Exam 3 [Diseases Of Heart]

Question 1

Cause of Ischemic Heart Disease

Answer 1

Usually atherosclerosis

Question 2

Cause of Hypertension Heart Disease

Answer 2

Obesity -> Hypertension -> Atherosclerosis

Question 3

Cause of Valvular Disease

Answer 3

May be Congenital or a Complication of other Heart Diseases

Question 4

Heart diseases that cause Valvular disease

Answer 4

• Rheumatic fever
• Infective Endocarditis
• Ischemic heart Disease
• Cardiomyopathies

Question 5

Major Manifestations of Heart Disease

Answer 5

• Pain
• Change in Size (usually enlargement)
• Failure
• Arrythmias

Question 6

Hypertrophy Definition

Answer 6

Increased muscle mass of a ventricle (decreasing size of chamber)

Question 7

Heart Dilation definition

Answer 7

• Heart muscles becomes flabby/hypotonic
• Ventricle stretches (enlarging the chamber)

Question 8

Cause of Arrythmias

Answer 8

• Ischemia
• Myocarditis
• Drugs
• Electrolyte abnormalities

Question 9

Effect of an Arrythmia

Answer 9

Decreased Cardiac Output

Question 10

Cause of “Low Output Failure” & What is “Low Output Failure”?

Answer 10

Caused by heart disease, failure of the pump

Question 11

Cause of “High Output Failure” & What is “High Output Failure”?

Answer 11

Caused by diseases not of the myocardium, Heart can’t pump fast enough to meet tissues needs

Question 12

Example of Low Output Failure

Answer 12

• Acute MI
• Cardiac Tamponade
• tension Pneumothorax
• Pulmonary Embolism
• Acute Valve failure

Question 13

Example of High Output Failure

Answer 13

• Anemia
• Hyperthyroidism
• Pregnancy

Question 14

What is “Forward Failure”?

Answer 14

Failure of delivery of the correct amount of blood to the tissues

Question 15

What is “Backward Failure”?

Answer 15

Congestion of blood in the venous system due to failure of heart to keep blood circulating

Question 16

Examples of Left Ventricular Failure:

Answer 16

1) Ischemic heart Disease
2) Hypertensive Heart Disease
3) Aortic OR Mitral Valve disease
4) Myocarditis
5) Cardiomyopathy
6) Cardiac Amyloidosis
7) High Out-Put States

Question 17

Examples of Right Ventricular Failure:

Answer 17

1) MC: Left Ventricular Failure
2) Chronic Pulmonary Disease (cor pulmonale)
3) Pulmonary OR Tricuspid Valve Stenosis
4) Congenital Heart Disease

Question 18

What is the most common cause of isolated Right Ventricular Failure?

Answer 18

Chronic Pulmonary Disease (cor pulmonale)

Question 19

Systemic Effects of Acute LVF (forward failure)

Answer 19

1) Hypotension
2) Syncope
3) Cardiogenic Shock
4) Sudden Death

Question 20

Systemic Effects of Acute LVF (backward failure)

Answer 20

Pulmonary Edema

Question 21

Systemic Effects of Chronic LVF (forward failure)

Answer 21

1) Ischemia of all organs
2) Hypoxia of Kidneys (Sodium/Fluid retention)

Question 22

Systemic Effects of Chronic LVF (backward failure)

Answer 22

Pulmonary Congestion

Question 23

Systemic Effects of Acute RVF (forward failure)

Answer 23

Sudden Death

Question 24

Systemic Effects of Acute RVF (backward failure)

Answer 24

Sudden, Painful Swelling of the Liver & Increased Jugular Venous Pressure

Question 25

Systemic Effects of Chronic RVF (forward failure)

Answer 25

No Clinical Consequences

Question 26

Systemic Effects of Chronic RVF (backward failure)

Answer 26

• Swelling of ankles
• Venous Congestion of Liver “Nutmeg Liver”
• Increased Jugular Venous Pressure
• Hypoxia of Kidneys (Sodium/Fluid retention)

Question 27

4 Types of Ischemic heart Disease

Answer 27

1) Angina Pectoris
2) Chronic Ischemic heart Disease
3) Myocardial infarction
4) Sudden Cardiac Death

Question 28

When does “Typical (Stable)” Angina Pectoris become a problem?

