the time course of a single dipole with fixed position and orientation (the one that maximized GOF) over the entire interval

Dipole (1 channel), Goodness of fit (1 channel)

Out:

MRI transform     : /home/circleci/mne_data/MNE-sample-data/MEG/sample/sample_audvis_raw-trans.fif
Head origin       :   -4.3   18.4   67.0 mm rad =   71.8 mm.
Fixed position    :  -61.1    5.3   59.6 mm
Fixed orientation  : 0.0113 -0.7506 -0.6606 mm
Noise covariance  : /home/circleci/mne_data/MNE-sample-data/MEG/sample/sample_audvis-cov.fif

Coordinate transformation: MRI (surface RAS) -> head
     0.999310  0.009985 -0.035787      -3.17 mm
     0.012759  0.812405  0.582954       6.86 mm
     0.034894 -0.583008  0.811716      28.88 mm
     0.000000  0.000000  0.000000       1.00
Coordinate transformation: MEG device -> head
     0.991420 -0.039936 -0.124467      -6.13 mm
     0.060661  0.984012  0.167456       0.06 mm
     0.115790 -0.173570  0.977991      64.74 mm
     0.000000  0.000000  0.000000       1.00
0 bad channels total
Read 305 MEG channels from info
99 coil definitions read
Coordinate transformation: MEG device -> head
     0.991420 -0.039936 -0.124467      -6.13 mm
     0.060661  0.984012  0.167456       0.06 mm
     0.115790 -0.173570  0.977991      64.74 mm
     0.000000  0.000000  0.000000       1.00
MEG coil definitions created in head coordinates.
Decomposing the sensor noise covariance matrix...
    Created an SSP operator (subspace dimension = 3)
Computing rank from covariance with rank=None
    Using tolerance 3.3e-13 (2.2e-16 eps * 305 dim * 4.8  max singular value)
    Estimated rank (mag + grad): 302
    MEG: rank 302 computed from 305 data channels with 3 projectors
    Setting small MEG eigenvalues to zero (without PCA)
    Created the whitener using a noise covariance matrix with rank 302 (3 small eigenvalues omitted)
Compute forward for dipole location...
[done 1 source]
Projections have already been applied. Setting proj attribute to True.
421 time points fitted

References

1

Jukka Sarvas. Basic mathematical and electromagnetic concepts of the biomagnetic inverse problem. Physics in Medicine and Biology, 32(1):11–22, 1987. doi:10.1088/0031-9155/32/1/004.

Total running time of the script: ( 0 minutes 57.931 seconds)

Estimated memory usage: 273 MB

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