Cardiac Cycle & LV Mechanics / Circulatory Hemodynamics

Question 1

When does systole begin and end, and how much of the cardiac cycle does this comprise?

Answer 1

1/3, begins when ventricles start to contract (isovolumetric contraction) and ends when the ejection stops (just BEFORE isovolumetric relaxation)

Question 2

Is atrial systole a part of systole or diastole?

Answer 2

Diastole - occurs just before ventricular systole and is considered the last part of diastole.

Question 3

When does isovolumetric relaxation begin and end? What does it correspond to on ECG? What is this volume?

Answer 3

Since it is the first part of diastole, it must begin with the end of ejection

Begins: Semilunar valves close
Ends: When ventricular pressure falls below atrial pressure, allowing AV valves to open

Corresponds to end of T wave on ECG -> ventricular repolarization

Volume = End systolic volume (ESV)

Question 4

At normal heart rates, how much of ventricular filling is passive / active? When does this become more important?

Answer 4

75% is passive, 25% is active

In high exercise states, diastole shortens so there is less passive filling time -> atrial contraction becomes more important

Question 5

What does atrial contraction coincide with on ECG?

Answer 5

Just after the P wave

Question 6

What does isovolumetric contraction coincide with on ECG? What is this volume?

Answer 6

Peak of the R wave (in QRS complex)

Volume = End diastolic volume

Question 7

When do the atria fill with blood?

Answer 7

All the time, even during ventricular systole, EXCEPT for atrial systole (part of diastole).

Question 8

What are normal RA, RV, and PA pressures?

Answer 8

RA = 0-5mmHg
RV = 25/5 mmHg (diastole corresponds to RAP)
PA = 25/10 mmHg (diastole corresponds to LAP)

Question 9

What are normal LA, LV, and Aortic pressures?

Answer 9

LA = 8-10 mmHg
LV = 120/10 mmHg (Diastole corresponds to LAP)
Aortic = 120/80 mmHg

Question 10

Why is preload a thing in cardiac muscle but not skeletal muscle?

Answer 10

Cardiac muscle has more connective tissue which makes it more resistant to stretch -> stretching it like a rubber band will store up some potential energy.

-> contraction will begin when the sarcomere is near its full length

Question 11

What is a good measurement approximator for preload? What two systemic factors will increase it?

Answer 11

ventricular EDV -> lets us know the end-diastolic length of the sarcomeres

Increased by: 1. Increased venous tone (more blood back to heart) 2. Increased blood volume

Question 12

How is afterload defined, and what happens if afterload > contraction force?

Answer 12

Force that the muscle cell must overcome to begin to shorten

-> if afterload > contraction force, isometric contraction will occur (no shortening possible)

Question 13

What changes the inotropy of cardiac muscle?

Answer 13

This is contractility - independent of preload and afterload

-> tends to be changed by biochemical environment of muscle bundle

Question 14

Your graph is stroke volume vs LV EDP. What will happen to the curve if something increases inotropy?

Answer 14

Slope will increase / shift to the left -> greater stroke volume at any given LV EDP.

Question 15

How is ejection fraction calculated?

Answer 15

SV / EDV

Where stroke volume = EDV - ESV

So

(EDV - ESV) / EDV

Question 16

What accounts for the majority of the increased cardiac output during exercise?

Answer 16

The heart rate

-> stroke volume plateaus very early

Question 17

Other than blood volume and venous tone, give a few other factors which can influence venous return to the heart and hence preload?

Answer 17

1. Posture -> i.e. lying down with legs up
2. Pericardial constraint -> i.e. pericardial thickening or effusion will limit distensibility of heart
3. Atrial contraction presence / efficiency

Question 18

Other than venous return, what other factor influences preload?

Answer 18

Ventricular compliance

-> hypertrophy will lower it

Question 19

How does ventricular compliance change with ventricular volume?

Answer 19

At higher volumes, a higher pressure will be needed to get an increase in volume.

• > due to its compliance characteristics
• > becomes more stiff / less compliant

Stiffness = pressure / volume, compliance = volume / pressure

Question 20

How can relaxation help myocardial compliance?

Answer 20

Reuptake of calcium into the SR rapidly will break actin-myosin crossbridges via an ATP-dependent process

• > explains why phospholamban phosphorylation of Ca+2-ATPase on SR, and phosphorylation of TnI increasing relaxation is a good thing
• > improvement of compliance will improve preload

Question 21

What happens when atrial filling pressures increase greater than physiologically needed for optimal preload?

Answer 21

There comes a point when increased venous return is not needed

• > volume overload
• > will lead to pulmonary congestion and ultimately left-sided heart failure due to so much preload with every pump

Question 22

What is the formula for wall stress? What increases / decreases it?

Answer 22

Wall stress = (Pressure x Radius) / 2(wall thickness)
-> force with cardiomyocytes must push against

Increased by greater radius from center to wall of ventricle, and systolic pressure (afterload)

Stress is normalized via increasing wall thickness

Question 23

Why is afterload approximated by mean arterial pressure?

Answer 23

Afterload is actually wall stress -> Force per unit area the heart must push against

However, we assume that ventricular radius and wall thickness are pretty much constant, so pressure (in the numerator of wall stress equation) is a pretty good proxy.

Pressure = Force per area
Radius = length (i.e. cm)
Wall thickness = length (i.e. cm)

(F/A * cm) / cm = F/A, Laplace’s law

Question 24

How does wall stress change during ejection?

Answer 24

It decreases because

1. The size of the LV cavity decreases -> Radius decreases
2. LV wall thickness increases -> more sarcomeres pushed together

Question 25

What does dilated cardiomyopathy do to wall stress?

