Cardio Physiology

Question 1

What is nernst potential equation?

Answer 1

Ex = RT/zF * ln [Xo]/[Xi]

Question 2

What is resting membrane voltage?

Answer 2

• 85 mV

- membranes are permeable to K+ but not Na or Ca

Question 3

What is K equilibrium potential [Ek]?

Answer 3

-89 mV

Question 4

What is Na equilibrium potential [Ena]?

Answer 4

+70 mV

Question 5

What is Ca equilibrium potential [Eca]?

Answer 5

+ 133 mV

Question 6

Which ion sets the resting voltage?

Answer 6

K+

Question 7

What is phase 0 of ventricular AP? What channels open/closed?

Answer 7

rapid upstroke and depolarization

due to voltage gated Na channels opening [ Na in]

Question 8

What is phase 1 of ventricular AP? What channels open/closed?

Answer 8

initial repolarization

• inactivation of voltage gated Na channels
• voltage gated K channels begin to open [K out]

Question 9

What is phase 2 of ventricular AP? What channels open/closed?

Answer 9

plateau phase = voltage decreasing at very slow rate

• Ca in through voltage gated Ca channels [depolarizing]
• balanced by K out [repolarizing]

Ca in triggers Ca release from SR and myocyte contraction

Question 10

What is phase 3 of ventricular AP? What channels open/closed?

Answer 10

rapid repolarization

lots of K out due to opening voltage-gated slow K channels

• slow voltage gated K open [K out]
• voltage gated Ca close

Question 11

What is phase 4 of ventricular AP? What channels open/closed?

Answer 11

resting potential

high K permeability through K channels

Question 12

What is path of action potential propagation in a heartbeat?

Answer 12

• SA node generates AP
• propagated to atrial muscle
• activates AV node between atria and ventricles
• goes down bundles of his to left and right bundle branches
• reaches purkinje fibers of L and R ventricles which excite subendocardium then epicardial surface

Question 13

How many contractions per AP in cardiac cell? why?

Answer 13

one contraction per AP

because of refractory period after AP –> need time to recover until 2nd AP

Question 14

What is the absolute refractory period?

Answer 14

time that must elapse before 2nd stimulus can cause an AP

–> impossible to trigger second AP during this time

Question 15

What is the relative refractory period?

Answer 15

period of time when very large stimulus can produce weak action potential [AP]

stronger signal than normal is required to produce a normal AP

Question 16

What is phase 0 for SA node?

Answer 16

upstroke

• opening Ca voltage-gated channels

Question 17

What is phase 2 for SA node?

Answer 17

no phase 2 in SA node

Question 18

What is phase 3 for SA node?

Answer 18

inactivation of Ca channels and activation of K channels

–> lots of K efflux to repolarize

Question 19

What is phase 4 for SA node?

Answer 19

slow diastolic depolarization

membrane potentially spontaneously depolarizes as Na conductance increases [If= funny current] , slope of phase 4 determines HR

• If in
• Ca out and Na in [NCX]

Question 20

What is difference phase 0 ventricular vs SA node cells?

Answer 20

ventricle: Na open/in

SA: Ca channels open/in, no fast voltage-gate Na b/c less negative resting voltage of these cells

phase 0 for ventricular myocyte = much faster [300 V/s]

SA = 20 V/s

Question 21

What is funny current [If]?

Answer 21

current that depolarizes in phase 4 of SA node contraction

mixed Na/K inward current

not present in ventricle

Question 22

What is inward rectifier current?

Answer 22

Ik = in ventricle but not SA node

responsible for flat phase 4

Question 23

How does phase 3 differ ventricle vs SA?

Answer 23

comparable

both have delayed rectifier K channels responsible for repolarization

Question 24

What is baseline voltage for SA node cells?

Answer 24

-60 mV

[compared to ventricle -85 mV]

Question 25

What is NCX current?

Answer 25

Na Ca exchanger current

• 3 Na in for 1 Ca out
• net Ca out and Na in

Question 26

What is single electrode whole cell voltage clamping?

Answer 26

• voltage clamp controls cellular voltage and measure of corresponding ionic current
• record changes in ionic current in response to series of depolarizations
• plot peak current vs voltage to understand underlying characteristics

Question 27

What is convention inward vs outward currents?

Answer 27

inward = negative
outward = positive

Question 28

What direction does current travel when voltage across membrane is greater than the nernst potential for an ion?

Answer 28

pos current

• ion will move out of cell [assuming + charge ion]

Question 29

What direction does current travel when voltage across membrane is less than the nernst potential for an ion?

Answer 29

neg current

• ion will move into cell [assuming + charge ion]

Question 30

What direction will Na/Ca/K go if voltage = 80?

Answer 30

• K out
• Na out
• Ca in

Question 31

What is mech of activation and speed of activation of Ik/Ach vs If [funny]?

Answer 31

Ik,Ach = activated by gprotein By subunits

If = activated by increased CAMP
- requires intermediate enzyme AC thus much slower

Question 32

Is parasympathetic or sympathetic effect on HR faster?

