cardiac assessment & conduction abnormalities

Question 1

review: what are the 3 layers of the heart

Answer 1

endocardium, myocardium, epicardium

Question 2

where does contractility occur in the heart

Answer 2

myocardium

Question 3

4 chambers of the heart

Answer 3

R atrium, R ventricle, L atrium, L ventricle

Question 4

atrioventricular valves (2)

Answer 4

tricuspid/mitral

Question 5

semilunar valves (2)

Answer 5

aortic/pulmonic

Question 6

what are valves connected to

Answer 6

cartilage connected to walls of heart via tendons

Question 7

coronary arteries

Answer 7

blood supply of heart
- starts at Aorta -> R coronary artery
- L main (widow maker) -> circumflex and Left anterior descending

Question 8

conduction of heart sequence

Answer 8

SA node -> AV node -> ventricles

Question 9

Review: depolarization

Answer 9

electrical activation of cell caused by influx of sodium into cell while potassium exits cell

Question 10

review: repolarization

Answer 10

return of cell to resting state caused by reentry of potassium into cell while sodium exits -> can’t depolarize again

Question 11

review: what are the 2 refractory periods

Answer 11

effective refractory period
relative refractory period

Question 12

effective refractory period

Answer 12

phase in which cells are incapable of depolarizing

Question 13

relative refractory period

Answer 13

phase in which cells require stronger-than-normal stimulus to depolarize

Question 14

how is a contraction formed

Answer 14

calcium IN -> mycocardial cells -> potassium OUT -> increases positive charge -> depolarizes cell -> allows for contraction

Question 15

healthy myocardial cells have what 6 properties

Answer 15

automaticity, excitability, conductivity, contractility, rhythmicity (pattern), refractoriness (no stimulus)

Question 16

___________/_________ maker potential changes based on location

Answer 16

automaticity/pace

Question 17

SA node

Answer 17

60-100 BPM (innervated by SNS/PNS to increase/decrease rate)
- ex: scared -> catecholamines -> increase HR -> PNS -> signal to slow down -> automaticity -> slower rate

Question 18

AV node

Answer 18

40-60

Question 19

Bundle of HIS

Answer 19

25-40
30-40

Question 20

Purkinje fibers

Answer 20

20-40

Question 21

what is the cardiac cycle

Answer 21

events that occur in heart from beginning of one heartbeat to next
- number of cycles depends on HR
- 3 major sequential events: diastole, atrial systole, ventricular systole

Question 22

diastole

Answer 22

start (relaxation)

Question 23

atrial systole

Answer 23

atria contract first -> blood intro ventricles -> Lub (S1)

Question 24

ventricular systole

Answer 24

ventricles with volume -> fill with blood -> aorta/pulmonic -> valves close -> Dub (S2)

Question 25

what is cardiac output

Answer 25

amount of blood pumped out of the L ventricle in L/min

Question 26

CO equation & normal amount

Answer 26

CO = SV x HR
- normal CO: 4-8L/min

Question 27

what is stroke volume

Answer 27

amount of blood ejected with each beat
- determined by L ventricle

Question 28

SV: preload?

Answer 28

degree of stretch of cardiac muscle fibers at end of diastole

Question 29

SV: afterload

Answer 29

resistance to ejection of blood from ventricle

Question 30

SV: contractility

Answer 30

ability of cardiac muscle to shorten in response to electrical impulse
- TIP: cardiac myocytes can squeeze/shorten if triggered by: calcium

Question 31

ejection fraction

Answer 31

percent of END DIASTOLIC VOLUME ejected from the L ventricle with each heart beat
- normal EF: 50-75%

TIP: R ventricle ejects blood -> Lungs. L ventricle stronger than R ventricle

Question 32

what are the 2 influencing factors of cardiac output

Answer 32

1) control of HR
2) control of SV

Question 33

how does HR affect CO (2)

Answer 33

1) autonomic nervous system: SNS (increases HR r/t increased catecholamines & excess thyroid hormone) /PNS (travels to vagus nerve to slow HR) -> changes in metabolic demand r/t stress, exercise, and illness = changes in CO
2) baroreceptor reflex (homeostasis): nervous system bundles (increase HR r/t blood pressure) -> accommodates changes in pressure by releasing discharge, transmitting impulses to medulla -> initiates PNS -> (elder) decrease HR and BP

TIP: opposite for hypotension = decrease baroreceptor -> increase BP/HR

Question 34

How does SV affect CO (preload? after load? contractility?)

