scholarly journals Mind the drift - improving sensitivity to fMRI pattern information by accounting for temporal pattern drift

2015 ◽  
Author(s):  
Arjen Alink ◽  
Alexander Walther ◽  
Alexandra Krugliak ◽  
Jasper J.F. van den Bosch ◽  
Nikolaus Kriegeskorte
Keyword(s):  
Random Walk ◽  
Temporal Pattern ◽  
Functional Magnetic Resonance ◽  
Resonance Imaging ◽  
Linear Modeling ◽  
Cognitive States ◽  
Single Voxel ◽  
Pattern Similarity ◽  
Orientation Information ◽  
Pattern Information

Analyzing functional magnetic resonance imaging (fMRI) pattern similarity is becoming increasingly popular because it allows one to relate distributed patterns of voxel activity to continuous perceptual and cognitive states of the human brain. Here we show that fMRI pattern similarity estimates are severely affected by temporal pattern drifts in fMRI data - even after voxel-wise detrending. For this particular dataset, the drift effect obscures orientation information as measured by fMRI pattern dissimilarities. We demonstrate that orientation information can be recovered using three different methods: 1. Regressing out the drift component through linear modeling; 2. Computing representational distances between conditions measured in independent imaging runs; 3. Crossvalidation of pattern distance estimates. One possible source of temporal pattern drift could be random walk like fluctuations - physiological or scanner related - occurring within single voxel timecourses. This explanation is consistent with voxel-wise detrending not alleviating pattern drift effects. In addition, this would explain why cross-validated pattern distances are robust to temporal drift because a random walk process is expected to give rise to non-replicable drift directions. Given these findings, we recommend that future fMRI studies take pattern drift into account when analyzing pattern similarity as this can greatly enhance the sensitivity to experimental effects of interest.

scholarly journals Local opposite orientation preferences in V1: fMRI sensitivity to fine-grained pattern information

2016 ◽  
Author(s):  
Arjen Alink ◽  
Alexander Walther ◽  
Alexandra Krugliak ◽  
Nikolaus Kriegeskorte
Keyword(s):  
Magnetic Resonance Imaging ◽  
Spatial Scales ◽  
Functional Magnetic Resonance ◽  
Resonance Imaging ◽  
Opposite Orientation ◽  
Small Patch ◽  
Fine Grained ◽  
Orientation Columns ◽  
Orientation Information ◽  
Pattern Information

The orientation of a visual grating can be decoded from human primary visual cortex (V1) using functional magnetic resonance imaging (fMRI) at conventional resolutions (2-3 mm voxel width, 3T scanner). It is unclear to what extent this information originates from different spatial scales of neuronal selectivity, ranging from orientation columns to global areal maps. According to the global-areal-map account, fMRI orientation decoding relies exclusively on fMRI voxels in V1 exhibiting a radial or vertical preference. Here we show, by contrast, that 2-mm isotropic voxels in a small patch of V1 within a quarterfield representation exhibit reliable opposite selectivities. Sets of voxels with opposite selectivities are locally intermingled and each set can support orientation decoding. This indicates that global areal maps cannot fully account for orientation information in fMRI and demonstrates that fMRI also reflects fine-grained patterns of neuronal selectivity.

scholarly journals Encoding of Novel Verbal Instructions for Prospective Action in the Lateral Prefrontal Cortex: Evidence from Univariate and Multivariate Functional Magnetic Resonance Imaging Analysis

2018 ◽  
Vol 30 (8) ◽  
pp. 1170-1184 ◽  
Author(s):  
Nicolas J. Bourguignon ◽  
Senne Braem ◽  
Egbert Hartstra ◽  
Jan De Houwer ◽  
Marcel Brass
Keyword(s):  
Magnetic Resonance Imaging ◽  
Magnetic Resonance ◽  
Functional Magnetic Resonance Imaging ◽  
Premotor Cortex ◽  
Functional Magnetic Resonance ◽  
Resonance Imaging ◽  
Task Instructions ◽  
Verbal Instructions ◽  
Fmri Session ◽  
Pattern Similarity

