Abstract
Noise-normalization has been shown to partly compensate for the localization bias towards superficial sources in minimum norm estimation. However, it has been argued that in order to make inferences for the case of multiple sources, localization properties alone are insufficient. Instead, multiple measures of resolution should be applied to both point-spread and cross-talk functions (PSFs and CTFs). Here, we demonstrate that noise-normalization affects the shapes of PSFs, but not of CTFs. We evaluated PSFs and CTFs for the MNE, dSPM and sLORETA inverse operators, on the metrics dipole localization error (DLE), spatial dispersion (SD) and overall amplitude (OA). We used 306-channel MEG configurations obtained from 17 subjects in a real experiment, including individual noise covariance matrices and head geometries. We confirmed that for PSFs DLE improved after noise normalization, and is zero for sLORETA. However, SD was generally lower for the unnormalized MNE. OA distributions were similar for all three methods, indicating that all three methods may greatly underestimate some sources relative to others. The reliability of differences between methods across subjects was demonstrated using distributions of standard deviations and p-values from paired t-tests. As predicted, the shapes of CTFs were the same for all methods, reflecting the general resolution limits of the inverse problem. This means that noise-normalization is of no consequence where linear estimation procedures are used as “spatial filters.” While low DLE is advantageous for the localization of a single source, or possibly a few spatially distinct sources, the benefit for the case of complex source distributions is not obvious. We suggest that software packages for source estimation should include comprehensive tools for evaluating the performance of different methods.
Highlights
The ultimate goal of neuroimaging is to determine the accurate spatio-temporal dynamics of perceptual and cognitive processes in the human brain
The inferior sensitivity to frontal compared to posterior sources is most likely due to the fact that our participants were seated with the backs of their heads against the back of the dewar, i.e. the distance between frontal sources and the sensors was larger than for posterior sources
We compared three different distributed source solutions–minimum norm estimation (MNE), dSPM and standardized low-resolution electromagnetic tomography (sLORETA)–using three resolution metrics designed to evaluate localization error (DLE), spatial extension (SD), and amplitude estimation (OA). These metrics were applied to point-spread functions (PSFs) as well as cross-talk functions (CTFs)
Summary
The ultimate goal of neuroimaging is to determine the accurate spatio-temporal dynamics of perceptual and cognitive processes in the human brain. They defined three measures that described different aspects of PSF distributions: (1) Dipole Localization Error (DLE), i.e. the distance of a solution's peak to the true location of a point source; (2) Spatial Dispersion (SD), i.e. a measure of the “width” of the distribution around the true source location; (3) the Resolution Index (RI), reflecting how much the activity at a particular location contributes to the amplitude estimate for that location.
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