Answer 34

augmented by catecholamines, SNS, medications
- preload: determined by volume status
- afterload: determined by vascular resistance
- contractility

Question 35

what is contractility decreased with? (5)

Answer 35

• hypoxia
• hypoxemia
• acidosis
• some drugs (beta-blockers - decrease contractility, NOT digoxin - increase contractility)
• viable heart muscle available, etc.

Question 36

assessment of cardiovascular system

Answer 36

(COLDSPA)
health hx (resp, cardiac, everything)
demographic information (environmental exposures)
family/genetic hx
cultural/social factors
risk factors: modifiable/non-modifiable

Question 37

what are modifiable risk factors for cardiovascular

Answer 37

lack of exercise
diet
obesity
high BP
lipid panels
blood glucose

Question 38

what are nonmodifiable risk factors for cardiovascular

Answer 38

age
family hx
sex (female/male)
ethnic background

Question 39

common sx of cardiovascular system (6)

Answer 39

• chest pain/discomfort
• pain/discomfort in other areas of the upper body
• SOB/dyspnea
• peripheral edema, wt. gain, abd distentino
• palpitations (sometimes)
• unusual fatigue, dizziness, syncope, change in LOC = decrease CO = decrease BF = brain

Question 40

past health, family, and social hx (8) considerations

Answer 40

• medications
• nutrition
• elimination
• activity/exercise
• sleep, rest
• self perception/self concept
• roles and relationships
• coping and stress

Question 41

physical assessment considerations (7)

Answer 41

• general appearance (pale? ashen? diaphoretic? temperature change?)
• skin and extremities (lack perfusion? bruising?)
• BP, othrostatic changes (15-30 seconds, teach slow movements)
• arterial pulses (radial, femoral, DP/PT, carotid)
• Jugular vein pulsations
• HR, inspection, palpation, auscultation
• assessment of other systems

TIP: good central pulse =/= BP

Question 42

lab tests for cardiovascular

Answer 42

• cardiac biomarkers (troponin HIGH SENSITIVITY, creatine kinase and CK-MB)
• blood chemistry, hematology, coagulation (electrolytes, renal function - contrast)
• brain (B-type- natriuretic peptide (BNP)
• lipid profile: cholesterol (total: <200, HDL-good >60, LDL-bad <100, triglycerides <150)

Question 43

describe troponin high sensitivity

Answer 43

• sustains cardiac injury
• guides interventions
• myocardial injury (heart attack) -> body releases troponin (cardiac biomarker) -> decreases blood flow to heart
• (muscle break down of the heart) or (heart mnucle injury)

Question 44

describe BNP

Answer 44

• chest tightness
• released when there is cardiac muscle stretch
• key indicator for HEART FAILURE
  ex: CHF: ventricles stretch d/t increased volume -> increase BNP

Question 45

electrocardiography (describe)

Answer 45

12 lead (one point in time, tells us cardiac damage) vs. continuous (hardwire or ambulatory monitoring - heart monitor)
- identifies RATE and RHYTHM
- useful for identifying ST elevation

Question 46

what do leads determine

Answer 46

waveforms
- split into 4 sections of 3 seconds (12 total) - 6 seconds on exam (2 sections)

Question 47

cardiac stress test (type (2), patient instruction, meds)

Answer 47

• exercise stress test
• pharmacologic stress test
• pt. instructed to AVOID stimulants pre-procedure (coffee, smoking)
• beta blockers, ca channel blockers, or other rate control drugs may be held (allow us to see more information about heart function)

Question 48

describe exercise stress test

Answer 48

• pt. walks on treadmill with intensity progressing according to protocols
• ECG, echo, VS, symptoms monitored (chest pain? SOB?)
• terminated when target HR is achieved
• if chest pain or 150 HR = patient FAILED

Question 49

describe pharmacologic stress test (what, meds?)

