Cardiac Pathophysiology

Question 1

Where is the heart located?

Answer 1

In the mediastinum between second rib and fifth intercostal space

Question 2

Superficial fibrous pericardium
function?
3

Answer 2

1. Protects,
2. anchors, and
3. prevents overfilling

Question 3

Layers of the heart wall

3

Answer 3

1. Epicardium—
2. Myocardium
3. Endocardium

Question 4

What is the epicardium?

What is the myocardium made of? 2

Endocardium is continuous with what?

Answer 4

-visceral layer of the serous pericardium

• Spiral bundles of cardiac muscle cells
• Fibrous skeleton of the heart: crisscrossing, interlacing layer of connective tissue

-continuous with endothelial lining of blood vessels

Question 5

Function of the myocardium? 3

Answer 5

1. Anchors cardiac muscle fibers
2. Supports great vessels and valves
3. Limits spread of action potentials to specific paths

Question 6

When is pericarditis most likely caused by?

4

Answer 6

1. Post viral
2. Autoimmune/lupus
3. Cancer
4. Idiopathic

Question 7

Tampanade does happen (friction rub) what will they describe it as?

What makes it better? 2

Answer 7

stabbing, shooting, pain of 7 to 10

Leaning forward
Shallow breathing

Question 8

What encircles the junction of the atria and ventricles?

What is the function of the auricles?

Answer 8

Coronary sulcus (atrioventricular groove)

Auricles increase atrial volume

Question 9

What marks the interventricular septum externally? 2

Answer 9

Anterior and posterior interventricular sulci mark

Question 10

What lines the wall of the atria?

What vessels enter the right atrium? 3

What vessels enter the let atrium? 2

Answer 10

Walls are ridged by pectinate muscles

Vessels entering right atrium

1. Superior vena cava
2. Inferior vena cava
3. Coronary sinus

Vessels entering left atrium
1. Right and 2. left pulmonary veins

Question 11

Ventricles: The Discharging Chambers

1. What lines the walls of the ventricles?
2. What kind of muscles project into the ventricular cavities?
3. What vessel leaves the right ventricle?
4. What vessel leaves the left ventricle?

Answer 11

1. Walls are ridged by trabeculae carneae
2. Papillary muscles project into the ventricular cavities
3. Vessel leaving the right ventricle
   Pulmonary trunk
4. Vessel leaving the left ventricle
   Aorta

Question 12

Pathway of Blood Through the Heart

The heart is two side-by-side pumps

1. Right side is the pump for the what?
2. Left side is the pump for the what?

Answer 12

1. Right side is the pump for the pulmonary circuit
   Vessels that carry blood to and from the lungs
2. Left side is the pump for the systemic circuit
   Vessels that carry the blood to and from all body tissues

Question 13

Describe the pathway of blood through the heart?

Including chambers, great vessels and valves

Answer 13

Right atrium → tricuspid valve → right ventricle
Right ventricle → pulmonary semilunar valve → pulmonary trunk → pulmonary arteries → lungs

Lungs → pulmonary veins → left atrium
Left atrium → bicuspid valve → left ventricle
Left ventricle → aortic semilunar valve → aorta
Aorta → systemic circulation

Question 14

_______ volumes of blood are pumped to the pulmonary and systemic circuits
Pulmonary circuit is a ____, _____-pressure circulation
Systemic circuit blood encounters _____ resistance in the long pathways

Anatomy of the ventricles reflects these differences

Answer 14

Equal

short, low

much

Question 15

What is Coronary Circulation?

______ _______ varies considerably and contains many anastomoses (junctions) among branches

______ routes provide additional routes for blood delivery

Answer 15

The functional blood supply to the heart muscle itself

Arterial supply

Collateral

Question 16

What are the arteries in our coronary circulation? 5

What are the veins in our coronary circulation? 3

Answer 16

Arteries

1. Right and
2. left coronary (in atrioventricular groove),
3. marginal,
4. circumflex, and
5. LAD

Veins

1. Small cardiac,
2. anterior cardiac, and
3. great cardiac veins (join together to make the cardiac sinus and dumps into the right atrium)

Question 17

The right coronary artery supplies blood to the ?
4

The left coronary artery supplies blood to the ? 2

Answer 17

1. right ventricle, the
2. right atrium, and
3. the SA (sinoatrial) and
4. AV (atrioventricular) nodes,
5. left ventricle and
6. left atrium

Question 18

When does does cornary circlaiton deliver blood to the heart?

