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What are we measuring in EEG and MEG?. Methods for Dummies 2007 Matthew Longo. Basic Logic. Electrical activity of neurons produces currents spreading through the head.
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What are we measuring in EEG and MEG? Methods for Dummies 2007 Matthew Longo
Basic Logic • Electrical activity of neurons produces currents spreading through the head. • These currents reach the surface of the scalp, in the form of voltage changes and magnetic fields, both of which can be measured non-invasively. • Measured voltage changes at the scalp are called the electroencephologram (EEG). • Measured magnetic fields at the scalp are called the magnetoencephologram (MEG).
Electrical Activity in the Cortex • Excitatory postsynaptic potential (EPSP) • Postsynaptic • Dendritic • Measurable by EEG/MEG • Action Potential • Presynaptic • Axonal • Generally notmeasurable by EEG/MEG
Apical dendrites are oriented in parallel along the cortical sheet • Apical dendrites thought to contribute strongest signals measurable with EEG/MEG • Axons are more randomly located, resulting in currents from presynaptic action potentials cancelling each other out • Postsynaptic electrical activity (EPSP) sums, creating large “dipole”
EEG and MEG Signals • EPSPs of parallel dendrites in cortical columns creates: • Primary current (what we want to know about) • Secondary/volume currents • Measured by EEG • Influenced by intervening tissue • Magnetic field perpendicular to primary current • Measured by MEG • Unaffected by intervening tissue
Spatial Resolution • Single synapse on dendrite contributes ~20 fA-m (femto = 10-15 = one quadrillionth) • Empirical observations suggest EEG/MEG signals are typically ~ 10 nA-m (nano = 10-9 = one millionth) • Therefore, typical EEG/MEG signals reflect summed activity of ~ 500,000 – 1,000,000 neurons • ~ 1-5 mm2 of cortex forms lower bound of spatial resolution • In practice, the inverse problem further limits the ability to spatially pinpoint EEG/MEG signals.
MEG Signals • MEG measures the fluctuations of frequency (Hz) and amplitude (T) of the brain magnetic signal • 10 fT (10-15) to about several pT (10-12) • Earth’s magnetic field ~ .5 mT • Requires: • Preposterously sensitive magnetometer (SQUID) • Shielding from external noise
The SQUID • Superconducting Quantum Interference Device (SQUID)
Further Reading • Baillet et al. (2001). Electromagnetic brain mapping. IEEE Signal Processing Magazine. • Del Gratta et al. (2001). Reports on the Progress of Physics, 64, 1759-1814. • Hämäläinen et al. (1993). Review of Modern Physics, 65, 413-497. • Murakami & Okada. (2006). Journal of Physiology, 575.3, 925-936. • Nunez & Silberstein. (2000). Brain Topography, 13, 79-96.