The EEG

1. The EEG What does EEG actually measure?

2. Neurons are Electrical • Remember that Neurons have electrically charged membranes • they also rapidly discharge and recharge those membranes (graded potentials and action potentials)

3. Electroencephalography • pyramidal cells span layers of cortex and have parallel cell bodies • their combined extracellular field is small but measurable at the scalp!

4. Whenever you build up charge in one place it tries to go somewhere else Voltage is a measure of the force with which charge tries to move

5. Electroencephalography • pyramidal cells span layers of cortex and have parallel cell bodies • their combined extracellular field is small but measurable at the scalp!

6. Electroencephalography • Cell bodies and apical dendrites tend to be pointed in the same direction • Perpendicular to the surface of the cortex

7. Electroencephalography • The field generated by a patch of cortex can be modeled as a single equivalent dipolar current source with some orientation (assumed to be perpendicular to cortical surface) Duracell

8. The “forward solution” • If we knew which parts of the brain were electrically active at a given time… • And if we knew the orientation of the cortex at those points… • And if we knew a few other parameters about the skull and scalp… • We could figure out what the voltage would be at each point on the scalp! Duracell

9. The “inverse solution” • EEG research at its essence is the process of running those steps in reverse Duracell

10. The “inverse solution” • The first couple weeks of class will be spent running EEG “backwards” using the BESA dipole simulator • We’ll make a hypothetical data set • Then we’ll analyze it as if it were real • Then we’ll collect real data and see how well they match • Don’t get your hopes up…they won’t match all that well

11. Electricity made inaccurately simple: • No such thing as voltage “at” a point • Battery analogy – you can’t record voltage from a single end • You always need a second point which we usually call a “ground” • Why not use “ground” as ground? • Potentially really dangerous! • Totally unnecessary

12. Why not use “ground” as ground? • Potentially really dangerous! • Voltage would fluctuate wildly due to many other factors

13. A simple virtual ground circuit • Use some other part of the head • Basically that makes a really good receive antennae – picks up EVERYTHING! • Noisy! • Picks up radio frequency noise from many sources (outside the head

14. A differential circuit • Also called “common-mode rejection” • Also called “balanced line” • Active electrode = V – 0 = V • Notice what happens when external RF noise comes in – it gets “rejected” by the circuit (V + noise) – (0 + noise) = V – 0 = V Active – ground = V Reference – ground = “zero”

15. Common mode rejection works as long as the electrodes have the same electrical characteristics • The most important of these is impedance • We must ensure that the impedance of each electrode is low and consistent with the others

16. Choosing reference site • Ideally it would be independent of brain electrical activity but that doesn’t really exist • Instead we’ll compute a “virtual” reference that is the average of each of the electrodes