Answer 28

When Vessel is narrowed 75% or more of the area of the Lumen

Question 29

Cause of “Typical (Stable)” Angina Pectoris

Answer 29

Atherosclerosis

Question 30

Symptoms of “Typical (Stable)” Angina Pectoris

Answer 30

• Recurrent chest pain w/ activity or stress
• Pain is limited in duration & relieved by rest
• Pain usually Substernal OR radiates to left arm, jaw & upper abdomen

Question 31

What medication can decrease “Typical (Stable)” Angina Pectoris Pain?

Answer 31

Sublingual Nitroglycerin (Vasodilator)

Question 32

“Unstable” Angina Pectoris is associated with

Answer 32

Atherosclerosis

Question 33

Cause of “Unstable” Angina Pectoris

Answer 33

Worsening symptoms of angina due to Thrombus formation over plaque of atherosclerosis

Question 34

What brings on the symptoms of “Unstable” Angina Pectoris?

Answer 34

Exercise
- less exercise needed to bring symptoms as time passes, eventually rest can bring symptoms

Question 35

“Unstable” Angina Pectoris is also known as:

Answer 35

Crescendo Angina because it usually ends in a Myocardial Infarction

Question 36

Cause of “Variant (Prinzmetal)” Angina Pectoris

Answer 36

• Unknown
• But it is due to Vasospasm NOT ATHEROSCLEROSIS

Question 37

When does pain occur in “Variant (Prinzmetal)” Angina Pectoris?

Answer 37

Often at rest

Question 38

Heart Attack = ???
MI = ???

Answer 38

Heart Attack = Clinical Syndrome
MI = Autopsy Finding
“A heart attack may not be produced by an AMI”

Question 39

Myocardial Infarction Risk Factors:

Answer 39

1) Atherosclerosis
2) Systemic Hypertetion
3) Diabetes Mellitus
4) Smoking
5) Emotional Stress/ Physical Activity
6) Hypoxia (anemia or respiratory diseases)

Question 40

What heart layers are damaged by Myocardial Infarction?

Answer 40

Endocardium or Pericardium
+ necrosis of muscle

Question 41

Most Myocardial Infarction’s affect what chamber of the heart?

Answer 41

Left Ventricle

Question 42

Arteries MCly causing a Myocardial Infarction & their Percentages

Answer 42

Right Coronary Artery (30%)
Left Anterior Descending Artery (50%)
Left Circumflex Artery (20%)

Question 43

Enzymatic Proteins in Myocardial Infarction & When they rise

Answer 43

Troponins
CPK-MB (rise in 3-6 hours, peak at 18-24 hours)
SGOT & LDH also rise

Question 44

ECG Features in a Myocardial Infarction

Answer 44

Elevation of ST Segment + Q Waves
- T wave Inversion

Question 45

Risk Factors of Chronic Ischemic Heart Disease (Ischemic Cardiomyopathy)

Answer 45

1) Patchy loss of muscle w/ fibrosis and inflammatory cells
2) Chronic LVF or an arrhythmia (such as a heart block)

Question 46

What is Chronic Ischemic Heart Disease (Ischemic Cardiomyopathy)?

Answer 46

• Multiple atherosclerotic narrowing in the blood vessels
• Irregular chronic MI

Question 47

Definition of Sudden Cardiac Death:

Answer 47

Unexpected death due to a lethal arrythmia such as asystole or sustained ventricular fibrilation

Question 48

Risk Factors of Sudden Cardiac Death:

Answer 48

1) Patients w/ atherosclerosis
2) People who smoke cigarettes

Question 49

What decreases most rapidly following cessation of smoking?

