Cardio cram

Question 1

Syndromes associated with ASD

Answer 1

Holt Oram
Fetal alcohol syndrome

Question 2

Widely split fixed S2
ESM left upper sternal border
Mid-diastolic rumble
Mild RVH or RBBB

Answer 2

= ASD
- ESM (relative PS) and mid-diastolic rumble (relative TS)
Primum ASD = superior axis
Secundum ASD = RAD

Question 3

Syndromes associated with VSD

Answer 3

T21
DiGeorge
Turner

Question 4

Holosystolic murmur LLSB +/- thrill
Apical mid-diastolic murmur
Early decrescendo murmur
LVH or LAH

Answer 4

= VSD
- Early decrescendo murmur (AR with infundibular VSD)
- outlet associated with aortic insufficiency/LVOT
LVH -> LAH -> RVH
BVH if large shunt

Question 5

Syndromes associated with AVSD

Answer 5

T21

Question 6

Apical holosystolic murmur
Superior axis
RVH or RBBB
Prolonged PR interval

Answer 6

= AVSD

Question 7

Syndromes associated with PDA?

Answer 7

Maternal rubella
Prematurity

Question 8

Bounding pulses, wide pulse pressure, hyperactive praecordium
Continuous machinery murmur
LVH or LAH

Answer 8

= PDA

Question 9

Systolic murmur LUSB, mid-diastolic rumble, RVH or RBBB (or normal ECG)

Answer 9

= PAPVR

Question 10

Syndromes associated with pulmonary stenosis

Answer 10

Rubella = PS and PPS
Alagille = PPS
Williams = PPS
Noonan = dysplastic PV

Question 11

ESM LUSB radiating to back
A2 and P2 widely split
Prominent a wave
RAD, RAH and RVH strain

Answer 11

Pulmonary stenosis

Question 12

Syndromes associated with aortic stenosis

Answer 12

Supravalvular - Williams, familial hyperchol
Valvular - Turner (bicuspid AV)

Question 13

Harsh ESM RUSB
Early decrescendo LLSB
S2 splits normally or narrowly
LVH with strain

Answer 13

Aortic stenosis

Question 14

Syndromes associated with coarctation

Answer 14

Turner
Kabuki
PHACES

Question 15

Single S2, S3 gallop, reduced femoral pulses
Nonspecific ejection systolic
Low post ductal sats
Normal or RAD
RVH and RBBB, progresses to LVH by 2 years

Answer 15

= coarctation of the aorta

Question 16

Inter AA

Answer 16

Extreme form of CoA in which the aortic arch is atretic or a segment of the arch is absent

Question 17

Load S1 at apex, narrow split S2, low frequency mid-diastolic rumble
LAH, RVH +/- LAD

Answer 17

= MS
May have opening snap (rheumatic)
LAD associated with pulmonary hypertension

Question 18

Syndrome associated with MR

Answer 18

MPS (Hurler) - most common cardiac lesion
Most common murmur in KD and ARF

Question 19

S1 normal/reduced, loud S3, pansystolic murmur at apex
LVH +/- LAH, ECG can also be normal

Answer 19

= MR
Loud S3 due to increased blood flow across MV
May have apical mid-diastolic murmur of relative TS

Question 20

Syndromes associated with mitral valve prolapse?

Answer 20

Marfan
EDS
OI
Stickler
PCKD (adults)
Klinefelter

Question 21

Mid-systolic click +/- late systolic murmur
Enhanced by expiration
May have 1st degree AV block

Answer 21

= mitral valve prolapse

Question 22

Syndromes associated with aortic regurgitation?

Answer 22

Overall rare, but associated with dilated aortic root (Marfan, EDS)
MPS (Hurler)

Question 23

High pitched diastolic decrescendo murmur at LLSB, hyperdynamic praecordium, bounding pulse, wide pulse pressure
LVH if severe

Answer 23

Aortic regurgitation

Question 24

Conditions associated with TOF?

