Heartbeat and ECG

Question 1

Describe how a cardiac pacemaker cell works

Answer 1

At rest there is constant sodium influx into the cell coupled with simultaneous potassium efflux (prevents depolarisation) –> potassium efflux decays with time –> membrane potential slowly depolarises –> action potential generated when outward potassium reaches critically low level and there’s transient increase in sodium influx –> potassium efflux then ‘reset’ to a high level again –> cycle repeats

Question 2

What is happening biochemically in a cardiac pacemaker cell at rest?

Answer 2

There is a constant sodium influx (leak) into the cell at rest, and this would normally depolarise the cell but a simultaneous outward potassium current is preventing this.

Question 3

Why are cardiac pacemaker cells myogenic?

Answer 3

Due to the constant inward sodium current, the pacemaker cells in the SAN are spontaneously active and therefore the rate of stimulation simply depends on the rate of decay of outward potassium current.

Question 4

What is the voltage of the cardiac pacemaker cells at rest?

Answer 4

~ -70mV

Question 5

What is the voltage of the cardiac pacemaker cells before generating an action potential?

Answer 5

~ -40mV

Question 6

Where is the SAN found?

Answer 6

On the wall of the right atrium near the entrance of the superior vena cava

Question 7

Describe the SAN

Answer 7

A group of modified cardiac muscle cells that generate impulses (pacemaker) that is sent to adjacent atrial cells by gap junctions

Question 8

What is the blood supply to the SAN?

Answer 8

Right coronary artery

Question 9

Where is the AVN located?

Answer 9

Located on the inter-atrial septum close to the tricuspid valve (right side of heart)

Question 10

Describe the function of the AVN

Answer 10

Transmits the impulse from the SAN down to the ventricles down the bundles of His and then up the Purkinje fibres, to cause upwards contraction from the apex of the heart

Question 11

What nervous stimulation is there to the SAN?

Answer 11

Sympathetic and parasympathetic

Question 12

Describe the parasympathetic nervous innervation of the SAN

Answer 12

Parasympathetic nerves from the vagus act via interneurons within the node to inhibit the closure of the potassium channels via muscarinic receptors, making the pacemaker cells slow down.

Question 13

Describe the sympathetic nervous innervation of the SAN

Answer 13

Sympathetic nerves at the SAN increase closure of the potassium channels by beta adrenoreceptor actions, which makes pacemaker cells ‘speed up’

Question 14

How does adrenaline act to increase the force of contraction of the myocardium

Answer 14

 Adrenaline in the blood acts on beta receptors throughout the myocardium as well as in the SAN, in order to produce ionotropic actions (increased force of contraction)

Question 15

What nervous stimulation is there to the AVN?

Answer 15

Both parasympathetic and sympathetic nervous system (weaker inputs than into the SAN)

Question 16

Describe the spread of the action potential from the SAN in the heart

Answer 16

SAN –> both atria within 60ms –> 60ms delay to AVN to allow time for atrial to contract and push blood into ventricles before ventricular contraction –> fast conduction muscle fibres leave AVN –> travel down IV septum –> down the left and right bundles of His to the apex of the heart –> activates the Purkinje fibres which then move the impulse up the walls of the ventricles to cause upwards contraction –> blood moves into the great vessels

Question 17

What is a first degree atrioventricular block?

Answer 17

Where the PR interval is lengthened beyond 200ms

Question 18

How may conduction through the bundles of His or Purkinje fibres be impaired?

Answer 18

Conduction can be damaged by ischaemia

Question 19

What type of calcium ion channel is present in cardiac muscle?

Answer 19

slow, L type

Question 20

Describe the action potential graph in ventricular muscle

Answer 20

Fast rise in voltage (depolarisation) due to opening of the sodium channel, this is then followed by a prolonged depolarisation phase known as the plateau (due to late and prolonged entry of calcium into the cell –> muscles can contract for much longer than skeletal muscle) – followed by a refractory period whereby potassium efflux occurs

Question 21

What is the function of L-type calcium channel antagonists?

Answer 21

Drugs which block these slow calcium channels are used to decrease the force of ventricular contraction and thus the work (and oxygen demand) of the heart

Question 22

How many leads are there in an ECG?

Answer 22

12

Question 23

What produces an ECG trace?

Answer 23

Although an ECG is caused by the cardiac action potentials, it is not the same shape as the cardiac action potential graphs; generally the ECG is mainly generated at the start and the end of cardiac action potentials

Question 24

What does the R wave signify in an ECG?

Answer 24

The start of ventricular depolarisation

Question 25

What does an ECG lead do?