Answer 49

• agents given to mimic exercise if patient cannot handle actual test -> physical impair
• dobutamine - synthetic sympathomimetic drug

Question 50

describer ECHO (echocardiography)

Answer 50

(GOLD STANDARD FOR CARDIAC TEST, q6 months outpatient)
largely noninvasive US test that is used to
- measure ejection fraction
- examine size, shape, and motion of cardiac structures
- identifies valve disease
- easy to perform
most common: transthoracic - against chest wall, tranesophageal (TEE) - same but in esophagus

Question 51

describe cardiac catheterization (what, Left, right)

Answer 51

• what: invasive procedure used to diagnose (and treat) structural and functional diseases of the heart and great vessels (ex: coronary ds.)
• right heart Cath: pulmonary artery pressure and oxygen saturations may be obtained, biopsy of myocardial tissue may be obtained
• left heart Cath: involves CONTRAST, identifies blockages that can be treated via percutaneous coronary intervention (PCI) - diseased arteries are “ballooned” and stented with specialized catheters (keep vessels open)
• usually use femoral artery or radial artery
• if thin blood -> sheath stays in vessel (one way valve, water tight seal)

Question 52

nursing care post Cath (8)

Answer 52

• observe Cath site for bleeding, hematoma (MOST IMPORTANT)
• assess peripheral pulses
• evaluate temp, color, cap refill of affected extremities
• screen for dysrhythmias
• maintain BR for 2-6 hours
• instruct patient to report chest pain, bleeding
• monitor for contrast induced nephropathy
• ensure patient safety (Manual pressure Q30 min post Cath)

Question 53

dysrhythmias (what, irregularities, concerns, diagnosed)

Answer 53

disorders of formation/conduction (or both) of electrical impulses within heart
- irregularities in: rate, rhythm, or both
- concerning when the alter blood flow and hemodynamics (change BP)
- diagnosed by: ECG waveforms (patient goes in and out rhythm (continuous/12lead)

Question 54

2 types of dysrhythmias

Answer 54

atrial
ventricular

Question 55

atrial dysrhythmias type 3

Answer 55

premature atrial complex
atrial flutter
atrial fibrillation

Question 56

ventricular dysrhythmias

Answer 56

premature ventricular complex
ventricular tachycardia
ventricular fibrillation
ventricular asystole

Question 57

normal conduction pathway

Answer 57

SA node
AV node
bundle of HIS
right and left bundle branches
purkinje fibers
- depolarization: stimulation (contraction) = systole
- repolarization: relaxation = diastole

Question 58

components of telemetry (3)

Answer 58

electrodes
apply electrodes
5 lead wire system

Question 59

describe electrodes

Answer 59

• disposable disks consisting an adhesive ring with a conductive substance in the center
• conductive media conducts skin surface voltage changes through color coded wires

Question 60

apply electrodes

Answer 60

• apply on dry skin (no alcohol)
• remove dead/dry skin before application with rough paper or cloth
• clip hair
• place on skin over areas with minimal muscle activity to avoid artifact
• change as needed or daily
• change batteries for portable monitors as needed

Question 61

describe 5 lead wire system

Answer 61

• most common set up in acute & critical care
• white, black, and red electrodes are located in identical positions to the 3 lead set
• green electrode is located opposite the red electrode
• brown precordial lead V1 is located to the right of the sternal border at the 4th intercostal space
• precordial vectors may be moved to translate different sections of the heart

Question 62

what is P wave

Answer 62

atrial depolarization

Question 63

what is QRS complex

Answer 63

ventricular depolarization

Question 64

what is t wave

Answer 64

ventricular repolarization

Question 65

ECG analysis

Answer 65

heart rhythm & rate
P wave evaluation
PR interval evaluation
QRS evaluation
QT interval evaluation

step 1: rhythm?
step 2: rate? - calculate heartbeat by 6 second method (count # QRS in 6 sec, multiple by 10)

Question 66

what to do after rate?

Answer 66

atrial conduction
- are p waves present
- p waves per QRS?
- p waves before QRS?
- shape of p wave? do they look alike (if not = issues)
- more p waves than QRS? (1:1 ratio)

Question 67

what happens if ectopic beats

Answer 67

• ask if there are abnormal shaped P waves in relationship to these beats? SA node fire independently? extra beats
• are the p waves buried? no av blocks

Question 68

describe AV conduction

Answer 68

allows for atrial kicks - maximize for filling ventricle
- is PR interval normal? 0.12-0.20 (atrial kick)
- are PR intervals the same?
- if PR intervals different, is there a pattern? (specific to AV blocks)

Question 69

describe ventricular conduction

Answer 69

• ORS complexes normal? 0.06-0.12
• QRS complexes of same duration (1 QRS/ p wave)
• QRS complexes look the same?

