Cardiology

Question 1

ECG

Question 2

Which leads point in the downward direction?

Answer 2

• aVF (straight down, 90 degrees)
• II (60 degrees)
• III (120 degrees)

Question 3

Which lead is at 0 degrees?

Answer 3

I

Question 4

What is a normal range for mean axis of depolarization?

Answer 4

-30 to 110

Question 5

What is a quick way to know that the axis of depolarization is in the normal range?

Answer 5

“Thumbs up sign”

If pt is positive in lead I and positive in aVF, they are in normal range (0-90)

Question 6

What part of electrical conduction of the heart does the P wave represent?

Answer 6

Atrial depolarization

Question 7

What part of electrical conduction of the heart does the QRS complex represent?

Answer 7

Ventricular depolarization

Question 8

What part of electrical conduction of the heart does the T wave represent?

Answer 8

Ventricular repolarization

Question 9

If lead I is isoelectric, which lead do you look at to determine direction of the axis of depolarization?

Answer 9

aVF

• If (+), axis is +90
• If (-), axis is -90

Question 10

If lead II is isoelectric, which lead do you look at to determine direction of the axis of depolarization?

Answer 10

aVL

• If (+), it is -30
• If (-), it is +150

Question 11

If lead aVF is isoelectric, which lead do you look at to determine direction of the axis of depolarization?

Answer 11

Lead I

• If (+), it is 0
• If (-), it is +180

Question 12

What does a long QT interval indicate?

Answer 12

Problems with repolarizing the ventricles

Question 13

How is heart rate calculated?

Answer 13

Find an R wave which peaks on a heavy line – the next heavy black line is 300, followed by 150, 100, 75, 60 and 50

Question 14

In normal sinus rhythms, the P wave is upright in which leads?

Answer 14

Leads I and II

Question 15

What does the PR interval indicate?

Answer 15

Time it takes for stimulus to travel from the SA node to the ventricles

Question 16

What does an inverted T wave represent?

Answer 16

Ischemia

Question 17

How is the QT interval affected by LV hypertrophy?

Answer 17

Lengthened

Question 18

How is the QT interval affected by digitalis?

Answer 18

Shortened

Question 19

How is the QT interval affected by hypokalemia?

Answer 19

Lengthened

Question 20

How is the QT interval affected by MI?

Answer 20

Lengthened

Question 21

How is the QT interval affected by Hypercalcemia?

Answer 21

Shortened

Question 22

How is the QT interval affected by myocarditis?

Answer 22

Lengthened

Question 23

How is the QT interval affected by thyrocosis?

Answer 23

Shortened

Question 24

How is the QRS complex affected by AV node escape rhythm?

Answer 24

Narrowed

Question 25

How is the QRS complex affected by ventricular escape rhythm?

Answer 25

Widened

depolarization wave spreads slowly via abnormal pathway in the ventricular myocardium and not via the His bundle and bundle branches

Question 26

What is the inherent HR of the following?

• Atria
• AV node
• Ventricles

Answer 26

• Atria: 75/min
• AV node: 60/min
• Ventricles: 30-40/min

Question 27

What do you look for on an ECG to determine whether the patient has heart block?

Answer 27

Whether every P wave is followed by QRS

Yes => No heart block

Question 28

What do you look for on an ECG to determine whether the patient has ischemia?

Answer 28

Inverted T wave

Question 29

Diagnose:

Answer 29

Sinus bradycardia

• Sinus rhythm
• HR = 45

Question 30

What are the characteristics of 1st degree heart block?

Answer 30

• P is followed by QRS
• PR interval is more than a box away (>250ms)

Question 31

What are the characteristics of 2nd degree heart block type I?

Answer 31

PR prolongation but just drops a beat out of no where

Question 32

What are the characteristics of 2nd degree heart block type II?

Answer 32

PR interval is the same before and after the block

(block is below the His-purkinje system)

Question 33

What are the characteristics of 3rd degree heart block?

Answer 33

• QRS complexes are going at their own rate
• don’t always see a p wave at end b/c it is superimposed on QRS

Question 34

What are the characteristics of a 2:1 AV block?

