excitable cells

Question 1

what is an electrical event

Answer 1

a mechanism of cell-to-cell communication/sensing environmental changes/triggering intracellular events

Question 2

extracellular fluid properties

Answer 2

similar to PLASMA in ionic composition (mostly proteins and ions) and has a high [NaCl]

Question 3

predominant cation in the ecf

Answer 3

Na+

Question 4

intracellular fluid properties

Answer 4

very HIGH [PROTEIN] (which give it a net negative charge), predominant salt is KCl

Question 5

predominant cation of the icf

Answer 5

K+

Question 6

membrane properties

Answer 6

lipid bilayer and proteins. equal amounts of protein and lipid and small amount of carbohydrates

Question 7

define permeability

Answer 7

ability of the ion to cross the membrane

Question 8

changes in permeability are (2)

Answer 8

1. ion-specific

2. timed

Question 9

simple diffusion

Answer 9

random diffusion down an electrical or concentration gradient (organic molecules or ions)

Question 10

non-polar organic molecules undergo simple diffusion

Answer 10

rapidly through the membrane. no energy required. Ex. O2, CO2, fatty acids, steroid hormones

Question 11

ions undergo simple diffusion

Answer 11

through channels that are ion-specific

Question 12

define flux

Answer 12

amount of substance crossing a surface per unit of time

Question 13

movement of ions/molecules b/w compartments is always

Answer 13

bidirectional

Question 14

define net flux

Answer 14

difference b/w the two unidirectional fluxes. when = to 0, the system is at “diffusion equilibrium”

Question 15

2 types of mediated transport

Answer 15

1. facilitated diffusion

2. active transport

Question 16

facilitated diffusion

Answer 16

no energy required. membrane protein acts as a carrier to move molecule across membrane. large/polar molecules (ex. glucose)

Question 17

active transport

Answer 17

requires energy. molecule being transported must bind to a transporter and move up its concentration/electrical gradient

Question 18

in active transport, energy can affect:

Answer 18

1. the affinity of the transporter for the ligand on one side of the membrane
2. the rate of transporter conformational change

Question 19

primary active transport

Answer 19

energy source is hydrolysis of ATP, then the transporter gets phosphorylated, then the transporter changes its affinity for the molecule, and this increases the transport rate

Question 20

secondary active transport

Answer 20

energy source is in ion concentration gradient across membrane (down its gradient) . the transporter has 2 binding sites.

Question 21

what are the 3 factors that determine the rate of flux

Answer 21

1. number of transporters in membrane
2. extent of transporter saturation
3. rate of transporter conformational change

Question 22

how is transporter saturation affected

Answer 22

1. transporter affinity for the ligand

2. ligand concentration

Question 23

types of channels

Answer 23

1. ligand-sensitive
2. voltage-sensitive
3. mechano-sensitive

Question 24

osmosis

Answer 24

bulk flow of water across a membrane. water (polar) diffuses through channels down its concentration gradient.

Question 25

osmolarity

Answer 25

total solute concentration in a solution (1 mole of NaCl=2.0 osmoles)

Question 26

isotonic

Answer 26

no change in cell volume

Question 27

hypotonic

Answer 27

cells swell

Question 28

hypertonic

Answer 28

cells shrink

Question 29

endocytosis

Answer 29

engulfment of fluid and particles from the ecm. includes pinocytosis (small particles w/ or w/o small vol of ecf) and phagocytosis (large particles/debris)

Question 30

pinocytosis is performed by what cell type

Answer 30

all cell types

Question 31

phagocytosis is performed by what cell type

Answer 31

phagocytes

Question 32

exocytosis

Answer 32

export of material from a cell…secretion

Question 33

voltage

Answer 33

charge difference b/w the inside and outside of a cell. steady in a resting cell.

Question 34

resistance

Answer 34

plasma membrane must control the voltage and therefore must resist the ion movement

Question 35

current

Answer 35

when R changes, ion movement occurs and this movement is current

Question 36

conductance

Answer 36

reciprocal of resistance….g=1/r

Question 37

conductance and resistance are both

Answer 37

membrane properties

Question 38

Ohm’s law

Answer 38

V=IR

Question 39

nernst equation

Answer 39

yields the equilibrium potential of a single ionic species. the equilibrium potential is the voltage across a cell membrane that exactly balances the force in the [ ] gradient of a permeable ion. theoretical membrane potential.