Question 70

describe QT intervals

Answer 70

• looking for elevation or depression
• timing can be prolonged with drugs (antipsychotics, abx, zofran = taken all together)
• longer -> longer refractory periods -> dangerous arrhythmias

Question 71

normal sinus rhythm

Answer 71

• rate: 60-100 bpm
• normal PR interval
• normal QRS
• 1 P wave for every QRS complex (t wave)

Question 72

sinus Brady

Answer 72

• rhythm: regular (slow)
• rate: <60 bpm
• normal p wave, preceding each QRS
• normal PR, QRS interval, T wave, QT interval

Question 73

clinical considerations for sinus Brady(3)

Answer 73

signs of poor perfusion:
- low BP, decreased LOC, dizziness, syncope, chest pain, dyspnea
possible causes:
- cardiac ischemia, HR slowing meds (digoxin, beta blockers, ca channel blockers, antiarrhythmics like amirodarone and betapace)
non cardiac disorders:
- electrolyte imbalance (hyperkalemia), vagal responses, hypothermia, hypothyroid

Question 74

treatment for sinus Brady

Answer 74

• asses ABC’s
• assess VS, IV patency
• Administer O2
• transcutaneous external pacemaker (sedate: can change rate, painful) (send electrical impulse to heart)
• IV dopamine got 2-10 mcg/min (1mg in 500 ml 0.9 NS @ 1-5 ml/min)
• atropine (0.5-1.0 mg every 3-5 minutes to a total of 0.4 mg/kg)

tip: not uncommon for athletes to have slow HR, tx is reserved for sx., SB that occurs with sleep is not abnormal

Question 75

sinus tachycardia

Answer 75

• rhythm: regular atrial and ventricular
• rate: >100 bpm
• P waves for of normal size and shape preceding QRS, may be superimposed on preceding t wave with increasing HR
• PR intervals, ORS complex, T waves normal
• OT interval usually shortens

Question 76

clinical significance of sinus tachycardia (what, assess?, causes, presence of?, tx?)

Answer 76

• decreases cardiac output by REDUCING DIASTOLE (increase myocardial O2 demand in unhealthy heart)
• assess: ABCs, VS, chest pain, dyspnea, palpitations
• causes: hypovolemia, pain, anxiety, physiologic stress (eg. infection, sepsis, anemia, shock states), fever (anything that stimulates SNS)
• presence of stimulants (caffeine, nicotine, amphetamines, OTC dugs, illicit drugs)
• tx: treat underlying cause if possible (consider slowing HR w/ beta blockers, calcium channel blockers, be careful d/t compensatory mechanisms) (provide reassurance and reduce fear and anxiety if possible)

Question 77

describe sinus arrhythmia

Answer 77

• GAP
• irregularity

Question 78

electrocardiography atrial rhythms (PACs)

Answer 78

• extra beats originating in the atria
• conducted (rhythm -> QRS)/ non-conducted (extra P wave) PACs
• pathway matters: how do we know if it comes from a different pathway (clue = ds)
• look at causes: ICU pt may have more PACs than other pts (will increase OT)

TIP: extra P wave, quite common

Question 79

describe atrial fibrillation (rate, what, effects)

Answer 79

• atrial rate of 350-600 times/minute of disorganized chaotic stimulus
• AV node acts as a buffer zone to the ventricles
• coordinated atrial emptying during diastole is IMPAIRED
• effects include: loss of atrial kick (decrease CO 30%), pooling and clotting of blood in atria (subsequent thromboembolism, strokes)

Question 80

diagnostic characteristics of atrial fibrillation (rhythm, rate, pqrst complex)

Answer 80

• rhythm: irregularly irregular
• atrial rate: indiscernible; often >400/min
• ventricular rate: <100 - 150/min (regular if given meds, tachycardic with meds = RVR (rapid ventricular response)
• P waves absent, PR internal indiscernible
• QRS complex <0.12 sec., T wave and QT interval indiscernible