Answer 34

Pattern: P, QRS, P, (skip), P, QRS, P, (skip)

Question 35

What are the characteristics of atrial fibrillation?

Answer 35

• Ventricular rate is irregularly irregular, no discernable P waves
• upper chambers are just quivering
• see slide 88

Question 36

What are the characteristics of atrial flutter?

Answer 36

• Fast, but it is a circuit in the atrium going about 300 bpm
• See a saw-tooth pattern

Question 37

Determining L from R bundle branch block

Answer 37

• Bundle branch block
  
  • Widened QRS
• L or R?
  
  • Look at lead V1
  • Look at last part of QRS
  • If most energy is above the isoelectric line => Right
  • If most energy is below the line => Left
  • ***Think of a turn signal
  • Reference: ekg.academy

Question 38

What are the characteristics of acute ischemia? How can you tell if it affects the anterior heart or the inferior heart?

Answer 38

• Acute ischemia:
  
  • ST elevation
• Anterior heart
  
  • Leads V2, V3
• Inferior heart
  
  • Leads II, III, aVF

Question 39

What are the characteristics of an old infarct?

Answer 39

Significant Q wave

• wider than 1 mm or
• length 1/3 QRS amplitude

Question 40

What are the characteristics of ischemia?

Answer 40

• T wave inversion
• ST interval depression
• See slide 103

Question 41

What are the characteristics of pericarditis?

Answer 41

• Diffuse ST elevation (everywhere)
• PR depression
• They will have a rub that is worse when they lean forward

Question 42

Intro to CHF

Question 43

Decreased perfusion to the kidney activates what system? What is the result?

Answer 43

• Activates Renin - Angiotensin - Aldosterone system
• Result:
  
  • Na and water retention
  • Vasoconstriction

Question 44

What is abnormal about the beta receptors in CHF?

Answer 44

• Downregulate themselves
  
  • not as affected by NE (doesn’t permit vasodilation for example)

Question 45

What is the effect of the SNS in CHF?

Answer 45

• Increases afterload
• Increases HR
• Impairs contractility
• Increases O2 demand of the heart
  
  • provokes ischemia
• Triggers arrhythmia
• Ca overload and apoptosis

Question 46

What electrical abnormalities can be present in CHF?

Answer 46

• A-V dysynchrony
• Abnormal impulse propagation in the ventricules
• Atrial or ventricular arrhythmias

Question 47

What can cause high-output CHF?

Answer 47

• Thyrotoxicosis
• Beri beri
• A-V fistula

Question 48

What are the physical signs of Right sided CHF?

Answer 48

1. JVD
2. Tricuspid regurg
3. Peripheral edema
4. S3 gallop
5. Hepatojugular reflex
   
   • pushing on liver makes jugular distention increase

Question 49

What are the physical signs of Left sided CHF?

Answer 49

• Rales (crackles)
• Mitral regurg
• Pulmonary congestion
• S3 gallop
  
  • early diastolic sound
• Abnormal apical impulse

Question 50

What are the symptoms of CHF?

Answer 50

• Dyspnea
  
  • Orthopnea
  • Parosysmal nocturnal dyspnea
• Cheyne-stokes respiration
  
  • breathing pattern with apnea and hyperventilation
• Nocturia

Question 51

What is most important for diagnosis of CHF?

Answer 51

Thorough H&P

Question 52

What are some causes of CHF?

Answer 52

• CAD (Most common)
• Valvular disease
• Congenital disease
• Tachycardia
• Chagas
• Toxins:
  
  • ETOH
  • Cocaine
  • Adriamycin

Question 53

What toxins can result in CHF?

Answer 53

• EtOH
• Cocaine
• Adriamycin

Question 54

Should CHF patients be on ACE inhibitors?

Answer 54

Yes

Question 55

What is the MOA of Beta-blockers in CHF?

Answer 55

• Improve relaxation
• Protect myocardium from catecholamines
• Negative chronotrope
  
  • Decrease O2 demand
• Increase beta-receptor density

Question 56

What response do natriuretic peptides cause in the body?

Answer 56

Na and H2O diuresis

(counter the RAAS system)

Question 57

Shock

Question 58

Patient has mild hypotension, tachycardia, and tachypnea. There is also an increase in the anion gap. In what stage of shock is the patient? How effective is treatment?