Answer 25

Increases it by increasing the radius in Laplace’s law

Question 26

How does heart rate increase contractility?

Answer 26

Decreases the ability of Ca+2 to leave the cytoplasm -> more calcium for next contraction.

Question 27

How does the B1 adrenoceptor increase contractility?

Answer 27

Phosphorylates the Ca+2 channels, increasing Ca+2 entry and thus Ca+2-induced Ca+2 release.

Also, phosphorylates phospholamban to reuptake Ca+2 into SR faster for quicker relaxation, and phosphorylates TnI for faster recovery.

Question 28

What effect will increased preload have on the LV pressure volume loops (LV pressure vs LV volume)?

Answer 28

Increases the EDV and thus stroke volume since you will still return to the same ESV.

Question 29

What effect will increased afterload have on the LV pressure volume loops (LV pressure vs LV volume)?

Answer 29

Increases the ESV and thus decreases stroke volume since you will have the same EDV.

ESV will move up the same slope of the ESPVR curve (same contractility).

Question 30

What effect will increased contractility have on the LV pressure volume loops (LV pressure vs LV volume)?

Answer 30

Shifts the ESPVR curve to the left, increasing its slope. This will decrease the ESV while keeping EDV the same.
-> increased stroke volume.

Question 31

What is normal ejection fraction?

Answer 31

55-60%

Question 32

What will increasing preload, afterload, and contractility do to ejection fraction?

Answer 32

Preload - increase EF (to a point, until fibers are overstretched and excess blood will be held in ventricle)
Afterload - decrease EF
Contractility - increase EF (lower ESV / greater SV)

Question 33

What does concentric hypertrophy happen in response to, and what is its pathogenesis?

Answer 33

In response to increased afterload
-> Lay down more sarcomeres in parallel, decreasing LV cavity size and increasing wall thickness, which decreases wall stress.

Question 34

Give a few conditions causing concentric hypertrophy?

Answer 34

Uncontrolled HTN
Aortic valve stenosis
Pulmonic valve stenosis (thickening of RV)

Question 35

What does eccentric hypertrophy happen in response to, and what is its pathogenesis?

Answer 35

In response to chronically increased preload

• > Lay down more sarcomeres in series to accommodate increased volume
• > Increased volume increases wall stress (radius is larger)
• > Lay down sarcomeres in parallel to increase wall thickness and decrease cavity size

Question 36

Give a few conditions causing eccentric hypertrophy?

Answer 36

Aortic, mitral, pulmonic, and tricuspid regurgitation states.
-> will dilate one chamber of the heart each time.

Question 37

Why is LV hypertrophy bad?

Answer 37

1. Volume of myocytes increases disproportionately to capillary growth -> decreased coronary reserve in situations of high demand (i.e. tachycardia)
2. Sarcomeres increase more than mitochondria -> inefficient energy use
3. Decreased contraction efficiency in myosin ATPase
4. Increased collagen deposition -> increased LV stiffness

Question 38

What is concentric remodeling?

Answer 38

Reversible and physiologic hypertrophy which happens in athletes

Question 39

What is “remodeling”?

Answer 39

LV dilatation related to primary myocyte structural or functional loss, as in MI or non-ischemic cardiomyopathy

Question 40

How does the thermodilution method of testing cardiac output work?

Answer 40

Put a pulmonary artery catheter in via the femoral vein. Cold saline is injected via proximal right atrial catheter and temperature is measured via distal thermometer in pulmonary artery

Drop in temperature correlates with velocity of blood / stroke volume

Question 41

What is the Fick equation and how is it used to measure cardiac output?

Answer 41

Cardiac output = VO2 (measured via inspiration / expiration, in mL/min) / AV oxygen difference (mL O2 / liter of blood)

Measure the patients arterial and venous O2 concentrations for the AV oxygen difference.

Question 42

How is vascular resistance (afterload) measured? Units?

Answer 42

Mean pressure difference across a vascular bed / mean blood flow

Mean blood flow is measured in volume / time (cm^3/sec)

Thus, units are (Dynes/cm^2) / (cm^3 / sec) = dynesseccm^-5

Question 43

What is the conversion between dynesseccm^-5 and Woods Units?

Answer 43

1 Wood Unit = 80 dynesseccm^-5

So 10 Woods Units = 800 dynesseccm^-5

Question 44

What does pulmonary capillary wedge pressure (PCWP) approximate?

Answer 44

Left atrial pressure (diastolic pressure from a balloon catheter inserted into the pulmonary artery) -> LVEDP -> preload

Question 45

How is the systemic vascular resistance calculated and what is the normal range?

Answer 45

SVR = (MAP - Mean RAP) / CO

RAP = right atrial pressure

Normal = 900-1300 dynesseccm^-5

Question 46

How is the pulmonary vascular resistance calculated and what is the normal range?

Answer 46

PVR = (Mean PAP - Mean LAP) / CO

LAP = Left atrial pressure = PCWP

Normal = 40 to 90 dynesseccm^-5

Question 47

What things increase SVR or PVR?

Answer 47

SVR -> systemic vasoconstriction

PVR -> pulmonary vasoconstriction from hypoxia or by clotting or scarring

Question 48

What things decrease SVR or PVR?

Answer 48

SVR -> systemic vasodilation, i.e. sepsis, anemia

PVR -> pulmonary vasodilation

Question 49

How do you calculate Mean Arterial Pressure with Cardiac output and total peripheral resistance?

Answer 49

MAP = CO * TPR

V = I*R

Question 50

How do you calculate MAP and pulse pressure with systolic / diastolic pressure?

Answer 50

MAP = 2/3 diastolic + 1/3 systolic, or diastolic + 1/3 pulse pressure

Pulse pressure = Systolic - diastolic