We will continue our effort to understand the genesis of magnetoencephalographic (MEG) signals in terms of the modern concepts of dendritic and somatic electrophysiology in order to help interpret MEG signals from the human brain in disease and health. Our work has characterized the MEG signals produced by guinea pig hippocampal slicers. Intracellular and extracellular field potential data was well as MEG signals were obtained after systematically blocking the various ligand-gated and voltage-and calcium-sensitive channels. This has brought our research to a new stage where it is possible to make some quantitative comparisons between the three types of signals and those generated by a mathematical model (Traub model) of CA3. The model we have used contains 100 excitatory cells and 20 inhibitory cells, each excitatory cell having two types of excitatory and inhibitory receptors and six different voltage- and calcium-sensitive conductances. We will Extend the Traub model to predict no only intracellular potentials, but also field potentials and MEG signals. Our modeling work has shown that the Traub model can be extended to make some quantitatively accurate predictions. We will first apply the extended model to account for the three sets of data collected thus far and identify the aspects of the data that are well explained by the model and those that are not. The comparisons will be used to revise the model to better account for the three data sets simultaneously. The revision will, for example include changes in the distribution of the channel densities and receptor site along the dendrites and addition of new channels. As the model is improved, it should be possible to infer with increasing levels of confidence the role of different types of currents in generating the MEG signals. Experimental analyses of this issue are often ambiguous even with the use of selective channel blockers. A mathematical model helps us clarity their roles since the currents can be separately calculated. On the basis of our work, we expect that the calcium conductance plays an important role in generating MEG signals and field potentials. The comparison will also be used as the basis for specifying a new set of experiments that will best characterize the role of individual channels in generating MEG signals. In one series of study, we will characterize the signals generated with synaptic transmissions blocked and the pyramidal cells directly excited. We will also combine the model and experiments to understand the MEG signals underlying spontaneous activities such as the gamma-oscillations discovered in the hippocampal slices. Our preliminary study indicates that such oscillation scan be recorded in our preparations.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS021149-15
Application #
2891638
Study Section
Neurology A Study Section (NEUA)
Program Officer
Edwards, Emmeline
Project Start
1985-03-01
Project End
2002-08-31
Budget Start
1999-09-01
Budget End
2000-08-31
Support Year
15
Fiscal Year
1999
Total Cost
Indirect Cost
Name
University of New Mexico
Department
Neurology
Type
Schools of Medicine
DUNS #
829868723
City
Albuquerque
State
NM
Country
United States
Zip Code
87131
Murakami, Shingo; Okada, Yoshio (2015) Invariance in current dipole moment density across brain structures and species: physiological constraint for neuroimaging. Neuroimage 111:49-58
Tanosaki, Masato; Ishibashi, Hideaki; Zhang, Tongsheng et al. (2014) Effective connectivity maps in the swine somatosensory cortex estimated from electrocorticography and validated with intracortical local field potential measurements. Brain Connect 4:100-11
Murakami, Shingo; Okada, Yoshio (2006) Contributions of principal neocortical neurons to magnetoencephalography and electroencephalography signals. J Physiol 575:925-36
Zhang, Tongsheng; Okada, Yoshio (2006) Recursive artifact windowed-single tone extraction method (RAW-STEM) as periodic noise filter for electrophysiological signals with interfering transients. J Neurosci Methods 155:308-18
Murakami, Shingo; Hirose, Akira; Okada, Yoshio C (2003) Contribution of ionic currents to magnetoencephalography (MEG) and electroencephalography (EEG) signals generated by guinea-pig CA3 slices. J Physiol 553:975-85
Murakami, Shingo; Zhang, Tongsheng; Hirose, Akira et al. (2002) Physiological origins of evoked magnetic fields and extracellular field potentials produced by guinea-pig CA3 hippocampal slices. J Physiol 544:237-51
Wu, J; Okada, Y C (2000) Roles of calcium- and voltage-sensitive potassium currents in the generation of neuromagnetic signals and field potentials in a CA3 longitudinal slice of the guinea-pig. Clin Neurophysiol 111:150-60
Wu, J; Okada, Y C (1999) Roles of a potassium afterhyperpolarization current in generating neuromagnetic fields and field potentials in longitudinal CA3 slices of the guinea-pig. Clin Neurophysiol 110:1858-67
Wu, J; Okada, Y C (1998) Physiological bases of the synchronized population spikes and slow wave of the magnetic field generated by a guinea-pig longitudinal CA3 slice preparation. Electroencephalogr Clin Neurophysiol 107:361-73
Okada, Y C; Wu, J; Kyuhou, S (1997) Genesis of MEG signals in a mammalian CNS structure. Electroencephalogr Clin Neurophysiol 103:474-85

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