EKG 6

Question 1

Causes of arrhymias

Answer 1

. Anatomical variation
. Altered ANS activity (altered sinus rhythms)
. Electrolyte disturbances (altered K or Ca)
. Drugs
. Myocardial ischemia

Question 2

Myocardial ischemia consequences

Answer 2

. Infarcts

. Injured tissue (inadequate O2)

Question 3

Depolarization in injured tissue

Answer 3

. Due to accumulation of K in the extracellular spaced

. Depolarized cells do not conduct as rapidly due to voltage inactivation of Na channels

Question 4

Injury currents

Answer 4

. Currents flow btw depolarized and non-depolarized regions

. May result in ectopic foci developing

Question 5

Ischemia in relation to dispersion of refractory periods

Answer 5

. Ischemia opens specific K channels leading to early repolarization in affected area
. Shorter AP duration is responsible for a shorter refractory period
. Regions w/ differing degrees of ischemia will have differing refractory periods

Question 6

ATP-sensitive K channels (IKatp channels) in relation to ischemia

Answer 6

. Inhibited by physiological conc. Of intracellular ATP so they are largely closed
. Open during ischemia
. Shortens AP duration which results in reduced Ca entry during the plateau
. Contractility is reduced in ischemia region and ATP is spared
. Reduces likelihood of irreversible damage to the cardiac myocytes in the ischemic area
. Shortened APs lead to arrhythmias

Question 7

Accumulation of toxic metabolites during ischemia

Answer 7

. Cell membranes breakdown during ischemia
. Causes accumulation of phospholipid metabolites
. Block many channels and open some
. Cause altered conduction
. Can also cause spontaneous depolarization which can lead to ectopic foci

Question 8

Reentry

Answer 8

. Single incoming electrical impulse causes more than 1 depolarization of the same cell or region due to re-excitation
. Occurs due to shortening the refractory period or slowing conduction

Question 9

Altered sinus rhythms

Answer 9

. Originating in SA node
. Tachycardia or bradycardia
. P waves, QRS complex, and T waves are all present and relatively normal

Question 10

Sinus block

Answer 10

. 1+ sinus impulses fails to initiate cardiac cycle (P wave, QRS, and T wave are all missing)
. Atria fail to depolarize bc the SA node fails to depolarize it, the SA node depolarized but the wave fails to exit node, or the SA node depolarized but the impulse fails to stimulate atria bc impulse is weaker than normal or atria tissue doesn’t respond

Question 11

Incomplete sinus block

Answer 11

. Occasional dysfunction in which one (common) or 2 cycles is missing
. Pause is a multiple of normal P-P period
. Causes: digitalis toxicity, carotid sinus massage, ischemia

Question 12

Supraventricular Tachycardia

Answer 12

. Originates above ventricles in SA node, atrial, or AV node
. Lumped together as SVT bc it is hard to distinguish
. P waves not clearly seen at higher HRs

Question 13

Paroxysmal SVT

Answer 13

. Appears suddenly and ends suddenly
. Precipitated by premature atrial complex which causes reentry
. Symptoms: lightheadedness and palpitations
. Well tolerated as long as rate is less than 190
. Older people can get angina and infarcts from it

Question 14

Junctional tachycardias

Answer 14

. Subset of supraventiruclar tachycardias
. Arise from AV junction
. QS and T waves normal
. Other have no P wave or P wave can come after QRS
. Seen to be inverted in Lead II if present in normal space

Question 15

Atrial flutter

Answer 15

. Originates from ectopic pacemaker or reentry circuit in atria
. Get saw tooth pattern
. Waves occur at 250-350/min
. Accompanying QRS complexes and T waves occurring at lower rate

Question 16

Atrial fibrillation

Answer 16

. Similar to flutter but modified P waves are smaller in amplitude and occur at rates over 350/min
. Uncoordinated electrical activity at extremely high rates
. Leads to uncoordinated mechanical activity

Question 17

What are the most common atria-ventricular dysrhythmia?

Answer 17

. AV conduction block

Question 18

First degree AV block

Answer 18

. Prolonged PR interval
. 1 P wave for every QRS
. Looks relatively normally, need to measure PR interval to determine

Question 19

Second degree A block

Answer 19

. Partial dissociation of atria and ventricles
. Not every P wave is followed by QRS
. Wenckebach Phenomenon: gradually inc. PR interval until finally P wave isn’t followed by QRS, then cycle repeats
. Mobitz Type II: PR interval constant, some P waves not followed by QRS (2:1, 3:1)

Question 20

Third degree AV block

Answer 20

. Complete dissociation of atria and ventricles
.P and QRS are totally independent of one another
. Complete heart block
. Secondary pacemaker takes over
. Requires an artificial pacemaker

Question 21

Premature ventricular complexes

Answer 21

. Extra QRS dur to abnormal depolarization of ventricles primer to arrival of normal impulse
. Caused by ectopic focus or reentry in ventricles
. Extra QRS are accompanied by contraction (extrasystoles)
. Early contraction weaker than normal that’s followed by compensatory pause since cells are in refractory period when normal SA impulse arrives
. Leads to skipped beat
. Compensatory pause followed by stronger than normal contraction
. Occur at low frequency in normal person

Question 22

Wolff-Parkinson-White syndrome

Answer 22

. Caused by 2nd conduction pathway btw atria and ventricles
. known as Pre-excitation
. Conduction through pathway faster than AV node so ventricles depolarized sooner than normal
. Causes short PR interval and wide QRS w/ initial hump (delta wave)
. Occurs bc QRS complex is generated by 2 waves of depolarization (first through aberrant pathway, 2nd through normal pathway)

Question 23

Ventricular Tachycardias

Answer 23

. Abnormally high rate caused by ectopic focus or reentry in ventricles
. QRS complexes unusual
. P and T waves obscured
. Precede ventricular flutter and fibrillation bc ventricles don’t fill well and heart pumps less efficiently at high rate
. O2 requirement inc. due to inc. work causing myocardial ischemia

Question 24

Ectopic focus

Answer 24

. Pacemaker other than normal pacemaker
. One that fires occasionally may lead to individual complexes
. Ones that fire repeatedly and faster than rate of firing of SA node will drive other cells, result in tachycardias

Question 25

Torsades de Pointes

Answer 25

. Ventricular tachycardia w/ unique appearance

Question 26

Ventricular flutter

Answer 26

. Very rapid tachycardia which usually progressed to fibrillation due to ischemia
. QRS complexes themselves don’t inc. or dec. in amplitude to same degree as Torsades

Question 27

Ventricular fibrillation

Answer 27

. Uncoordinated electrical activity of ventricles at extremely high rate (350-500 bpm)
. Leads to uncoordinated mechanical activity
. Ventricles can’t pump and death ensues
. Due to firing of multiple ectopic foci