Answer 58

• Stage I
  
  • Compensated
• Treatment is most effective in this stage

Question 59

Patient appears cool, cyanotic, and diaphoretic. He has hypotension, tachycardia, and tachypnea. He also has a decrease in urine output. In what stage of shock is the patient? How effective is treatment?

Answer 59

• Stage II
  
  • Compesatory mechanisms begin to break down
• Aggressive therapy can reverse changes

Question 60

Patient is found to have hypotension, tachycardia, and tachypnea. There are also signs of end organ damage and DIC. In what stage of shock is the patient? How effective is treatment?

Answer 60

• Stage III
  
  • Irreversible
• Therapy is not effective

Question 61

What is the cause of acidosis in shock? What problems result? What are the corrective measures?

Answer 61

• Cause:
  
  • anaerobic metabolism
  • Toxins
• Result:
  
  • alters oxy-hemoglobin dissociation
  • Hypoxia worsens
• Corrective measures:
  
  • Add buffer (NaHCO3)
  • Correct respiratory component

Question 62

What type of shock is characterized by a low CO and a high SVR? What is the cause?

Answer 62

• Cardiogenic shock
  
  • Cause: cardiomyopathy
  • Volume replacement makes worse
• Hypovolemia
  
  • hemorrhage
  • dehydration
  • fluid loss due to injury or burns
  • Volume replacement makes better

Question 63

What type of shock is characterized by a decreased SVR and a CO that may be normal, high, or low?

Answer 63

Septic Shock

Question 64

Patient has a low CO and a high SVR. Volume replacement worsens the problem. Which type of shock is this?

Answer 64

Cardiogenic shock

Question 65

Patient has alow CO and a high SVR. Volume replacement fixes the problem. Which type of shock is this?

Answer 65

Hypovolemia

Question 66

When can pressor support be used in the treatment of shock?

Answer 66

Only once hypovolemia is corrected

Question 67

Pulmonary Hypertension

Question 68

What is the effect of an increase in length of the vessel on vascular resistance?

Answer 68

Resistance will increase proportionately

Question 69

What is the effect of an increase in viscosity of blood on vascular resistance?

Answer 69

Resistance will increase proportionately

Question 70

What is the effect of an increase in radius of the vessel on vascular resistance?

Answer 70

The resistance will decrease (by a power of 4)

Ex: radius increases by a factor of 2, resistance will decrease by a factor of 16

Question 71

In pulmonary HTN, how is the intima and media changed?

Answer 71

• Intima:
  
  • hyperplasia
• Media
  
  • Hypertrophy
• Also interstitial fibrosis occurs

Question 72

What is Eisenmenger’s Syndrome? What is the result?

Answer 72

• Eisenmenger Syndrome
  
  • A previously L => R shunt changes to a R => L shunt
    
    • often due to increased pulm pressure from overload and damage
• Result
  
  • Fatal (lack of oxygenation)

Question 73

What is the result of Cor Pulmonale?

Answer 73

RV failure

Question 74

In pulmonary HTN, how is JVP affected?

Answer 74

• Large a wave
• Prominent v-wave

Question 75

What murmurs are common with Pulm HTN?

Answer 75

• Closely split S2 with loud P2
• PA click and murmur
• RV S3 gallop

Question 76

What changes in the carotid occur with Pulm HTN?

Answer 76

Low volume

(blood stuck in veins)

Question 77

What laboratory abnormalities can be found in Pulm HTN?

Answer 77

• Polycythemia
  
  • response to hypoxia
• Increased liver function tests
  
  • response to congestion of liver

Question 78

What ECG findings occur in Pulm HTN?

Answer 78

• Right axis deviation
• R atrial abnormalities
• LV hypertrophy

Question 79

How is primary Pulmonary Hypertension diagnosed? What population is most affected? What are the symptoms?

Answer 79

• Diagnosis
  
  • exclusion of other possibilities
• Population
  
  • young women
• Symptoms
  
  • Chest pain
  • Loud P2
  • Dyspnea on exertion

Question 80

What is the best treatment for Cor Pulmonale?