Answer 18

relaxation/diastole

Question 19

DURING WHAT PERIOD OF THE CARDIAC CYCLE DO THE CORONARY ARTERIES RECEIVE PERFUSION?

Answer 19

diastole

Question 20

What is angina pectoris?

What does this cause?

Answer 20

–Thoracic pain caused by a fleeting deficiency in blood delivery to the myocardium

–Cells are weakened

Question 21

Describe Myocardial infarction (heart attack)?

2

Answer 21

• -Prolonged coronary blockage

- -Areas of cell death are repaired with noncontractile scar tissue

Question 22

Infarction is different from ischemia how?

Answer 22

sudden and not going away. Killing heart cells until you do an itervention and perfuse again

ischemia can leave and be relieved on its own

Question 23

1. Which side of the heart acts as the pulmonary pump?
2. Which side of the heart acts as the systemic pump?
3. Which ventricle is larger?
4. Which system is a high pressure system?
5. Name two main branches of the RCA?

Answer 23

1. right
2. left
3. left
4. systemic
5. PDA and marginal

Question 24

What are the different AV heart valves and what is their purpose?

What anchor AV valve cusps to papillary muscles?

When pressure increases and blood fills in what happens to the valves?

Answer 24

Atrioventricular (AV) valves
Prevent backflow into the atria when ventricles contract
Tricuspid valve (right)
Mitral valve (left)

Chordae tendinae

the valves close
Intraventricluar pressure increases and look to shoot out the blood!

Question 25

What are the semilunar valves and what is their function?

Answer 25

Prevent backflow into the ventricles when ventricles relax

Aortic semilunar valve
Pulmonary semilunar valve

Question 26

What causes the opening of the AV valves?

What causes them to close?

Answer 26

AV valves open; atrial pressure greater than ventricular pressure

AV valves closed; atrial pressure less than ventricular pressure

Question 27

Fibrous insulator exists between atrium and ventricle. Why?

Answer 27

provides electrical insulation

Question 28

46

Answer 28

46

Question 29

Describe cardiac muscle?

3

Answer 29

1. Gap junctions (for conduction)
2. Actin and mysoin filaments
3. low resistance intercalated disks

Question 30

1. Depolarization of the heart is ______ and ______?
2. About __% of cardiac cells have automaticity— (are self-excitable)
3. What do gap junctions ensure?
4. Describe the refractory period of the cardiac muscle?

Answer 30

1. rhythmic and spontaneous
2. 1
3. the heart contracts as a unit
4. Long absolute refractory period (250 ms)

Question 31

Similarities of Cardiac and Skeletal Muscle

1. WHich are triggered by action potentials that sweep across cell membranes?

1% of cardiac fibers are autorhythmic

2. The bulk of heart muscle, however, is composed of _______ ______ _____responsible for the heart’s pumping action
3. In these cells, the sequence of events leading to contraction is similar to that in ________ ______ ____?

Answer 31

1. Both
2. contractile muscle fibers
3. skeletal muscle fibers

Cardiac (short and interconnected, one or two nuclei)

Question 32

What happens during systole?

What happens during diastole?

On the EKG what is the:
Pwave?
QRS?
T wave?

Answer 32

Systole – ventricular muscle stimulated by action potential and contracting

Diastole – ventricular muscle reestablishing Na+/K+/Ca++ gradient and is relaxing

EKG -
P-atrial wave
QRS - Ventricular wave T - ventricular repolarization

Question 33

Volume overload to fibrosis what do you hear?

Heart failure what do you hear?

Answer 33

S4

S3

Question 34

What is the intrinsic cardiac conduction system?

Answer 34

A network of noncontractile (autorhythmic) cells that initiate and distribute impulses to coordinate the depolarization and contraction of the heart

Question 35

What are the parts of the cardiac conduction system?