Answer 32

parasympathetic = by activation Ik by G protein By subunit

Question 33

When do voltage gated Na channels [Ina] open? Close?

Answer 33

• open at greater than -60 mV
• close milliseconds later

thus not open at -85 mV resting potential

Question 34

When do L-type Ca channels [Ica] open? close?

Answer 34

• open at more positive membrane potential than Na

- activates and inactivates 10x slower than Na

Question 35

What mediates parasympathetic stimulation of heart cells?

Answer 35

via muscarinic ACh receptors

Question 36

What is effect of parasympathetic stimulation in SA? AV? ventricular?

Answer 36

SA: slower firing by activation of Ik, Ach by G protein By subunits

AV: slower electrical conduction through AV by reduced Ica due to decreased PKA activity

ventricle: no effects

Question 37

What is the inward rectifying K channel [Ik1]? when is it open/closed?

Answer 37

• open at resting potential
• closes at positive potentials and closed completely at 0 mV

keeps ventricle membrane potential constant at -85 mV

not present in SA node

Question 38

What are the delayed rectifying K channels [Ikr and Iks]? when are they open/closed?

Answer 38

• closed at resting potential
• open in plateau [phase 2] positive potential

Ikr = rapid delayed rectifier = can be blocked by meds
Iks = slow delayed rectifier

Question 39

What is effect of sympathetic stimulation of heart cells on SA? AV? ventricles?

Answer 39

SA: faster firing by activation If by increase CAMP

AV: faster electrical conduction through AV by increased Ica due to increase PKA activity

ventricle: stronger contraction, faster relaxation
- increased Ica due to increased PKA
- phosphorylation phospholamban, increased SERCA

Question 40

What receptors mediate sympathetic stimulation of heart cells?

Answer 40

B-adrenergic receptors

Question 41

What is difference AP vs ECG voltage?

Answer 41

AP = Vin - Voutside of cell

ECG = V2 - V1 = voltages outside of cells at 2 different locations = AP1 - AP2 = subtract APs

Question 42

What is funny current? another name for the channel?

Answer 42

If = HCN = hyperopolarization-activated cyclic nucleotide gated channel

present in SA and AV node but not ventricle
- closed at more positive potentials, opens when membrane potential less than -50

mixture of Na and K [mostly Na]
depolarizing

Question 43

Is heart under parasympathetic or sympathetic control? blood vessels?

Answer 43

heart = both; except ventricles just sympathetic

blood vessels = just sympathetic

Question 44

What is chronotropy?

Answer 44

HR

Question 45

What does a positive chronotrope do?

Answer 45

increase HR

Question 46

What is inotropy?

Answer 46

contractile strength

Question 47

What does a positive inotrope do?

Answer 47

increases force of contraction

Question 48

What is action of digoxin?

Answer 48

positive inotrope

Question 49

What is dromotropy?

Answer 49

speed at which electrical impulses propogate through heart

Question 50

What is lusitropy?

Answer 50

speed of relaxation of ventricle

Question 51

Upward or downward deflection [wave] in ECG?

• depolarization toward + electrode
• depoarlization away from + electrode
• repolarization toward + electrode
• repolarization away from + electrode

Answer 51

• depolarization toward + electrode
  == pos deflection [wave]
• depoarlization away from + electrode
  == neg deflection [wave]
• repolarization toward + electrode
  == neg deflection [wave]
• repolarization away from + electrode
  == pos deflection [wave]

Question 52

What part of heart is main determinant of dromotropy?

Answer 52

SV node!

Question 53

What is parasympathetic innervation of SA node?

Answer 53

vagus nerve

Question 54

Is resting HR in a heart transplant patient higher or lower than normal?

Answer 54

resting HR in heart transplant 90-100 bpm compared to healthy = 60-80

Question 55

What happens to heart if you give atropine?

Answer 55

atropine = parasympathetic antagonist

–> increase HR

Question 56

What happens to heart if you give B-blocker?

Answer 56

blocks sympathetics –> HR decrease

Question 57

Do you get bigger change in HR if you block parasympathetic or sympathetic?

Answer 57

block PNS = much greater rise in HR compared to blocking SNS = not as much decrease HR

Question 58

What is the cellular basis for T wave?

Answer 58

endocardium activates before and repolarizes after epicardium

if you do Vendo-Vepi you get an upward deflecting t wave

== ventricular repolarization

Question 59

What is the cellular basis for p wave?

Answer 59

atrial depolarization

Question 60

What is the cellular basis of QRS complex?

Answer 60

ventricular depolarization

Question 61

What is equation for aVL from other leads?

Answer 61

aVL = 0.6 * (V1-V3) [L is for left]

Question 62

What is equation for aVR from other leads?

Answer 62

aVR = 0.6 * (-V1-V2) [R is for Right]

Question 63

What is equation for aVF from other leads?

Answer 63

aVF = 0.6*(V2 + V3) [F is for food

Question 64

What angle for aVL?

Answer 64

-30

Question 65

What angle for aVR?

Answer 65

-150

Question 66

What angle for II?

Answer 66

+60

Question 67

What angle for aVF?

Answer 67

+90

Question 68

What angel for III?

