Neuronal Action Potentials and Ion Channels

To maintain the potential difference across the cell membrane

To facilitate cell division

To produce neurotransmitters

To generate electrical signals

By stopping all ion movement

By equalizing the concentration of ions inside and outside the cell

By maintaining a higher concentration of sodium outside the cell

By allowing sodium ions to enter freely

Involves no energy consumption

Dissipates with distance

Effective over long distances

Fast signal transmission

Potassium ions flood out

Sodium ions flood in

The cell stops transmitting signals

The cell becomes more negative

They dissipate over long distances

They require a lot of energy

They cannot be measured

They are too slow

A specific voltage threshold

A decrease in potassium concentration

A change in temperature

The presence of neurotransmitters

They are faster than electrotonic potentials

They do not dissipate over distance

They occur only in short bursts

They require no energy

+40 millivolts

+35 millivolts

-55 millivolts

-70 millivolts

They prevent sodium ions from entering

They help return the cell to its resting state

They close the sodium gates

They initiate the action potential

They are faster

They are more easily controlled

They require less energy

They can travel long distances without losing strength