4

Answer 35

1. SA node
2. AV node
3. Bundle of HIS
4. Bundle branch

Question 36

Pathway of the heartbeat:

1. Begins where?
2. Then?
3. Where does the impulse pause?
4. Then?
5. Then?

Answer 36

1. Begins in the sinoatrial (S-A) node
2. Internodal pathway to atrioventricular (A-V) node
3. Impulse delayed in A-V node and bundle
4. A-V bundle takes impulse into ventricles
5. Left and right bundles of Purkinje fibers take impulses to all parts of ventricles

Question 37

Why is the impulse delayed in the AV node?

Answer 37

(allows atria to contract before ventricles)

Question 38

1. What kind of cells have unstable resting potentials (pacemaker potentials or prepotenials)?
2. Why?
3. When the potenial reaches threshold what happens?
4. This causes?
5. What does repolarization result from?

Answer 38

1. Autorhythmic Cells
2. due to open slow Na+ channels
3. At threshold, Ca2+ channels open
4. Explosive Ca2+ influx produces the rising phase of the action potential
5. Repolarization results from inactivation of Ca2+ channels and opening of voltage-gated K+ channels

Question 39

Pacemaker potential:
This slow depolarization is 
due to both opening of \_\_\_
channels and closing of \_\_\_
channels. Notice that the 
membrane potential is 
never a flat line.

Answer 39

Na+

K+

Question 40

Depolarization The 
action potential begins when 
the pacemaker potential 
\_\_\_\_\_\_ \_\_\_\_\_\_\_. 
Depolarization is due to \_\_\_\_
influx through \_\_\_\_ channels.

Answer 40

Reaches threshold

Ca2+
Ca2+

Question 41

Repolarization is due to 
\_\_\_ channels inactivating and 
\_\_\_ channels opening. This 
allows \_\_\_ efflux, which brings 
the membrane potential back 
to its most \_\_\_\_\_\_\_ voltage.

Answer 41

Ca2+
K+

K+
negative

Question 42

1. What is the SA node?
2. What does it act as and why?
3. When membrane potential reaches -40 mV what happens?
4. After 100-150 msec _____ channels close and ___ channels open more thus returning membrane potential to -55mV

Answer 42

1. Specialized cardiac muscle connected to atrial muscle
2. Acts as pacemaker because membrane leaks Na+ and membrane potential is -55 to -60mV
3. When membrane potential reaches -40 mV, slow Ca++ channels open causing action potential

4.
Ca++
K+

Question 43

What actually causes the depolarization/contraction of the heart?

Answer 43

Ca+ channels open

Question 44

Heart Physiology: Sequence of Excitation

First?
Second?
Third?
Fourth?
Fifth?

Answer 44

1. Sinoatrial (SA) node (pacemaker)
2. Atrioventricular (AV) node
3. Atrioventricular (AV) bundle (bundle of His)
4. Right and left bundle branches
5. Purkinje fibers

Question 45

SA node generates impulses at what rate?

________ faster than any other part of the myocardium

SA is mediated by who?

Answer 45

75 times/minute

Depolarizes

Parasympathetic system (otherwise normal would be 100 or over)

Question 46

Describe the structure of the AV node? 2

Delays impulses how much?

Depolarizes how many times per minute without the SA node influence?

Answer 46

1. Smaller diameter fibers;
2. fewer gap junctions (so the impulses move slower)

Delays impulses approximately 0.1 second

Depolarizes 50 times per minute in absence of SA node input

Question 47

What is the only electrical connection between the atria and the ventricles?

Answer 47

Atrioventricular (AV) bundle (bundle of His)

Only electrical connection between the atria and ventricles

Question 48

Whats the purkinje system?

Describe its conduction and why?

Answer 48

Fibers lead from A-V node through A-V bundle into Ventricles

Fast conduction; many gap junctions at intercalated disks

Question 49

What are the Right and left bundle branches?

Answer 49

Two pathways in the interventricular septum that carry the impulses toward the apex of the heart

Question 50

Purkinje fibers complete the conduction pathway into the _____ and __________ _____?