Answer 80

O2

Question 81

Cardiomyopathy

Question 82

Dilated cardiomyopathy results in dysfunction of what cardiac mechanism?

Answer 82

Contraction

(systole)

Question 83

What causes dilated cardiomyopathy?

Answer 83

• EtOH
• Cobalt
• Uremia
• Hypocalcemia
• Hypophosphatemia

Question 84

Hypertrophic cardiomyopathy results in dysfunction of what cardiac mechanism?

Answer 84

Filling

(diastole)

Question 85

What causes hypertrophic cardiomyopathy?

Answer 85

1. Genetics
2. Abnormal sympathetic stimulation
3. Ischemia (coronary artery disease)
4. Collagen abnormality

Question 86

What are the clinical manifestations of hypertrophic cardiomyopathy?

Answer 86

• Dyspnea
• Angina pectoris
• Fatigue
• Syncope
• Palpitations

Question 87

What murmurs can be present with hypertrophic cardiomyopathy?

Answer 87

• S3 gallop
• S4 gallop
• Systolic crescendo - decrescendo murmur
• Systolic thrill
• Mitral regurg (if systolic anterior motion is present)

***Best heard at apex

Question 88

Treatment of HCM is focused on trying to change what cardiac characteristics?

Answer 88

• Decrease contractility
• Increase ventricular compliance
• Increase ventricular volume
• Increase systemic arterial pressure
• Increase dimensions of outflow tract

Question 89

What pathophysiological signs are present in restrictive cardiomyopathy? What forms of cardiac dysfunction result?

Answer 89

• Myocardial fibrosis
• Hypertrophy
• Infiltration

This causes:

• Excessively rigid ventricular walls
• Abnormal diastolic function
  
  • impeded ventricular filling
• Abnormal systolic function

Question 90

What are the clinical manifestations of restrictive cardiomyopathy?

Answer 90

• Weakness and fatigue
• Increased central venous pressure
  
  • JVD
• Peripheral edema
  
  • Ascites
  • Anascara
• Inspiratory increase in venous pressure
  
  • aka Kussmaul’s sign

Question 91

What is Kussmaul’s sign?

Answer 91

An inspiratory increase in venous pressure

(present in Restrictive Cardiomyopathy)

Question 92

What causes restrictive cardiomyopathy?

Answer 92

• Amyloidosis
• Sarcoidosis
• Inherited infiltrative diseases
• Endomyocardial disease

Question 93

What are the causes of myocarditis?

Answer 93

• Infectious
  
  • most common is Coxsackie A and B
• Toxic
• Chemical
• Drugs
• Physical Agents

Not more specific than that in ppt

Question 94

A patient has a history of prodromal “flu”. Which type of pericarditis is most likely? How can this be confirmed?

Answer 94

• Viral pericarditis
  
  • Cocksackie A or B
  • Echovirus
  • EBV (mono)
• Confirmation
  
  • Viral titers

Question 95

Patient with pericarditis has been on dialysis. What is the most likely cause of the pericarditis? What complication can result?

Answer 95

• Cause:
  
  • Uremia
• Complication
  
  • Hemodynamic instability

Question 96

What type of MI is most likely to cause pericarditis? How long post-MI is it most likely to occur?

Answer 96

• Type:
  
  • Transmural MI
• Time frame
  
  • 2-3 days post-MI
• May have atrial arrhythmias

Question 97

Which cancers are most likely to cause pericarditis?

Answer 97

• Bronchogenic
• Breast
• Lymphoma
• Leukemia
• Melanoma

Question 98

What symptoms commonly occur with pericarditis?

Answer 98

• Chest pain
  
  • Pleuritic
• Dyspnea
• Fever

Question 99

What findings on physical exam indicate acute pericarditis?

Answer 99

• Friction rub
• Tachycardia
• Increased JVP
• Pulsus paradoxus
  
  • large decrease in systolic BP on inspiration

Question 100

What is the differential diagnosis for the signs and symptoms of Acute Pericarditis?

Answer 100

• Acute MI
• Pneumonia with Pleuritis
• Acute pulmonary embolism
• Chest trauma causing Pneumothorax
• GI disturbance

Question 101

What are the clinical manifestations of Cardiac Tamponade?