Question 81

risk factors for AFIB

Answer 81

• HTN
• advancing age
• dilated L atrium
• Valve disease (aortic or mitral)
• coronary artery disease
• elevated glucose (uncontrolled)
• thyroid disease (typically hyper, but also hypo)

Question 82

complications r/t AFIB (3)

Answer 82

• loss of ventricular regulation (too much impulse going towards AV node can cause “rapid ventricular response” RVR, rates exceed normal SR & diminish diastolic filling (decrease SV), tx with rate/rhythm control drugs: beta, calcium, amiodarone)
• loss of coordinated emptying (tx with DOACs (perdaxa, eliquis) or heparin IV (quicker)
• loss of atrial systole (30% CO)

Question 83

rate/rhythm control in afib (meds) (3)

Answer 83

amiodarone (anti arrhythmic): brings back to SR
diltiazem (calcium channel blocker): control rate (decrease ventricular response)
verapamil (calcium channel blocker: control rate (ventricular response)
- sometimes beta blocker to reduce sympathetic stimulation of the heart (metoprolol)

Question 84

stroke preventions in afib (CHA2DS2VASc)

Answer 84

(higher score = more aggressive with anticoagulation)
CHA2DS2VASc scoring system
- C = congestive heart failure
- H = HTN
- A2 = age 75
- D = diabetes
- S2 = stroke
- v = vascular disease
- A = age 65
- Sc = sex category (female)

Question 85

score risk recommendation for LT anticoagulation

Answer 85

0 = 1.9% adjusted stroke risk (no therapy indicated)
1 = intermediate (anticoagulation recommended risk vs. benefit discussed with patient, ASA strongly advised at least)
2 or more (3 for women) = anticoagulation highly recommended, high (CHA2Ds2VASc) or intermediate (CHADS2 classic), DOAC unless there are reasons to avoid it OR Coumadin if valvular disease present

Question 86

DOAC vs warfarin

Answer 86

warfarin
- slow onset
- variable dosing
- vitamin K affect
- many drug interactions
- requires monitoring
- offset is long
DOAC (apixiban (eliquis), dabigatran (pradaxa), rivaroxaban (xarelto)
- rapid onset
- fixed dosing
- no food affect
- few drug interactions
- no monitoring
- offset is shorter

Question 87

afib treatment (4)

Answer 87

1) electrical cardioversion (resets heart rhythm)
- must be on anticoagulation for a minimum 4 wks, with a TEE to r/o clot
2) catheter ablation therapy (similar invasiveness to cardiac Cath)
3) cox maze procedures (requires open heart approach)
4) left atrial appendage occlusion (watchman device) - not candidate for blood thinners, mesh net that sit in atria

Question 88

atrial flutter (rate, pqrst)

Answer 88

• atrial rate: 200-400 bpm, will be treated than ventricular rate (organized atrial rhythm)
• abnormal p waves referred to as flutter or “saw tooth waves”
• QRS complex will usually be normal
• PR interval: atrial regular, ventricular irregular
• QT: indiscernible

tip: atria tries to stimulate AV node, another impulse fills atria

Question 89

aflutter mangement (4) depends on?

Answer 89

• dependent on ventricular response rate
• pharmacologic cardioversion: (ibutilide, sotalol, procainamide, amiodarone)
• pharmacologic rate control: (calcium channel blockers, beta blockers, digoxin)
• non pharm interventions: cardioversion (electrical), overdrive atrial pacing (set atrial higher, slowly bring down)
• permanent termination: radiofrequency ablation

Question 90

ventricular arrhythmias

Answer 90

PVCs
Vtach
Vfib
Asystole
blocks (not on exam)

Question 91

premature ventricular contractions (PVCs) where, pqrst, tx)

Answer 91

• originate in ventricles below bundle of HIS from different pathway
• P waves absent d/t no atrial depolarization
• T waves and QRS complexes deflect in opposite directions
• QRS complex is wider than normal
• can be normal with no tx or a warning of ventricular irritability

tip: random contractions decrease AV node, no stimulations

Question 92

managing PVCs (tx)

Answer 92

• assess need for tx
• assess for sx
• treat cause: assess for electrolytes, drugs that cause ventricular ectopy
• pharmacologic management: beta blockers to reduce sympathetic stimulation, antidysrhythymic drugs

Question 93

ventricular tachycardia (VT) (what, rhythm?, rate?, pqrst?)