AV bundle and Purkinje fibers depolarize only __ times per minute in absence of AV node input

Answer 50

apex and ventricular walls

30

Question 51

Describe Homeostatic Imbalances?

Answer 51

Defects in the intrinsic conduction system

Question 52

Defects in the intrinsic conduction system may result in what?
3

Answer 52

1. Arrhythmias: irregular heart rhythms
2. Uncoordinated atrial and ventricular contractions
3. Fibrillation: rapid, irregular contractions; useless for pumping blood

Question 53

Defective SA node may result in
what?
2

Answer 53

1. Ectopic focus: abnormal pacemaker takes over

2. If AV node takes over, there will be a junctional rhythm (40–60 bpm)

Question 54

Defective AV node may result in what?

2

Answer 54

1. Partial or total heart block

2. Few or no impulses from SA node reach the ventricles

Question 55

Heartbeat is modified by what system?

Answer 55

autonomic nerve system

Question 56

Where are the cardiac nerve centers located?

Answer 56

medulla oblingata

Question 57

Cardioacceleratory center innervates what? 3

Cardioinhibitory center inhibits what and through what system?

Answer 57

Cardioacceleratory center innervates

1. SA and AV nodes,
2. heart muscle, and
3. coronary arteries through sympathetic neurons

Cardioinhibitory center inhibits
1. SA and AV nodes through parasympathetic fibers in the vagus nerves

Question 58

What nerve decreases heart rate?

What nerve increases heart rate?

Answer 58

1. The vagus nerve
   (parasympathetic)
   decreases heart rate.
2. Sympathetic cardiac
   nerves increase heart rate
   and force of contraction.

Question 59

What is an EKG?

What are the three waves and describe them?

Answer 59

a composite of all the action potentials generated by nodal and contractile cells at a given time

P wave: depolarization of SA node
QRS complex: ventricular depolarization
T wave: ventricular repolarization

Question 60

Why doesnt the p wave repolarization show up?

Answer 60

hidden in the QRS

Question 61

What happens in a junctional rhythm?

Answer 61

The SA node is nonfunctional, P waves are absent, and heart is paced by the AV node at 40 - 60 beats/min.

Question 62

What is a Second-degree heart block?

Answer 62

Some P waves are not conducted through the AV node; hence more P than QRS waves are seen. In this tracing, the ratio of P waves to QRS waves is mostly 2:1.

Question 63

What is ventricular fibrillation?

Answer 63

These chaotic, grossly irregular ECG deflections are seen in acute heart attack and electrical shock.

Question 64

What is the Lubb heart sound?

When does it occur?

Answer 64

first heart sound (S1)
A-V valves closing
occurs during ventricular systole

Question 65

What happens if you have a long QT what can happen?

Answer 65

go into torsades

Question 66

What is the Dubb heart sound?

When does it occur?

Answer 66

second heart sound (S2)
pulmonary and aortic semilunar valves closing
occurs during ventricular diastole

Question 67

First heart sound occurs when what happens and signifies what?

Second heart sound occurs when what happens and signifies what?

Answer 67

First sound occurs as AV (Tricuspid and Mitral) valves close and signifies beginning of systole

Second sound occurs when SL (Aortic and Pulmonic) valves close at the beginning of ventricular diastole

Question 68

What are heart murmurs?

Answer 68

Heart murmurs: abnormal heart sounds most often indicative of valve problems

Question 69

1. Aortic valve is heard where?
2. Pulmonary valve is heard where?
3. Mitral valve is heard where?
4. Tricuspid valve is heard where?

Answer 69

1. Aortic valve sounds heard
   in 2nd intercostal space at
   right sternal margin
2. Pulmonary valve
   sounds heard in 2nd
   intercostal space at left
   sternal margin

3. Mitral valve sounds
heard over heart apex
(in 5th intercostal space)
in line with middle of
clavicle

4. Tricuspid valve sounds typically
   heard in right sternal margin of
   5th intercostal space

Question 70

What is the definition of the cardiac cycle?