Answer 49

Risk of Sudden Cardiac Death

Question 50

Risk factors of the development of Ischemic Heart Disease:

Answer 50

Are basically the same as for Atherosclerosis
(Incidence for CIHD is used from the measurement of incidence of atherosclerosis in a population)

Question 51

Pathology of Hypertensive Heart Disease:

Answer 51

• Left ventricular hypertrophy
• Left ventricular failure (40% of deaths in hypertensive patients)
• Ischemic heart disease

Question 52

Cause of Acute Cor Pulmonale

Answer 52

• Pulmonary Hypertension leading to increased pressure in R. Side of the heart
• Massive Pulmonary Embolism

Question 53

Cause of Chronic Cor pulmonale

Answer 53

• COPD
• Autoimmune Diseases
• Blood clots in lungs
• Cystic Fibrosis
• Scarring of Lung tissue
• Severe Kyphoscoliosis

Question 54

Pathophysiology of Acute Cor Pulmonale

Answer 54

• Increased pressure in R. Side of heart
• R. Ventricular dilatation & failure

Question 55

Pathophysiology of Chronic Cor Pulmonale

Answer 55

• Increased R. Ventricular afterload
• Preserve’s stroke volume until Myocardium fails due to Ischemia or other pathological condition

Question 56

Etiology of Mitral Stenosis

Answer 56

• Chronic Rheumatic heart Disease
• Female 9:1

Question 57

Pathophysiology of Mitral Stenosis

Answer 57

• Increased resistance to transmittal flow
• Thickening of valve leaflets (narrowing the valve)

Question 58

Etiology of Mitral Regurgitation

Answer 58

• 50% due to chronic rheumatic heart disease combined with aortic stenosis
• “Fen-Phen” induced valvular fibrosis

Question 59

Mitral Valve prolapse is seen in what population?

Answer 59

1% of young adults (mostly females)

Question 60

Mitral Valve prolapse is due to:

Answer 60

Degeneration of the valve
(A.k.a. “Floppy Valve Syndrome”)

Question 61

Rupture of what can lead to Mitral Regurgitation?

Answer 61

• Chordate Tendinae (due to endocarditis)
• Papillary muscles (due to MI)

Question 62

Pathophysiology of Mitral Regurgitation

Answer 62

• Volume & pressure is transmitted backward from left atrium to the pulmonary vasculature
• disruption of the papillary muscles, chordate tendinae or valve leaflets (chronic = L. Ventricle)

Question 63

Etiology of Aortic Stenosis

Answer 63

• Rheumatic Aortis Stenosis
• Congenital bicuspid valves (50% of cases)
• Hypertrophic cardiomyopathy

Question 64

Pathophysiology of Aortic Stenosis

Answer 64

• Ventricle can no longer compensate -> L. Ventricle enlargement
• Reduced ejection fraction & CO
• Lipid accumulation
• Inflammation
• Calcification & Fibrosis of the valve

Question 65

Etiology of Aortic Regurgitation

Answer 65

• Rheumatic heart disease (50%) usually associated with aortic stenosis & mitral valve disease
• Syphilitic Aneurysm
• Valve rupture due to endocarditis

Question 66

Pathophysiology of Aortic Regurgitation

Answer 66

• Increase in regurgitation volume in L. Ventricle
• Poor forward flow
• Diastolic pressure increases -> acute pulmonary edema & cardiogenic shock

Question 67

Examples of Pulmonary Valve Stenosis

Answer 67

1) Congenital
2) Tetralogy of Fallot
3) Carcinoid Syndrome

Question 68

Populations affected by Rheumatic Fever

Answer 68

• children 5-15 years old
• lower social economic groups

Question 69

Etiology of Rheumatic fever

Answer 69

• Occurs 2-6 weeks following streptococcal pharyngitis
• Group A streptococcus (streptococcus pyogenes)

Question 70

Antigen/Antibodies in Rheumatic Fever

Answer 70

• Associated w/ HLA-B5 antigen
• Cross reacting antibodies (hypersensitivity Type II)

Question 71

Rheumatic Fever affects what layers of the heart?