Answer 25

Records the voltage between two points on the body

Question 26

What does Lead I in an ECG record?

Answer 26

Records the signal between the left and right axillae

Question 27

What does Lead II in an ECG record?

Answer 27

Records the signal between the right axilla and leg

Question 28

What does Lead III in an ECG record?

Answer 28

Records the signal between the left axilla and leg

Question 29

Where is a standard ECG recorded from and why?

Answer 29

From lead II (between right axilla and leg) as this ordinarily gives the largest signal of the three limb leads

Question 30

How long should the QRS complex be ordinarily?

Answer 30

Less than 100ms

Question 31

How long should the PR interval be ordinarily?

Answer 31

120-200ms

Question 32

What represents the first heart sound (Lubb - closure of AV valve) in an ECG?

Answer 32

QRS complex

Question 33

In which limb leads is the P wave normally positive?

Answer 33

Leads I and II and sometimes also in III

Question 34

How should the P wave appear in an ECG?

Answer 34

Smooth and rounded is normal

Question 35

Is the Q wave positive or negative on an ECG trace?

Answer 35

Negative, no Q wave is present if QRS complex signal starts upwards

Question 36

How does the Q wave appear on the limb leads in an ECG?

Answer 36

Normally small; but it’s absent on lead II (right axilla and leg)

Question 37

How does the R wave appear on the limb leads in an ECG?

Answer 37

R wave is positive by definition and is usually present on all three leads

Question 38

How does the S wave appear on the limb leads in an ECG?

Answer 38

S wave is negative by definition

Question 39

What does the ST segment represent in an ECG?

Answer 39

When all of the ventricular muscles are contracting

Question 40

What are ST segment changes important in the diagnosis of?

Answer 40

Acute myocardial infarction

Question 41

How does the T wave appear on the limb leads in an ECG?

Answer 41

Normally orientated in the same direction as the preceding QRS complex

Question 42

What are the augmented limb leads in an ECG?

Answer 42

Unipolar leads because the amplitude of the signal is calculated between one physical recording point and one virtual reference point on the centre of the chest; the ECG automatically calculates the values on these leads

Question 43

How many limb leads are there in total?

Answer 43

6; I, II, III, aVR, aVL, aVF

Question 44

Describe the recordings present on the aVR limb lead

Answer 44

Always has a large Q waave and small or non-existent R wave

Question 45

Describe the recordings present on the aVL limb lead

Answer 45

Readings are often very small

Question 46

How many chest leads are there in the production of an ECG?

Answer 46

6; V1-V6

Question 47

What type of leads are the chest leads used in the production of an ECG trace?

Answer 47

Unipolar leads that reference the amplitude of signal to a virtual point in the centre of the chest

Question 48

Where is the V1 chest lead placed?

Answer 48

In the 4th intercostal space next to the sternum on the patient’s right

Question 49

Where is the V2 chest lead placed?

Answer 49

In the 4th intercostal space next to the sternum on the patient’s left

Question 50

Describe the recordings present on the V1 chest lead

Answer 50

Mainly negative with a large S wave

Question 51

Describe the recordings present on the V5 and V6 chest leads

Answer 51

Mainly positive with a large R wave

Question 52

Why are 12 recordings collected for an ECG?

Answer 52

Electrodes are affected more by electrical activity in physically nearer parts of the body so different leads view different regions of the heart to pick up abnormalities in the areas

Question 53

Which leads provide a view of the inferior heart?

Answer 53

II, III and aVF

Question 54

Which leads provide a view of the lateral heart?

Answer 54

I, aVL, V5, V6

Question 55

Which leads provide a view of the anterior heart?

Answer 55

V3, V4

Question 56

Which leads provide a view of the septal heart?

Answer 56

V1 and V2

Question 57

How may COPD or coronary heart failure appear on an ECG trace?

Answer 57

Notched or peaked P waves

Question 58

What is the absence of a P wave in an ECG trace likely to represent?

Answer 58

Atrial fibrillation

Question 59

What is the presence of extra P waves in an ECG trace likely to represent?

Answer 59

Atrial flutter

Question 60

What is ST elevation?

Answer 60

Where, instead of the S portion returning to baseline prior to the T wave, it continues to increase and doesn’t reach the baseline until after the T wave

Question 61

What is ST depression?

Answer 61

Where, instead of the S portion returning to baseline it remains beneath this point until the T wave

Question 62

What is ST elevation indicative of?

Answer 62

Acute ischaemia in the viewed part of the heart such as acute myocardial infarction

Question 63

What is a ST depression indicative of?

Answer 63

Sign of chronic ischaemia in the viewed region of the heart