What is systole?
What is diastole?

Answer 70

all events associated with blood flow through the heart during one complete heartbeat

Systole—contraction
Diastole—relaxation

Question 71

1. What is the first phase of the cardiac cycle?
2. When does it take place?
3. What valves are open?
4. What percent of the blood passively flows into the ventricles?
5. What delivers the remaining percentage?
6. What is end diastolic volume?

Answer 71

1. Ventricular filling—
2. takes place in mid-to-late diastole
3. AV (tricuspid and mitral) valves are open
4. 80% of blood passively flows into ventricles
5. Atrial systole occurs, delivering the remaining 20%
6. End diastolic volume (EDV): volume of blood in each ventricle at the end of ventricular diastole

Question 72

1. What is the second phase of the cardiac cycle?
2. What do the atria do here?
   Ventricles?
3. What causes the closing of the AV valves?
4. What contraction phase is this?
5. What happens in the ejection phase?
6. What is end systolic volume?

Answer 72

1. Ventricular systole
2. Atria relax and ventricles begin to contract
3. Rising ventricular pressure results in closing of AV valves
4. Isovolumetric contraction phase (all valves are closed)
5. In ejection phase, ventricular pressure exceeds pressure in the large arteries, forcing the SL valves open
6. End systolic volume (ESV): volume of blood remaining in each ventricle

Question 73

1. What is the third phase of the cardiac cycle?
2. What do the ventricles do?
3. What closes the SL valves and what does this cause?

Answer 73

1. Isovolumetric relaxation occurs in early diastole
2. Ventricles relax
3. Backflow of blood in aorta and pulmonary trunk closes SL valves and causes dicrotic notch (brief rise in aortic pressure)

Question 74

SV =

CArdiac output =

Answer 74

EDV - ESV

SV(stroke volume) X HR

Question 75

1. The second heart sound is associated with the closing of which heart valves?
2. If the MV were insufficient, would you expect to hear the murmur during ventricular systole or diastole?
3. During the cardiac cycle, there are two periods when all four valves are closed. Name these two periods.

Answer 75

1. SL valves closing
2. systole (AV valve should we closed during systole)
3. • -Isovolumetric contraction phase- beginning of systole (ventricle depolarization) and
   • -Isovolumetric relaxation -beginning of diastole (ventricle repolarization)

Question 76

What is cardiac output?

Answer 76

Volume of blood pumped by each ventricle in one minute

Question 77

What is stroke volume?

Answer 77

volume of blood pumped out by a ventricle with each beat

Question 78

1. At rest what is our normal cardiac output?
2. Maximal CO is ____ times resting CO in nonathletic people
3. Maximal CO may reach ___ L/min in trained athletes
4. What is the Cardiac reserve?

Answer 78

1. CO (ml/min) = HR (75 beats/min) × SV (70 ml/beat) = 5.25 L/min
2. 4–5
3. 35
4. difference between resting and maximal CO

Question 79

Three main factors affect SV?

Answer 79

Preload (EDV)
Contractility (ESV)
Afterload (ESV)

Question 80

1. Ejection fraction is what?
2. Whats normal?
3. How can we determine this? 2

Answer 80

1. measurement of ventricular systolic function
2. normal is 60%
3. • echocardiogram
   • cardiac catheterization

Question 81

What is the definition of preload?

Answer 81

Preload: degree of stretch of cardiac muscle cells before they contract (Frank-Starling law of the heart)

Question 82

1. What kind of relationship does cardiac muscle exhibit?
2. What length are cardiac cells at rest?
3. What increases venous return?
4. What does increased venous return do?2

Answer 82

1. Cardiac muscle exhibits a length-tension relationship
2. At rest, cardiac muscle cells are shorter than optimal length
3. Slow heartbeat and exercise increase venous return
4. Increased venous return
   - -distends (stretches) the ventricles and
   - -increases contraction force

Question 83

1. Pressure-volume relationships are critical for understanding the pathophysiologic mechanisms of diseases that affect the entire ventricular chamber function, such as ______ _______ and_______ abnormalities.
2. Increase pre-load ______ SV
3. Increase after-load _______ SV
4. Increasing contractile state shifts the isovolemic pressure-volume relationship ______ (_______ ESV) _______ SV

Answer 83

1. heart failure
   valvular
2. increases
3. decreases
4. leftward
   decreasing
   increasing

Question 84

What is contractility?

