Membrane Potentials and Action Potentials Flashcards
Lipid Membranes
-doesn’t allow Ions to Pass through Unless via Specialized Transport Mechanisms
o Protein Molecules and Membrane Structure – trans membrane domains
o Hydrophilic pores made by proteins through the membrane
o No transmembrane protein = no ion flux
Active vs. Passive Transport
- Active Transport Mechanisms – consume energy to move ions against concentration gradient
- Passive Transport Mechanisms – channel mediated diffusion based on concentration gradients; no energy required
Measuring Ionic Flux
– flux and direction determined by 2 driving forces (voltage and concentration gradient)
Ionic Channels
– passive, facilitated diffusion mechanism
o Selectivity to K+ or Na+
o Gating – either voltage or ligand
o Resting potential uses K+ and Na+ leak channels
o Action potential uses K+ and Na+ voltage-gated channels
Ionic Flux Generating Membrane Potential
o K+ ions pushing out by diffusion (chemical driving force)
o Electrical potential builds up due to K+ moving out
At Rest: Electrical-chemical Equilibrium
o All nerve cells are negatively charged
o Balance between chemical (concentration) force and electrical (membrane potential) force
o Resting Potential = -60mV
o At equilibrium there is NO NET FLUX
o Nernst Equation – at equilibrium (no net flux) the potential is determined by
E = 59 log [K]o/[K]in
Resting Membrane Potential
– dynamic balance between K+ leak outward and Na+ leakage inward
o K+ In = 155; K+ Out = 4
o Na+ In = 12; Na+ Out = 145
o Resting Potential VARIES = -60mV when awake; -70mV when sleeping
o High Na+ outside; High K+ inside
o Depolarized = inside becomes more positive
o Hyperpolarized = inside becomes more negative
Threshold
stimulus opens up some voltage gated Na+ channels; if the influx of Na+ reaches threshold then more channels are opened triggering an action potential
Action Potential - Depolarization
o Action potential triggers Na+ channels to open, K+ channels remain closed
o Initial Positive Feedback
Inward Na+ Current Membrane Depolarization opening of voltage-gated Na+ channels MORE inward Na+ current
Action Potential - Repolarization
o Inactivation (closure) of voltage gated Na+ channels; K+ channels open to repolarize the membrane potential back to resting membrane potential
Refractory Periods
o Absolute – all Na+ channels inactive
Makes sure there is one-way propagation of action potentials
Second response NOT possible
o Relative – some Na+ channels recovered
Helps limit the frequency of action potentials
Second response can be elicited but at a greater cost (strength or duration)
Axonal Action Potential Factors
– all or nothing; unidirectional o Conduction velocity – speed of propagation Units: meters/sec Differs for different axons o Membrane capacitance and myelination o Activation kinetics of the Na+ channel
Conduction Velocity Depends on:
o Internal diameter of axon and internal resistance
o Membrane capacitance
o Amount of myelination
o Activation kinetics of Na+
Space Constant
• Space Constant (λ) = √(Rm / Ri)
o Ri = 1 / diameter
o Larger diameter = lower Ri (internal resistance) = higher conduction velocity
Capacitance
– slows down the generation of action potential
o Property of biological membranes ability to store charge
o Larger the capacitance the larger the time constant