Answer 101

• Physical exam:
  
  • Beck’s Triad:
    
    • Hypotension
    • Elevated venous pressure
    • Small, quiet heart
  • Pulsus paradoxus
  • Tachycardia
  • Tachypnea
• History:
  
  • Chest pain
  • Dyspnea

Question 102

What is found on ECG for a patient with cardiac tamponade?

Answer 102

• ST elevation (pericarditis)
• Electrical alternans
  
  • alternation of QRS complex amplitude oraxis between beats and a possible wandering base-line
• Low voltage

Question 103

Which part of the heart cycle is affected by constrictive pericarditis?

Answer 103

Diastole

(Restricted filling of the heart)

Question 104

What are some causes of constrictive pericarditis?

Answer 104

• TB
• Uremia
• Irradiation
• Surgery
• Connective tissue disorders
• Cancer

Question 105

What are the clinical features of Constrictive Pericarditis?

Answer 105

• Diastolic pericardial knock
• Elevated venous pressure
  
  • Edema
  • Hepatomegaly
  • Ascites
  • Elevated jugular venous pressue (Kussmaul’s sign)
• Elevated left heart pressure
  
  • Dyspnea
  • Cough
  • Orthopnea
• Low cardiac output
  
  • Fatigue

Question 106

What are the differences in signs and symptoms between cardiac tamponade and constrictive pericarditis?

Answer 106

Question 107

Congenital Heart Disease

Question 108

Atrial septal defect

• Type of shunt
• Cyanotic?
• Complications
• Murmur
• ECG findings
• Method of diagnosis

Answer 108

• Type of shunt
  
  • L => R
• Cyanotic?
  
  • No
• Complications
  
  • Asymptomatic thru mid adult life
  • A-fib
• Murmur
  
  • Systolic ejection murmur: upper LSB
  • Persisten split of S2
• ECG findings
  
  • RV conduction delay
• Method of diagnosis
  
  • Echo

Question 109

Ventricular Septal Defect

• Type of shunt
• Cyanotic?
• Complications
• Murmur
• ECG findings
• Method of diagnosis

Answer 109

• Type of shunt
  
  • L => R
• Cyanotic?
  
  • No
• Complications
  
  • Infective endocarditis
  • Heart Failure
• Murmur
  
  • holosystolic murmur at lower LSB and apex
• ECG findings
  
  • LV enlargement
• Method of diagnosis
  
  • Echo and Doppler

Question 110

Patent Ductus Arteriosus

• Type of shunt
• Cyanotic?
• Complications
• Murmur

Answer 110

• Type of shunt
  
  • L => R
• Cyanotic?
  
  • No
• Complications
  
  • Infective endocarditis
  • LV failure
• Murmur
  
  • Machine murmur
  • Bounding pulse
  • Wide pulse pressure
    *

Question 111

Eisenmenger Syndrome

• Type of shunt
• Cyanotic?

Answer 111

• Type of shunt
  
  • R => L
  • previously L => R, but reversed due to pulm HTN
• Cyanotic?
  
  • Yes

Question 112

Coarctation of the Aorta

• Definition
• Presentation
• Consequences

Answer 112

• Definition
  
  • stenosis of aorta
  • No shunt or cyanosis
• Presentation
  
  • Upper body HTN
• Consequences
  
  • Aortic rupture or dissection
  • Heart Failure
  • Infective endocarditis
  • Cerebral hemorrhage

Question 113

Tetrology of Fallot

• Definition
• Presentation

Answer 113

• Definition
  
  • Pulmonary stenosis
  • VSD
  • Transposed aorta
  • RV hypertrophy
• Presentation
  
  • Cyanotic
  • Dyspnea
  • Squatting
    
    • increases systemic bp to force more blood into pulm circulation

Question 114

Ebstein’s Anomaly

• Definition
• Consequences

Answer 114

• Definition
  
  • Abnormal tricuspid valve (displaced into RV)
  • Pulm or aortic valve stenosis
• Consequences
  
  • May be asymptomatic until adulthood
  • (doesn’t describe consequences specifically)

Question 115

Transposition of the Great Vessels

• Consequence

Answer 115

Cyanosis

Must have other defect to serve as a shunt between the sides of the heart