Inverse Current Source Density Method in Two Dimensions: Inferring Neural Activation from Multielectrode Recordings

Inverse Current Source Density Method in Two Dimensions: Inferring Neural Activation from Multielectrode Recordings

The recent development of large multielectrode recording arrays has made it affordable for an increasing number of laboratories to record from multiple brain regions simultaneously. The development of analytical tools for array data, however, lags behind these technological advances in hardware. In...

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Bibliographic Details
Published in:Neuroinformatics (Totowa, N.J.) Vol. 9; no. 4; pp. 401 - 425
Main Authors: Łęski, Szymon, Pettersen, Klas H., Tunstall, Beth, Einevoll, Gaute T., Gigg, John, Wójcik, Daniel K.
Format: Journal Article
Language:English
Published: New York Springer-Verlag 01-12-2011
Springer Nature B.V
Subjects:
Algorithms
Animals
Bioinformatics
Biomedical and Life Sciences
Biomedicine
Brain Mapping - methods
Computational Biology/Bioinformatics
Computer Appl. in Life Sciences
Evoked Potentials - physiology
Male
Microelectrodes - standards
Models, Neurological
Neocortex - cytology
Neocortex - physiology
Neurology
Neurosciences
Original
Original Article
Pyramidal Cells - physiology
Rats
Rats, Wistar
Signal Processing, Computer-Assisted
Inverse problems
Rat
Local field potentials
Evoked potentials
Current source density
Subiculum
Cortical model
Hippocampus
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Summary:The recent development of large multielectrode recording arrays has made it affordable for an increasing number of laboratories to record from multiple brain regions simultaneously. The development of analytical tools for array data, however, lags behind these technological advances in hardware. In this paper, we present a method based on forward modeling for estimating current source density from electrophysiological signals recorded on a two-dimensional grid using multi-electrode rectangular arrays. This new method, which we call two-dimensional inverse Current Source Density (iCSD 2D), is based upon and extends our previous one- and three-dimensional techniques. We test several variants of our method, both on surrogate data generated from a collection of Gaussian sources, and on model data from a population of layer 5 neocortical pyramidal neurons. We also apply the method to experimental data from the rat subiculum. The main advantages of the proposed method are the explicit specification of its assumptions, the possibility to include system-specific information as it becomes available, the ability to estimate CSD at the grid boundaries, and lower reconstruction errors when compared to the traditional approach. These features make iCSD 2D a substantial improvement over the approaches used so far and a powerful new tool for the analysis of multielectrode array data. We also provide a free GUI-based MATLAB toolbox to analyze and visualize our test data as well as user datasets.
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ISSN:1539-2791
1559-0089
DOI:10.1007/s12021-011-9111-4