Excitable Cell Membranes and Action Potential Flashcards
Lipid Bilayer
• Intracellular space o cytosol • Extracellular space o Outside of cell • At body temperature, interior of bilayer is fluid
Transmembrane/Integral Proteins
o Span membrane
o Signal, channel proteins
Peripheral Membrane Proteins
o On either side of membrane, doesn’t go through
o Usually enzymes
o Facilitate functions of transmembrane proteins
Charges Near the Cell Membrane:
Na, K, Cl, negatively charged proteins
o Na and Cl more concentrated outside cell
o Called physiological saline
o K and Proteins more concentrated inside cell
o Overall more negative inside than outside
o Mainly because of negatively charged proteins
Membrane Potential
o Difference in electrical charge between inside and outside of cell
Permeability of Cell Membrane:
o Impermeable to electrically charged proteins
o Not very permeable to Na
o Relatively permeable to K
o Very permeable to Cl (therefore Cl is in equilibrium)
Hodgkin and Huxley Experiment
o Calculated electrostatic charge needed to keep various ions from equilibrium (at rest, with the exception of Cl)
o Potassium
o 90 mV acting to move K out of neuron
o Sodium
o 120 mV of force pushing Na into neuron
o 70 mV attracted Na into cell, 50 mV pushing Na in, adds to 120
Sodium-Potassium Pump:
o Active Co-transport mechanism
o Used energy (ATP)
o 3 Na ions move out, 2 K ions move in, maintains uneven distribution of Na and K ions
o Phosphate binds to pump, allows Na to bind, Na moves out of cell, K moves in, Phosphate comes off pump
EPSP
o Na channels open, Na enters cell, causes depolarization
o 120 mV of pressure acting on Na to move, when channels open, Na very readily moves into cell
IPSP
o Cl enters cell, causes hyper polarization
Inhibatory Poste Synaptic Potential
Spatial/Temporal Summation
o Each EPSP/IPSP only causes a small change in membrane potential (only measurable in location where it is occurring). Therefore rely on spatial and temporal summation
o Same time, different locations, rapid succession at the same synapse
Graded Response
EPSP/IPSP vary in magnitude
Decremental Conclusion
o Signal getting smaller because ion are dispersing within neuron
o By the time it reaches the axon, it is not large enough to cause action potential
Action Potential
o Fires at around -65 mV, membrane potential changes from -65 to +50 mV
o All or none principle- it either fires or it doesn’t
o Occurs in axon membrane adjacent to axon hillock
o Travels down axon, non-decremental (doesn’t lose strength)
Process of Action Potential
Na channels open (voltage gated)
Na enters, cell depolarizes causing K channels to open (voltage gated)
K ions exit cell
membrane reaches +50 mV
Na channels close
K ions still exit cell due to electrostatic pressure, membrane starts depolarizing
K channels close gradually, hyperpolarization, refractory period