Answer 24

22q11
T21
Alagille

Question 25

Harsh ESM, systolic thrill, continuous murmur, single S2
RAD, RAH, RVH

Answer 25

= TOF
ESM - right ventricle outlet obstruction
Continuous murmur - PDA
Single S2 - pulmonary component not audible

Question 26

Variations of TOF

Answer 26

TOF + PA: usually no murmur, S1 ejection click, S2 loud and single
TOF + absent PV: PS and PR ‘to and fro’ murmur

Question 27

Conditions associated with tricuspid atresia

Answer 27

Pulmonary stenosis
TGA - common!!!
Coarctation

Question 28

Cyanosis, single S2, LV impulse, holosystolic murmur LLSB
Superior axis, RAH +/- LAH, LVH

Answer 28

= TA
VSD causing holosystolic murmur LLSB is most common

Question 29

Conditions associated with Ebstein anomaly

Answer 29

Maternal lithium use
Cardiac associations - PS, PA, TOF, VSD

Question 30

Mild to severe cyanosis, quadruple rhythm (split S1, S3 and S4), holosystolic or early systolic murmur of TR at LLSB, hepatomegaly
Superior axis, RBBB, RAH, 1st degree AV block, WPW

Answer 30

= Ebstein anomaly
May also have SVT/other atrial tachycardias

Question 31

Cyanosis, single and loud S2, usually no murmur (but can be present)
Upright T wave in V1

Answer 31

= dTGA
Can have VSD holosystolic murmur or outflow tract murmur
May have BVH, RAH or LAH on ECG

Question 32

L-TGA associated with what conditions?

Answer 32

VSD = 80%
PS = 50%
TR = 40%
Dextrocardia in 50%

Question 33

Absence of q waves in V5/6, presence of Q waves in V1, upright T waves across praecordium, varying AV block, atrial arrhythmia +/- WPW

Answer 33

= L-TGA

Question 34

Hyperactive RV impulse, widely split S2, systolic murmur LUSB, mid-diastolic murmur LLSB
RV overload (rsR’ in V1) and RVH

Answer 34

= TAPVR (without obstruction)

Question 35

Cyanosis, marked tachypnoea, single S2, gallop rhythm, no murmur, pulmonary crackles, hepatomegaly
RAD, RVH

Answer 35

= TAPVR (with obstruction)

Question 36

Associations with truncus arteriosus

Answer 36

22q11 (30%)
VSD always present, with complete mixing
May also have coronary artery abnormality or interrupted aortic arch/right aortic arch

Question 37

Varying cyanosis, hyperactive praecordium, single S2, ejection systolic click LUSB, systolic murmur
BVH in majority +/- LAH

Answer 37

= truncus arteriosus
Can have varying signs of CHF
Systolic murmur due to VSD

Question 38

Associations with double inlet left ventricle

Answer 38

TGA 85%
PS/PA 50%

Question 39

Associations with hypoplastic left heart?

Answer 39

Turner
T18, T13
Jacobson’s syndrome
22q11
Cardiac - ASD/PFO, VSD, coarctation (75%)
CNS abnormalities in 30%

Question 40

Shock and acidosis, pulses weak/absent, loud and single S2, no murmur, grey colour
RVH

Answer 40

= hypoplastic left heart

Question 41

5 most common cyanotic lesions

Answer 41

1. Truncus arteriosus
2. TGA
3. Tricuspid atresia
4. TOF (most common)
5. TAPVR

Question 42

DDx for cyanosis and respiratory distress

Answer 42

= increased pulmonary blood flow: TGA, truncus arteriosus, obstructed TAPVR

Question 43

DDx for cyanosis without respiratory distress

Answer 43

= reduced pulmonary blood flow: TA, Ebstein, PA, PS, TOF

Question 44

Lesions presenting with shock

Answer 44

Hypoplastic left heart
Critical AS
Critical CoA
Interrupted aortic arch

Question 45

Lesions presenting with very early cyanosis?