Answer 71

All of Them

Question 72

Acute vs. Chronic presentation of Rheumatic Fever

Answer 72

Acute = “acute rheumatic carditis”
Chronic = “chronic valvular deformities”

Question 73

Affect of Rheumatic Fever on the Endocardium

Answer 73

Vegetations on the heart valves

Question 74

Affect of Rheumatic Fever on the Myocardium

Answer 74

(Myocarditis)
- Becomes pale, flabby & hypotonic
- Aschoff Body = Characteristic Lesion***

Question 75

Affect of Rheumatic Fever on the Pericardium

Answer 75

(Pericarditis) Only in the most severe cases

Question 76

Clinical Features of Rheumatic Fever

Answer 76

• Fever
• Arthritis
• congestive heart failure, chest pain, shortness of breath
• fatigue
• chorea ( uncontrollable body movements)

Question 77

What is Chronic Rheumatic Heart Disease?

Answer 77

Severe valvular scarring occurring weeks to years after acute rheumatic fever

Question 78

Most common valvular lesions

Answer 78

1) Mitral Stenosis & Mitral Incompetence
2) Aortic Valve Lesions
3) Tricuspid Valve Lesions (10%)

Question 79

Complications of Chronic Rheumatic Heart Disease

Answer 79

1) Bacterial Endocarditis
2) Mural thrombi in the Atria or Ventricles
3) Cor pulmonale
4) Congestive Heart failure
5) Adhesive Pericarditis

Question 80

Nonbacterial Thrombotic Endocarditis Pathophysiology

Answer 80

• has vegetations
• nondestuctive

Question 81

Libman-Sacks Endocarditis Pathophysiology

Answer 81

Immune complex sterile vegetations on heart valves

Question 82

Acute Infective Endocarditis Organisms

Answer 82

Staph Aureus OR Streptococcus Pyogenes

Question 83

Acute Infective Endocarditis Presentation

Answer 83

• Lasts less than 6 weeks
• May have completely normal heart
• may produce perforation of a valve

Question 84

Subacute Infective Endocarditis Presentation

Answer 84

• Present longer than 6 weeks
• Patient has pre-existing cardiac abnormality
• Rarely perforates the valve

Question 85

Subacute Infective Endocarditis Organisms

Answer 85

Staphlococcus Epidermis OR Streptococcus Viridans

Question 86

Infective Endocarditis: Populations affected

Answer 86

1) Patients w/ Cardiac Abnormalities
2) Valve replacement surgery
3) Intravenous Drug abusers

Question 87

Pathology of Infective Endocarditis

Answer 87

1) vegetations on endocardium of valves that contain organisms
2) often large, hemorrhagic & friable producing septic emboli

Question 88

Complications of Infectious Endocarditis

Answer 88

1) Valve dysfunction w/ changing murmurs
2) Septic Emboli producing mycotic aneurysyms/abscesses
3) Immune complex diseases
4) Microinfarctions from Emboli

Question 89

Causes of Infectious Myocarditis

Answer 89

1) Viral infections
2) bacterial
3) Protozoa
4) Fungi
5) helminths

Question 90

Causes of Noninfectious Myocarditis

Answer 90

1) rheumatic fever
2) systemic lupus erthematosus
3) Allergic drug reactions
4) cardiac transplantation rejection
5) sarcoidosis

Question 91

Causes of Dilated Cardiomyopathy

Answer 91

1) Post-Myocarditis
2) Alcohol Toxicity
3) Pregnancy
4) Chemical Toxicity
5) Idiopathic dilated cardiomyopathy

Question 92

Pathology of Dilated Cardiomyopathy

Answer 92

• general enlargement/dilation
• poor contracting -> stagnant blood leading to mural thrombi & thromboemboli
• may produce Arrythmias

