Portfolio Decisions and Brain Reactions via the CEAD method

Decision making can be a complex process requiring the integration of several attributes of choice options. Understanding the neural processes underlying (uncertain) investment decisions is an important topic in neuroeconomics. We analyzed functional magnetic resonance imaging (fMRI) data from an in...

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Bibliographic Details
Published in:Psychometrika 2016-09, Vol.81 (3), p.881-903
Main Authors: Majer, Piotr, Mohr, Peter N. C., Heekeren, Hauke R., Härdle, Wolfgang K.
Format: Article
Language:English
Subjects:
Algorithms
Assessment
Attitude
Attitudes
Behavioral Science and Psychology
Brain
Brain - diagnostic imaging
Brain - physiology
Brain Mapping
Cerebral Cortex - physiology
Choice Behavior - physiology
Cluster Analysis
Cognitive Psychology
Decision making
Decision Making - physiology
Factor Structure
Functional Neuroimaging
Hemodynamics
Humanities
Humans
Hypotheses
Individual Differences
Investment
Law
Linear Models
Magnetic Resonance Imaging
Mathematics
Methods
Models, Statistical
Neurosciences
Prefrontal Cortex - physiology
Psychology
Psychometrics
Research Design
Resistance (Psychology)
Risk
Signal to noise ratio
Statistical Theory and Methods
Statistics for Social Sciences
Testing and Evaluation
Time series
Utility functions
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Summary:Decision making can be a complex process requiring the integration of several attributes of choice options. Understanding the neural processes underlying (uncertain) investment decisions is an important topic in neuroeconomics. We analyzed functional magnetic resonance imaging (fMRI) data from an investment decision study for stimulus-related effects. We propose a new technique for identifying activated brain regions: cluster, estimation, activation, and decision method. Our analysis is focused on clusters of voxels rather than voxel units. Thus, we achieve a higher signal-to-noise ratio within the unit tested and a smaller number of hypothesis tests compared with the often used General Linear Model (GLM). We propose to first conduct the brain parcellation by applying spatially constrained spectral clustering. The information within each cluster can then be extracted by the flexible dynamic semiparametric factor model (DSFM) dimension reduction technique and finally be tested for differences in activation between conditions. This sequence of Cluster, Estimation, Activation, and Decision admits a model-free analysis of the local fMRI signal. Applying a GLM on the DSFM-based time series resulted in a significant correlation between the risk of choice options and changes in fMRI signal in the anterior insula and dorsomedial prefrontal cortex. Additionally, individual differences in decision-related reactions within the DSFM time series predicted individual differences in risk attitudes as modeled with the framework of the mean-variance model.
ISSN:0033-3123
1860-0980
DOI:10.1007/s11336-015-9441-5