Informatics and Applications
2014, Volume 8, Issue 2, pp 77-85
INDEPENDENT COMPONENT ANALYSIS FOR THE INVERSE PROBLEM IN THE MULTIDIPOLE MODEL OF MAGNETOENCEPHALOGRAM’S SOURCES
- V. E. Bening
- M. A. Dranitsyna
- T. V. Zakharova
- P. I. Karpov
Abstract
This paper is devoted to a challenging task of brain functional mapping which is posed due to the
current techniques of noninvasive human brain investigation. One of such techniques is magnetoencephalography
(MEG) which is very potent in the scientific and practical contexts. Large data retrieved from the MEG procedure
comprise information about brain processes. Magnetoencephalography data processing sets a highly ill-posed
problem consisting in spatial reconstruction of MEG-signal sources with a given accuracy. At the present moment,
there is no universal tool for accurate solution of such inverse problem. The same distribution of potentials on the
surface of a human head may be caused by activity of different areas within cerebral cortex. Nevertheless, under
certain assumptions, this task can be solved unambiguously. The assumptions are the following: signal sources are
discrete, belong to distinct functional areas of the brain, and have superficial location. The MEG-signal obtained
is assumed to be a superposition of multidipole signals. In this case, the solution of the inverse problem is a
multidipole approximation. The algorithm proposed assumes two main steps. The first step includes application
of independent component analysis to primary/basic MEG-signals and obtaining independent components, the
second step consists of treating these independent components separately and employing an analytical formula to
them as for monodipole model to get the isolated signal source location for each component.
[+] References (14)
- Sarvas, J. 1987. Basic mathematical and electromagnetic
concepts of the biomagnetic inverse problem. Phys.
Medicine Biol. 32(1):11–22.
- Baillet, S., J.C. Mosher, R.M. Leahy. 2001. Electromagnetic
brain mapping. IEEE Signal Processing Magazine.
7(2):14–30.
- Friston, K., L. Harrison, J. Daunizeau, S. Kiebel,
Ch. Phillips,N. Trujillo-Barreto, R. Henson,G. Flandin,
and J. Mattoutf. 2008. Multiple sparse priors for the
M/EEG inverse problem. NeuroImage 39:1104–1120.
- Zakharova, T. V., S. Yu. Nikiforov, M.B. Goncharenko,
M.A. Dranitsyna, G.A. Klimov, M. S. Khaziakhmetov,
and N. V. Chayanov. 2012. Metody obrabotki signalov
dlya lokalizatsii nevospolnimykh oblastey golovnogomozga
[Signal processingmethods for the localization of nonrenewable
brain regions]. Sistemy i Sredstva Informatiki —
Systems and Means of Informatics 22(2):157–176.
- Khaziakhmetov, M. S., and T. V. Zakharova. 2013. Ob algoritmakh
nakhozhdeniya opornykh tochek miogrammy
dlya ispol’zovaniya v lokalizatsii nevospolnimykh oblastey
golovnogo mozga [Algorithms for myogram reference
points search with the aim of irrecoverable brain regions
localization]. Statisticheskie Metody Otsenivaniya i
Proverki Gipotez. Mezhvuzovskiy Sbornik Nauchnykh Trudov
[Statistical methods for estimating and hypothesis
testing. Interuniversity Collection of Research Papers].
Perm. 25:56–63.
- Bening, V. Ye., A.K. Gorshenin, and V. Yu. Korolev. 2011.
Asimptoticheski optimal’nyy kriteriy proverki gipotez o
chisle komponent smesi veroyatnostnykh raspredeleniy
[Asymptotically optimum hypothesis test for number of
components in mixture of probability distribution]. Informatika
i ee Primeneniya — Inform. Appl. 5(3):4–16.
- Zakharova, T. V., M.B. Goncharenko, and S. Yu. Nikiforov.
2013. Metod resheniya obratnoy zadachi magnitoentsefalografii,
osnovannyy na klasterizatsii poverkhnosti
mozga [Inverse problemsolvingmethod based on clustering
of brain surface]. Statisticheskie Metody Otsenivaniya i
Proverki Gipotez. Mezhvuzovskiy Sbornik Nauchnykh Trudov
[Statistical methods for estimating and hypothesis
testing. Interuniversity Collection of Research Papers].
Perm. 25:120–125.
- Hyvarinen, A., J. Karhunen, and E. Oja. 2001. Independent
component analysis. New-York: John Wiley & Sons.
504 p.
- Landau, L.D., L.P. Pitaevskii, and E.M. Lifshitz. 1984.
Electrodynamics of continuous media. New York: Pergamon.
432 p.
- Hamalainen, M., R. Hari, R. J. Ilmoniemi, J. Knuutila,
and O. V. Lounasmaa. 1993. Magnetoencephalography—
theory, instrumentation, and applications to noninvasive
studies of the working human brain. Rev. Modern Phys.
65:413–497.
- Mosher, J.C., P. S. Lewis, and R.M. Leahy. 1992. Multiple
dipolemodeling and localization fromspatio-temporal
MEG Data. IEEE Trans. Biomedical Eng. 39(6):541.
- Uitert, R., D. Weinstein, and C. Johnson. 2002. Can a
spherical model substitute for a realistic head model in
forward and inverse MEG simulations? 13th Conference
(International) on Biomagnetism Proceedings. Jena, Germany.
798–800.
- Ilmoniemi, R. J., M. S. Hamalainen, and J. Knuutila.
1985. The forward and inverse problems in the spherical
model. Biomagnetism: Applications and theory. Eds. Weinberg,
H., G. Stroink, and T. Katila. New York: Pergamon.
278–282.
- Korolev, V. Yu., V. E. Bening, and S. Ya. Shorgin. 2011.
Matematicheskie osnovy teorii riska [Mathematical basics
of risk theory]. Moscow: Fizmatlit. 620 p.
[+] About this article
Title
INDEPENDENT COMPONENT ANALYSIS FOR THE INVERSE PROBLEM IN THE MULTIDIPOLE MODEL OF MAGNETOENCEPHALOGRAM’S SOURCES
Journal
Informatics and Applications
2014, Volume 8, Issue 2, pp 77-85
Cover Date
2014-03-31
DOI
10.14357/19922264140208
Print ISSN
1992-2264
Publisher
Institute of Informatics Problems, Russian Academy of Sciences
Additional Links
Key words
independent component analysis; normal distribution; current dipole; multidipole model; magnetoencephalogram
Authors
V. E. Bening  , 
, M.A. Dranitsyna , T. V. Zakharova , and P. I. Karpov 
Author Affiliations
Department of Mathematical Statistics, Faculty of Computational Mathematics and Cybernetics,
M. V. Lomonosov Moscow State University, 1-52 Leninskiye Gory, GSP-1,Moscow 119991, Russian
Federation
Institute of Informatics Problems, Russian Academy of Sciences, 44-2 Vavilov Str.,Moscow 119333, Russian
Federation
Department of Theoretical Physics and Quantum Technologies, College of New Materials and Nanotechnology,
National University of Science and Technology “MISiS,” 4 Leninskiy Prosp.,Moscow, Russian Federation
|