Question 93

Populations affected in Dilated Cardiomyopathy

Answer 93

• MC 20-60 years old
• Men > Women
• May be familial distribution

Question 94

Clinical aspects of Dilated Cardiomyopathy

Answer 94

• Progressive congestive cardiac failure
• Death

Question 95

Management of Dilated Cardiomyopathy

Answer 95

Cardiac Transplant

Question 96

Peripartum Cardiomyopathy

Answer 96

Exception (50% of patients recover spontaneously after pregnancy)

Question 97

Causes of Hypertrophic Cardiomyopathy

Answer 97

• 50% Autosomal Dominant (chromosome 14)
• All else = Idiopathic

Question 98

Pathology of Hypertrophic Cardiomyopathy

Answer 98

• Assymetric myocardial hypertrophy in the Interventricular Septum
• Heart weighs > 800 mg’s
• Ventricular outflow obstruction
• Dilated Left Atrium

Question 99

Clinical Effects of Hypertrophic Cardiomyopathy

Answer 99

• Sudden death
• Dyspnea, syncope & dizziness
• systolic ejection murmur
• angina pain

Question 100

Risks following Hypertrophic Cardiomyopathy

Answer 100

• Bacterial Endocarditis
• Progressive myocardial Fibrosis produces congestive cardiac failure

Question 101

Causes of Restrictive Cardiomyopathy

Answer 101

1) Cardiac amyloidosis
2) Sarcoidosis
3) Radiation injury
4) Hemochromatosis

Question 102

Pathology of Restrictive Cardiomyopathy

Answer 102

• ventricular muscle becomes rigid & loses compliance
• ventricle difficult to fill, but ejection is not forceful

Question 103

Clinical Effects of Restrictive Cardiomyopathy

Answer 103

• Fatigue, Exertional Dyspnea, Anginal pain
• May have arrythmias (including heart blocks)

Question 104

In later stages of Restrictive Cardiomyopathy…

Answer 104

Development of Congestive Cardiac Failure

Question 105

Causes of Obliterative Cardiomyopathy

Answer 105

1) tropical endocardial fibrosis
2) eosinophilic endomyocardial fibrosis (Loffler’s Syndrome)

Question 106

Pathology of Obliterative Cardiomyopathy

Answer 106

• Atria are normal sized
• Thick & Opaque Endocardium
• Thick Valves
  -Endocardium Fibrosis extends to Myocardium
• Eosinophil Infiltration

Question 107

Clinical Features of Obliterative Cardiomyopathy

Answer 107

• Tropical form in equatorial Africa
• Major Fibrosis & eosinophilia of Cardiac Muscle
• Restrictive Disease

Question 108

Obliterative Cardiomyopathy accounts for what percent of childhood Heart disease?

Answer 108

10%

Question 109

Most common congenital defect diagnosed vs. most common that is prevalent:

Answer 109

Diagnosed: VSD
Most Prevalent: ASD (not diagnosed until adulthood)

Question 110

Risk Factors of Congenital heart disease

Answer 110

1) In-Utero Infectinos
2) Chromosomal Defects
3) In-Utero Chemical Exposure (FAS)
4) In-Utero Radiation Exposure
5) Premature Delivery

Question 111

Effects of Congenital heart disease

Answer 111

1) abnormal blood flow -> murmurs
2) Shunts of blood from one side of the heart to the other
3) Short circuits of blood through circulation
4) Infective Endocarditis
5) Failure to thrive

Question 112

Presence or absence of a shunt percentages in Congenital heart disease

Answer 112

W/O: 20%
W/: 80%

Question 113

Acyanotic Congenital Heart Diseases

Answer 113

With a Shunt there is no cyanosis because direction of blood flow is Left to Right

Question 114

Cyanotic Congenital Heart Diseases

Answer 114

Right to Left shunt so it bypasses the lungs

Question 115

Small VSD (maladie de Roger) Produces:

Answer 115

1) Produces low volume shunt in systole
2) Produces pansystolic murmur

Question 116

Small VSD (maladie de Roger) Symptoms

Answer 116

-Few symptoms
- Defect decreases in size as child grows & may close spontaneously

Question 117

What is a Large VSD

Answer 117

• Volume overload & hypertrophy of both ventricles
• Pansystolic murmur

Question 118

What happens due to a Large VSD?