What is it independant of? 2

Answer 84

contractile strength at a given muscle length,

independent of muscle stretch and EDV

Question 85

Positive inotropic agents _______contractility. How? 2

Negative inotropic agents _______ contractility
When would this occur? 3

Answer 85

Increase
1. Increased Ca2+ influx due to
sympathetic stimulation
2. Hormones (thyroxine, glucagon, and epinephrine)

decrease

1. Acidosis
2. Increased extracellular K+
3. Calcium channel blockers

Question 86

Decreased contractility affects volume and pressure how?

Increased contractiility affects volume and pressure how?

Answer 86

Increases them

Decreases them

Question 87

Positive chronotropic factors ______ heart rate

Negative chronotropic factors ______ heart rate

Answer 87

increase

decrease

Question 88

Sympathetic nervous system is activated by emotional or physical stressors:
Norepinephrine causes the pacemaker to fire more______ (and at the same time_______ contractility)

Answer 88

rapidly

increases

Question 89

Sympathetic Effects on Heart rate

4

Answer 89

1. Releases norepinephrine at sympathetic ending
2. Causes increased sinus node discharge
3. Increases rate of conduction of impulse
4. Increases force of contraction in atria and ventricles

Question 90

Sympathetic activation increases pacemaker rate by

decreasing ___ perm and increasing slow inward___ and ___?

Answer 90

K+

Ca++
Na+

Question 91

Does parasympathetic affect contractility?

Answer 91

no

Question 92

Parasympathetic nervous system opposes sympathetic effects. How?

The heart at rest exhibits vagal tone. Why?

Answer 92

Acetylcholine hyperpolarizes pacemaker cells by opening K+ channels

parasympathetic response

Question 93

Parasympathetic (vagal) nerves, which release ______ at their endings, innervate what? 2

What does this cause and why?

Answer 93

acetylcholine

1. S-A node and
2. A-V junctional fibers proximal to A-V node.

Causes hyperpolarization because of increased K+ permeability in response to acetylcholine.

Question 94

Hyperpolarization due to increased K+ permeability in response to acetylcholine causes what?

Which leads to what??

Answer 94

decreased transmission of impulses maybe temporarily stopping heart rate.

Ventricular escape occurs

Question 95

1. What is the atrial (brain bridge) reflex?
2. What stimulates the SA node?
3. What does this also stimulate?

Answer 95

1. a sympathetic reflex initiated by increased venous return
2. Stretch of the atrial walls stimulates the SA node
3. Also stimulates atrial stretch receptors activating sympathetic reflexes

Question 96

Sympathetic stimulation causes an increase in what two things?

Parasympathetic does the opposite

We can tachycardia decrease cardiac output?

Answer 96

HR+ contractility
with HR = 180-200 and C.O. = 15-20 L/min.

because there is not enough time for heart to fill during diastole.

Question 97

Epinehphrine from where enhances what two things?

Thyroxine increases what?
And enchances what?

Answer 97

Epinephrine from adrenal medulla enhances heart rate and contractility

Thyroxine increases heart rate and enhances the effects of norepinephrine and epinephrine

Question 98

What is the common sign of low contractility?

Answer 98

leg edema

CCB

Question 99

Other Factors that Influence Heart Rate

4

Answer 99

Age
Gender (females have faster HR)
Exercise
Body temperature

Question 100

Bradycardia: heart rate slower than 60 bpm. What could this result in?

Answer 100

May result in grossly inadequate blood circulation

Question 101

HOw do we Assess Perfusion at the Bedside?

3

Answer 101

1. Cold extremities indicate reduced perfusion so feel the feet
2. Poor Urine Output also indicates poor tissue perfusion

You now have 2 ways to determine if the patient is adequately perfusing or to see if the heart is doing its job or mission.

3. Don’t forget the Blood pressure