Answer 45

TGA
Pulmonary atresia
Ebstein malformation

Question 46

Lesions associated with respiratory distress

Answer 46

At birth - truncus arteriosus, TAPVR, PDA in preterm infants
At 6 weeks - VSD, PDA

Question 47

Causes of single S2 related to abnormal valve position

Answer 47

Truncus arteriosus
TOF
Tricuspid atresia
HLH
TGA
L-TGA

Question 48

Causes of single S2 related to abnormal valve

Answer 48

Severe AS/PS/aortic atresia
PA
Eisenmenger
Large VSD

Question 49

Other causes of single S2

Answer 49

Pulmonary hypertension

Question 50

Characteristics of TOF

Answer 50

1. Large VSD
2. RVOT/PS (subvalvular)
3. Overriding aorta
4. RVH

Question 51

Characteristics of TA

Answer 51

Tricuspid valve absent - no connection between RA and RV, hypoplastic RV
Requires inter-atrial communication, systemic blood flow to cross to LA via ASD or PFO

Question 52

Characteristics of PA and intact ventricular septum

Answer 52

Absent PV - majority have a diaphragm like membrane PV
Inter-atrial communication required for systemic blood flow

Question 53

Characteristics of Ebstein anomaly

Answer 53

Downward displacement of TV into RV cavity - atrialised RV, hypoplasia of RV
Inter-atrial communication always present (PFO, ASD)

Question 54

Characteristics of D-TGA?

Answer 54

Aorta is located anterior and to the right of the PA (dextro = ‘d’)
Requires mixing lesion

Question 55

Characteristics of L-TGA?

Answer 55

Congenitally adjusted TGA:
RA -> LV -> PA
LA -> RV -> aorta
(i.e. wrong ventricles but blood moving the direction it should)

Question 56

Characteristics of TAPVR

Answer 56

No direct communication between PV and LA
PV drain to alternative sites:
supra cardiac 50%
infra cardiac 20%
cardiac 20%
mixed 10%
ASD/PFO required for survival

Question 57

Characteristics of truncus arteriosus?

Answer 57

Common PA and aorta (single arterial trunk)
VSD always present
Complete mixing of ventricles

Question 58

Characteristics of double inlet left ventricle (single ventricle)

Answer 58

Both AV valves connected to a main, single chamber
Main chamber connected to a rudimentary chamber via the BVF
One great artery arises from each chamber

Question 59

Characteristics of hypoplastic left heart syndrome

Answer 59

1. Hypoplasia of LV - completely non-functional
2. Atresia or critical stenosis of AV/MV
3. Hypoplasia of ascending aorta and aortic arch

Question 60

Indications for Fontan procedure

Answer 60

Dominant RV - HLHS
Dominant LV - DILV, PA and intact VSD, tricuspid atresia
Other - unbalanced AVSD, complicated DORV

Question 60

Indications for Fontan procedure

Answer 60

Dominant RV - HLHS
Dominant LV - DILV, PA and intact VSD, tricuspid atresia
Other - unbalanced AVSD, complicated DORV

Question 61

Phase 0 of cardiac action potential

Answer 61

Contractile cells are depolarised to threshold potential by the influx of Na and K through gap junctions.
When threshold potential is reached (-70mV) sodium channels open to allow rapid depolarisation through influx of sodium into cell

Question 62

Phase 1 of cardiac action potential

Answer 62

Sodium channels begin to close, therefore reduced influx of sodium
Rapid open and closure of potassium channels, allows efflux of potassium
Combined effect = brief depolarisation of the cell

Question 63

Phase 2 of cardiac action potential

Answer 63

Potassium channels open again allowing efflux of potassium from the cell
L-type calcium channels (activated by Na in phase 0) allow influx of calcium ions
Depolarising potassium is electrically balanced by depolarising calcium and tapering sodium currents, results in a plateau (distinguishes cardiac AP from nerve and skeletal muscle)
Influx of calcium triggers calcium release from sarcoplasmic reticulum, the intracellular calcium is responsible for cardiac myocyte contraction

Question 64

Phase 3 of cardiac action potential

Answer 64

Rapid depolarisation occurs through closure of L-type calcium channels whilst potassium channels remain open, allowing more potassium to leave the cell and resulting in a net negative current
Potassium channels close when membrane potential is restored to -85-90mV.
Ionic pumps restore concentrations to levels from prior to AP

Question 65

Phase 4 of cardiac action potential

Answer 65

Resting membrane potential of -90mV maintained through ionic pumps until stimulated to threshold potential.