Answer 93

• 3 or more PVCs in row
• unable to determine atrial rhythm; ventricular rate >100/min
• ventricular rhythm may or may not be regular
• no p waves and unmeasurable PR intervals
• QRS complex is wide and bizarre with T wave in the opposite direction (varies but usually)

Question 94

Vtach management (stable, unstable, pulseless)

Answer 94

dependent upon patient condition
- pulseless VT: life threatening; unsynchronized defibrillation
- unstable VT: electrical cardioversion (AED)
- stable VT: no loss of cardiac output, amiodarone or what? talk, slight palpitation

Question 95

ventricular fibrillation (what, management)

Answer 95

life threatening (no contraction at all, no CO)
- mangement: defibrillation, cardiopulmonary resuscitation

Question 96

ventricular fibrillation diagnostics

Answer 96

• chaotic rhythm
• rate: indeterminate
• no p waves, immeasurable PR
• indiscernible t waves
• waveform may appear as a wavy baseline
• this is one of the PRIMARY LETHAL ARRHYTHMIAS

Question 97

clinical significance of VT/VF (stable, unstable, pulseless)

Answer 97

• stable patients in VT may convert with Amiodarone 150 mg over 10 minutes
• unstable patients in VT require cardioversion
• unresponsive patients in VT require defibrillation
• in vfib, ventricles are quivering instead of contracting reducing CO to ZERO
• ABCs are of VITAL important (check pt responsiveness, defibrillate/AED if pt. is pulseless, CPR until defibrillator arrives)

Question 98

asystole (what, evidence, pqrst, etiology)

Answer 98

• cardiac standstill or total absence of ventricular electrical activity
• evidenced clinically by no pulse or CO
• no QRS seen on monitor
• caused by: ischemia, hypoxia, drug OD, electrolyte disturbances, traumatic arrest
• think about cause as much as treatment (tx with CPR and EPI 1 mg every 2-5 min)

Question 99

pacemakers (types, indication)

Answer 99

3 common types: transcutaneous, transvenous, permanent/implanted (can include automated internal cardiac defibrillator AICD)
- indicated for unstable Brady arrhythmias (open heart surgery)

Question 100

external pacing (transcutaneous) pacemaker

Answer 100

• electrodes placed on chest delivers impulses through chest wall
• chest wall impedance often causes great discomfort or inability to capture
• location: right upper, left lower, anterior/posterior

Question 101

internal/implanted pacer

Answer 101

consists of:
- generator/battery
- pacing leads (stay in place forever)
- somtimes a defibrillator lead (automatic)
- outpatient procedure (battery change)

Question 102

3 functions of pacemakers

Answer 102

1) firing or pacing: pacer delivers impulses per programmed rate. seen on monitor by observable spike followed by p wave (f atria stimulated) or QRS (ventricle is target chamber)
- may prolong QRS
- why would we want atrial lead? atrial kick back
2) capture target chamber: successfully depolarizes the target chamber (atria or ventricle) as evidenced by monitor by a p wave or QRS after the spike
- if new pacemaker and no capture, turn pt on L side (make pacers float in vent)
3) sensing: pacers ability to recognize presence of absence of intrinsic electrical activity. (if too sensitive) it will recognize inappropriate internal activity (such as skeletal muscle depolarization) and not fire when necessary (not sensitive) it won’t recognize intrinsic activity and fire on top of one’s own electrical stimulations

Question 103

automated internal cardiac defib (AICD) (what, indicated, in conjunction with)

Answer 103

• allows for detection and termination of life threatening arrhythmias
• indicated for: post MI w/ severe LV dysfunction, EF less than or equal to 35%, non ischemic dilated cardiomyopathy w/ low EF
• usually in conjunction with anti-arrhythmic meds to minimize risk of electrical discharge

Question 104

key interventions for arrhythmias (9)

Answer 104

• assess for chest pain
• evaluate rhythm
• assess and monitor cardiovascular status
• complete assessment of peripheral circulation
• monitor VS frequently
• evaluate client’s response to dysrhythmias
• monitor appropriate lab tests (lytes, mg/phos/ca/k, cardiac enzymes (trop vs BNP)
• administer anti-arrhytmics
• promote stress reduction