Changing Membrane Potential Flashcards
why are neurons electrically excitable?
because of the resting membrane potential!
ligand gated channels
respond to chemical stimuli
(ligand binds to receptor)
- found in dendrites of some sensory neurons (pain) and dendrites and cell bodies of CNS and motor neurons
mechanically gated channels
respond to mechanical vibration or pressure stimuli
- dendrites of some sensory neurons (touch, pressure and some pain)
voltage gated ion channels
respond to direct changes in membrane potential
- ONLY the axons on all types of neurons
leak channels
always open
found in nearly all cells, including dendrites, cell bodies and and axons of all types of neurons
2 types of electrical signals in neurons
GRADED POTENTIALS
- short distances only
- ligand gated and mechanically gated
- occur in cell body
ACTION POTENTIALS
- short and long distances
- voltage gated
out of electrical and chemical gradients, which will ions move with first?
chemical concentration gradient
how can different ions cause hyper or depolarization?
Na+ in = depolarization
Ca2+in = depolarization
Cl- in = hyperpolarization
K+ out = hyperpolarization
amplitude of a graded potential depends on the…
stimulus strength
characteristics of graded potential strength
Amplitude of GP depends on stimulus strength
GPs can be added together to become larger in amplitude
How is an action potential started?
enough graded potentials in cell body cause a strong electrical gradient that reaches TRIGGER ZONE, triggering voltage gated channels and an action potential
describe the “all or none” principle
only if a large enough depolarizing graded potential occurs will an action potential be possible
Describe process of an action potential
- Resting state (-70mV)
- Threshold
- enough GP cause Na+ activation gates to open - Depolarizing phase
- Na+ cells IN (+35mV)
- Na+ in fast because it’s following electric and concentration gradient
- K+ gates open more slowly - Repolarization phase
- +35mV cause Na+ inactivation gates close
- more K+ moves out of cell (via voltage channels AND sodium potassium pump) - End of repolarizing phase
- @ threshold, activation gates close, inactivation gates open
- K+ outflow returns membrane to -70mV - Afterpotential
- if enough K+ leaves, causes hyperpolarization - Return to resting potential
- via leak and sodium potassium pump
- voltage gated channels shut, repolarization occurs
- signal spreads over surface of axon without dying out
what kind of GP do you need to trigger an action potential?
many DEPOLARIZING GPs
Explain gate activity during resting membrane potential
- leak channels and sodium potassium pump maintain voltage
- K+ voltage gates closed
- Na+ activation gate closed, inactivation open