Answer 118

• Pulmonary Hypertension from increased pulmonary blood flow
• Thick & Narrow pulmonary vessels
• Eventually pressure in R. atrium increases so much that shunt flow decreases in volume & reverses itself

Question 119

Patient with a LArge VSD are at risk for:

Answer 119

Infective Endocarditis

Question 120

ASD Symptoms

Answer 120

(Usually none)
Patent Foramen Ovale doesnt produce symptoms, but functionally there is no movement of blood.

Question 121

ASD Clinical features

Answer 121

• R. Ventricular Hypertrophy
• Delayed pulmonary valve closing (Split S2)
• Can produce a pulmonary ejection murmur

Question 122

ASD Main Complication

Answer 122

• Pulmonary Hypertension
• Increased Righ side pressure
• Eventually reversal of the shunt

Question 123

What is Patent Ductus Arteriosus

Answer 123

-Ductus Arteriosus fails to close after birth
- Premature Infants

Question 124

What medication can potentially close ductus arteriosus?

Answer 124

Indomethacin

Question 125

Patent Ductus Arteriosus Pathology

Answer 125

• Continual blood flow from aorta to pulmonary circulation -> Pulmonary Hypertension
• “Machinery murmur” during entire cardiac cycle

Question 126

Left to Right Shunt Defects

Answer 126

1) VSD
2) ASD
3) Patent Ductus Arteriosus

Question 127

Right to Left Shunt Defects

Answer 127

[THESE PRODUCE CYANOSIS]
1) Tetrlogy of Fallot
2) Transportation of the Great Vessels
3) Eisenmenger’s Syndrome

Question 128

Tetralogy of Fallot Components

Answer 128

1) Over-riding Aorta
2) Pulmonary Stenosis
3) Right Ventricular Hypertrophy
4) Ventricular Septal Defect

Question 129

Tetralogy of Fallot Pathology & Treatment

Answer 129

• Pulmonary. Stenosis increases R. Ventricle pressure
• Surgery

Question 130

Tetralogy of Fallot Characteristic Behavior

Answer 130

Children running distance would have to squat down on their heels to equilibrate pressures

Question 131

Transposition of the Great Vessels Pathology

Answer 131

-Truncus Arteriosus forms abnormally
- Pulmonary trunk arises from L. Ventricle
- Aorta arises from R. Ventricle
(2 separate circulations)

Question 132

Transposition of the Great Vessels Fatality

Answer 132

Immediately unless Foramen Ovale & Ductus Arteriosus do not close

Question 133

What is Eisenmenger’s Syndrome

Answer 133

• A reversal of a previously acyanotic shunt that now produces cyanosis
• Once shunt reverses -> fatal and no longer eligible for surgery

Question 134

reversal of a shunt in Eisenmenger’s Syndrome makes the individual prone to:

Answer 134

Paradoxical Emboli

Question 135

Chronic Adhesive Pericarditis

Answer 135

May occur following bacterial infection of the pericardium where there was pus formation and exudate in the pericardium

Question 136

Chronic Restrictive Pericarditis

Answer 136

• Associated with Tuberculosis
• Tuberculosis Pericarditis encased the heart in fibrous tissue

Question 137

Glycogen Storage Diseases that affect the heart

Answer 137

Pompe’s Disease

Question 138

Myxoma

Answer 138

[Benign tumor of the heart]
- MC Primary Heart Tumor
- MC in Left Atrium

Question 139

Pompe’s Disease “Glycogenosis Type II”: What is it?

Answer 139

• Autosomal Recessive
• Lysosomal storage disorder
• Alpha-Glucosidase (DAA) Deficiency
• cant metabolize glycogen

Question 140

Pompe’s Disease “Glycogenosis Type II”: Accumulation of Glucose Causes what?

Answer 140

• Mental retardation
• enlarged heart, liver & spleen
• cardiac muscle failure