Answer 68

+120

Question 69

What is Ohm’s equation for BP control?

Answer 69

MAP = CO * TPR

MAP = mean arterial pressure
CO = cardiac output
TPR = total peripheral resistance

Question 70

What does increase in MAP do to CO?

Answer 70

nothing!

Question 71

What are the 3 phases of baroreceptor reflex?

Answer 71

1. something happen to change MAP
2. reflex response tries to return MAP to level that existed before
3. after changes, new steady state reached

Question 72

What is cellular meaning of PR interval?

Answer 72

propagation through AV node

Question 73

Why don’t you see a signal from atrial repolarization?

Answer 73

atria are much smaller = the muscle mass is too small

Question 74

What does baroreceptor reflex do when there is hemorrhage to return MAP to steady state? Effect on myocardium + vessels?

Answer 74

on myocardium:

• increase HR –> increase CO
• increase contractility –> increase CO

on vessels:

• arteriolar smooth muscle contraction –> increase TPR
• venous smooth muscle contraction –> increase preload –> increase CO

Question 75

What is renin-angiotensin-aldosterone system [RAAS] action to regulate BP?

Answer 75

• detect decreased pressure in kidneys –> release renin from juxtaglomerular cells
• increase renin –> increase angiotensin I –> ACE [angiotensin converting enzyme] –> angiotensin II
• angiotensin II
• -> increase aldosterone –> increase Na reabsorption in kidney –> increase blood volume
• -> vasoconstriction –> increase TPR

Question 76

What are the 4 phases of cardiac PV Loop?

Answer 76

1. isovolumic contraction
2. ejection
3. isovolumic relaxation
4. diastolic filling

Question 77

What is preload?

Answer 77

amount of pressure/stretch in heart muscle before contraction

Question 78

What is afterload?

Answer 78

pressure that exists in the aorta/vasculature against which

Question 79

When does MV close on PV loop?

Answer 79

bottom right = after diastolic filling at start of isovolumic contraction

Question 80

When does AoV open in PV loop?

Answer 80

top right = after isovolumic contraction at start of ejection

Question 81

When does AoV close in PV loop?

Answer 81

top left = after ejection at start of isovolumic relaxation

Question 82

When does MV open in PV loop?

Answer 82

bottom left = after isovolumic relaxation at start of filling

Question 83

What is EDPVR?

Answer 83

• end diastolic pressure-volume relationship

- bottom right of PV loop [MV closure] occurs along it

Question 84

What is ESPVR?

Answer 84

• end systolic pressure-volume relationship

- top left of PV loop [AoV closure] occurs along it

Question 85

What happens to PV loop if increase preload with constant afterload and contractility?

Answer 85

shift up along both ESPVR and EDPVR curves

–> increase stroke volume and arterial BP

Question 86

What are 2 ways to increase preload?

Answer 86

• increase blood volume

- venoconstriction –> decrease venous compliance

Question 87

What is starling curve?

Answer 87

relationship preload and stroke volume

increase preload [LVEDP] –> increase stroke volume

Question 88

What are some things that cause increased preload?

Answer 88

• fluid retention [as in advanced heart failure]

- constriction of veins

Question 89

What are some things that cause decreased preload?

Answer 89

• blood loss

- dilation of veins

Question 90

What happens to PV volume if increased TPR with constant preload and contractility?

Answer 90

• stays in same place along EDPVR
• moves up on ESPVR [end systolic volume increases]
• SV decreases [width of loop]

Question 91

How do you get increased TPR?

Answer 91

arteriolar constriction

Question 92

What does TPR represent?

Answer 92

afterload

Question 93

How do you calculate SV from PV loop?

Answer 93

SV = width of loop

= EDV - ESV

Question 94

What are some things that cause increase afterload?

Answer 94

• temporary constriction of arterioles
• chronic hypertension
• aortic stenosis [valve narrowing or block]

Question 95

What are some things that cause decrease afterload?

Answer 95

dilation of arterioles

Question 96

What happens to PV loop if increase contractility with constant preload and afterload?

Answer 96

• increase stroke volume
• increase ejection fraction
• decrease end systolic volume
• shits ESPVR line to the left

Question 97

What are some ways you can increase contractility?

Answer 97

• B adrenergic stimulation ventricles
• increase plasma Ca
• increase muscle mass [ physiological hypertrophy]

Question 98

What are some ways you can decrease contractility?

Answer 98

• B adrenergic blockade
• Ca channel blocker
• decrease energy supply [ischemia or hypoxia]
• decrease muscle mass [MI]

Question 99

How does venous return change with venous/atrial pressure?

Answer 99

as venous return/flow increases, atrial/venous pressure decreases

Question 100

In steady state was is relationship CO and venous return?

Answer 100

in steady state CO = venous return

Question 101

What does increased blood volume do to venous return curve?

Answer 101

line shifts up

Question 102

What does decrease TPR do to venous return curve?

Answer 102

y intercept increases = steeper slope

Question 103

What does venoconstriction do to venous return curve?

Answer 103

x intercept [mean systemic pressure] increases = shallower slope