Verbal instructions are central to humans' capacity to learn new behaviors with minimal training, but the neurocognitive mechanisms involved in verbally instructed behaviors remain puzzling. Recent functional magnetic resonance imaging (fMRI) evidence suggests that the right middle frontal gyrus and dorsal premotor cortex (rMFG-dPMC) supports the translation of symbolic stimulus–response mappings into sensorimotor representations. Here, we set out to (1) replicate this finding, (2) investigate whether this region's involvement is specific to novel (vs. trained) instructions, and (3) study whether rMFG-dPMC also shows differences in its (voxel) pattern response indicative of general cognitive processes of instruction implementation. Participants were shown instructions, which they either had to perform later or merely memorize. Orthogonal to this manipulation, the instructions were either entirely novel or had been trained before the fMRI session. Results replicate higher rMFG-dPMC activation levels during instruction implementation versus memorization and show how this difference is restricted to novel, but not trained, instruction presentations. Pattern similarity analyses at the voxel level further reveal more consistent neural pattern responses in rMFG-dPMC during the implementation of novel versus trained instructions. In fact, this more consistent neural pattern response seemed to be specific to the first instruction presentation and disappeared after the instruction had been applied once. These results further support a role of rMFG-dPMC in the implementation of novel task instructions and highlight potentially important differences in studying this region's gross activation levels versus (the consistency of) its response patterns.

Fuzzy General Linear Modeling for Functional Magnetic Resonance Imaging Analysis

2020 ◽  
Vol 28 (1) ◽  
pp. 100-111 ◽  
Author(s):  
Alejandro Veloz ◽  
Claudio Moraga ◽  
Alejandro Weinstein ◽  
Luis Hernandez-Garcia ◽  
Steren Chabert ◽  
...  
Keyword(s):  
Magnetic Resonance Imaging ◽  
Magnetic Resonance ◽  
Functional Magnetic Resonance Imaging ◽  
General Linear ◽  
Imaging Analysis ◽  
Functional Magnetic Resonance ◽  
Resonance Imaging ◽  
Linear Modeling ◽  
Magnetic Resonance Imaging Analysis

scholarly journals Meta-analytic activation maps can help identify affective processes captured by contrast-based task fMRI: the case of threat-related facial expressions

2019 ◽  
Author(s):  
M. Justin Kim ◽  
Annchen R. Knodt ◽  
Ahmad R. Hariri
Keyword(s):  
Facial Expressions ◽  
Brain Activity ◽  
Meta Analysis ◽  
Fmri Data ◽  
Functional Magnetic Resonance ◽  
Resonance Imaging ◽  
Independent Dataset ◽  
Pattern Similarity ◽  
Affective Processes ◽  
Amygdala Activity

AbstractMeta-analysis of functional magnetic resonance imaging (fMRI) data is an effective method for capturing the distributed patterns of brain activity supporting discrete cognitive and affective processes. One opportunity presented by the resulting meta-analysis maps (MAMs) is as a reference for better understanding the nature of individual contrast maps (ICMs) derived from specific task fMRI data. Here, we compared MAMs from 148 neuroimaging studies representing the broad emotion categories of fear, anger, disgust, happiness, and sadness with ICMs from fearful > neutral and angry > neutral facial expressions from an independent dataset of task fMRI (n = 1263). Analyses revealed that both fear and anger ICMs exhibited the greatest pattern similarity to fear MAMs. As the number of voxels included for the computation of pattern similarity became more selective, the specificity of MAM-ICM correspondence decreased. Notably, amygdala activity long considered critical for processing threat-related facial expressions was neither sufficient nor necessary for detecting MAM-ICM pattern similarity effects. Our analyses suggest that both fearful and angry facial expressions are best captured by distributed patterns of brain activity associated with fear. More generally, our analyses demonstrate how MAMs can be leveraged to better understand affective processes captured by ICMs in task fMRI data.

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