Question 40

transient diffusion potential

Answer 40

asymmetric ion flow

Question 41

steady diffusion potential

Answer 41

the electrical gradient can resist the movement of an ion down its [ ] gradient to reach an equilibrium potential

Question 42

the membrane of a resting cell is most permeable to

Answer 42

K+….when cell is at rest, K+ ions diffuse 60x more than do Na+ ions

Question 43

membrane potential vs. Ek

Answer 43

m.p= -70–90mV….Ek=-100mV. this is bc both Na and K are moving down their [ ] gradients. Na makes the cell more positive and keeps the m.p slightly above (more positive than) Ek

Question 44

the resting membrane potential is

Answer 44

a STEADY diffusion potential (not transient). not due to instantaneous movement of ions but due to ions (K+) that has moved across the membrane…which causes Na to move and balance it

Question 45

the Na/K ATPase pump is responsible for

Answer 45

moving K into the cell and Na out of the cell when it is at rest. hydrolyzes ATP for active transport of ions (up their [ ] grads). maintains [ ] grads for Na and K…replaces the Na and K that have diffused across the membrane at rest (down their [ ] grads)

Question 46

poisoning the pump (slowing it down) causes

Answer 46

a slow decrease in the r.m.p and the m.p moves towards 0 making it more (+) charged.

Question 47

depolarization

Answer 47

toward 0mV….getting more +

Question 48

repolarization

Answer 48

towards resting potential (-70mV)

Question 49

hyperpolarization

Answer 49

increase the m.p…getting more -

Question 50

without the Na/K pump

Answer 50

r.m.p would dissipate to 0mV

Question 51

what is an action potential

Answer 51

large transient change in membrane potential….first occurs in the INITIAL SEGMENT of neuron

Question 52

steps of an a.p

Answer 52

1. increase in P(Na)
2. Na into cell via voltage-regulate channels…gNa increases
3. m.p depolarizes towards 0mV
4. threshhold is reached….more Na channels open (voltage regulated)
5. more Na enters the cell (positive feedback cycle)…RISING PHASE
6. m.p rapidly reaches peak at +40mV
7. K channels (voltage gated) open/ P(K) increases and K flows out of the cell. gK increases.
8. m.p rapidly/abuptly reverses to resting potential….FALLING PHASE. Na channels close here = Na inactivation
9. hyperpolarization

Question 53

hyperpolarization vs rising and falling phases

Answer 53

depolarization and repolarization are usually ~1ms where hyperpolarization can last >10ms

Question 54

latent period

Answer 54

b/w applying the stimulus and depolarization. precedes the foot of the AP. channel gates are opening.

Question 55

why does the peak of the a.p stop at ~40mV

Answer 55

peak of A.P approaches E(Na) which is ~58mV. P(Na) is very high during the rising phase and crosses the membrane until its ionic gradient is at equilibrium with m.p.

Question 56

at the end of repolarization, m.p is close to

Answer 56

E(K)….P(K) is very high during the falling phase of the A.P.

Question 57

a subthreshold stimulus results in

Answer 57

a local response in which a small depolarization/hyperpolarization occurs and is confined to the immediate region of the membrane. a GRADED RESPONSE that is proportional to the stimulus strength.

Question 58

threshold/suprathreshold stimuli result in

Answer 58

A.Ps!…all or none property.

Question 59

absolute refractory period

Answer 59

period when a second stimulus (threshold OR suprathreshold) cannot elicit a second AP

Question 60

relative refractory period

Answer 60

for a longer period after an AP where a suprathreshold can elicit a second AP, but a threshold stimulus CANNOT.

Question 61

refractory periods cause

Answer 61

a limit on the fq at which cells can fire APs.

Question 62

tetrodotoxin

Answer 62

puffer fish toxin that binds to Na channels and blocks Na influx…no AP can occur

Question 63

adaptation

Answer 63

property of NERVE CELLS. need “square wave” stimulus to elicit an A.P. due to the ACCOMMODATION of channels

Question 64

accommodation

Answer 64

property of CHANNELS…gates of channels won’t open unless stimulus is quickly applied

Question 65

strength/intensity vs duration

Answer 65

decreased intensity requires increased duration

Question 66

rheobase

Answer 66

magnitude of the least intense stimulus that can elicit a response

Question 67

utilization time

Answer 67

duration required to elicit a response by a stimulus with a rheobase magnitude

Question 68

chronaxie

Answer 68

duration required to elicit a response by a stimulus with a magnitude that is twice the rheobase magnitude. used to compare the excitability of different cells.

Question 69

electrotonic or local currents

Answer 69

occur at immediate site of stimulation. passive bc they don’t propgate. if sufficient magnitude, lead to an AP

Question 70

schwann cells

Answer 70

produce myelin by wrapping layers of plasma membrane around an axon and creating nodes of ranvier

Question 71

saltatory conduction

Answer 71

APs only generate at the nodes…increases the velocity of AP propogation.

Question 72

breakdown of myelin causes

Answer 72

gross motor abnormalities

Question 73

axons with larger diameter have

Answer 73

higher velocities of conduction

Question 74

compound action potentials

Answer 74

peripheral nerves have many neurons. the further the recording electrodes are from the stimulating electorde, the more the individual APs are separated from each other.