Understanding Action Potentials in Neuroscience

Via electrical chemical signals

By mechanical movements

Using light waves

Through chemical reactions

Chloride and bicarbonate

Calcium and magnesium

Iron and zinc

Sodium and potassium

They inhibit sodium channels

They bind to receptors and open sodium channels

They close potassium channels

They increase the resting membrane potential

+30 millivolts

0 millivolts

-55 millivolts

-70 millivolts

It becomes more negative

It remains unchanged

It becomes more positive

It fluctuates randomly

Sodium enters the neuron

Potassium exits the neuron

Chloride exits the neuron

Calcium enters the neuron

A state where the neuron becomes more positive than at rest

A state where the neuron becomes more negative than at rest

A state where the neuron is inactive

A state where the neuron is at equilibrium

Through chloride channels

By passive diffusion

Through the sodium-potassium pump

By calcium channels

It generates action potentials

It maintains the resting membrane potential

It inhibits neurotransmitter release

It facilitates calcium influx

Increased neuron sensitivity

Decreased neuron firing

Normal neuron function

Inhibition of neurotransmitter release