CVS 1 - Heart failure

Question 1

Physiology

Answer 1

SA node - non contractile muscle tissue and spontaneously fires action potentials at a certain freq.
Action potential cause atria to contract.
Signal is slowed down at AV node

Blood is returned from the periphery via vena cava into right atrium . As right atrium contacts it forces blood into right ventirlce so atrium has to ocntract before the ventricle.

From the right ventrilce the blood exits and passesinto the lungs where the blood is oxygenated and returns from via the pulmonary vein into the left atria

after the left ventricle contacts blood ases into the aorta

Question 2

Sympathetic Nervous system

Answer 2

switched on if Blood pressure is low

SinoAtrial node – noradrenaline bind β1 increase pacemaker current (increase slope of phase 4) Atrial-Ventricular node – noradrenaline binds, increases Ca2* current (increases slope of phase 0) and hence conduction velocity
Also increase contractility of myocytes (heart)

Question 3

Parasympathetic Nervous system

Answer 3

switched on if Blood pressure is high

Sinoatrial node – ACh (vagus nerve) binds muscarinic receptors and slows depolarization (opens K+ channel, inhibits Na+ channel opening, reduces slope of phase 4)
Atrial-Ventricular node ACh binds muscarinic receptors and decrease conduction velocity (decreases slope phase 0)

Question 4

Autonomic regulation of cardiac function

Answer 4

• Autonomic nervous system - innervation of SA node
– sympathetic (noradrenaline,↑rate of SA node firing)
– parasympathetic (acetylcholine, ↓rate of SA node firing)
• Baroreceptors
– aortic
– carotid
– send afferent nerve fibres to cardiac control centre (medulla)
• If Increased bp
– baroreceptors activate parasympathetic outflow to inhibit SA firing rate
– parasympathetic outflow inhibits sympathetic nervous system from inducing vasoconstriction (parasympathetic ns causes little direct vasodilation)
• If Decreased bp
– baroreceptors activate sympathetic outflow to increase SA firing rate
– sympathetic nervous system → ↑vasoconstriction →↑venous return→↑ cardiac output

Question 5

Treatment of heart failure

Answer 5

• When the output of the heart is insufficient to meet the needs of the body (c.f. angina)
– insufficient cardiac output (eg reduced left ventricular contractility)
– inadequate venous return (eg inadequate diastolic relaxation)
– symptoms
» » »
tachycardia (compensation) shortness of breath, easily tired oedema
• Several underlying causes possible:
– coronary artery disease, hypertension, myocardial disease, previous M.I., valve dysfunction, arrhythmia, congenital defects
• Acute left ventricular failure
– inadequate output→pulmonary oedema
– inadequate output → reflex arterial/venous contraction →increased venous return → exacerbate problem
– Treatment goal –reduce venous return (preload)
» Loop diuretic (→ venous dilation & pooling even prior to diuresis) eg furosemide
» glycerol trinitrate (dilate venous capacitance vessels)
» opioid analgesic
• Cardiogenic shock
– sudden impairment to left ventricle systole (eg after acute M.I.) impairs organ perfusion
– treatment goal – resuscitation
– dobutamine (inotropic b agonist) to increase tissue perfusion
• Chronic heart failure
– myocardium disease due to excess load because of eg ischaemic heart disease, valve dysfunction, hypertension
– treatment goal
» reduce compensatory mechanisms triggered by failing heart (vasoconstriction, fluid retention) and/or increase output
– ACE inhibitor – first line!
» vasodilation reduces afterload
» Reduced aldosterone secretion reduce preload
– Diuretics – furosemide (reduce preload)
– Paradoxically β1 antagonists
» block reflex activation of RAAS by SNS?
– Digoxin (positive inotrope)

Question 6

Positive inotropic drugs: Digoxin

Answer 6

Digitalis glycosides
– (a.k.a. cardiac glycosides),
– originially isolated from foxglove (Digitalis purpura) 1785
• Mechanism
– inhibits Na+/K+ ATPase in myocyte cell membrane, → ↓ Ca2+ efflux by Na+/Ca2+ exchanger → ↑ Ca2+ in sarcoplasmic reticulum→ positive inotrope
– slows heart rate (activates vagus nerve, slows SA node and AV conduction - “AV block”)
» Because slows ventricular response, so can be useful to treat arrhythmia
– can cause arrhythmia
» AV block
» ↑ membrane potential & ↓ Ca2+ efflux →spontaneous Ca2+ release from s.r.)
» arrhythmia “bigeminy” (normal beat followed by ectopic beat), ventricular tachycardia, ventricular fibrillation.
– binds Na+/K+ ATPase in neurons in CNS and PNS – multiple effects

Question 7

digoxin: indications, pk, adr, caution, contraindication

Answer 7

• Indications
– symptom relief in heart failure
– supraventricular arrhythmia (eg atrial fibrillation)
– NB often used in sub-milligram dose (1000 mg = 1 mg)
• PK
– Good Foral ~ 75% but i.v. possible for rapid onset
– long t1/2 ~ 40 h, large Vd (~ 640L/70 kg; binds Na+/K+ ATPase in skeletal muscle)
– elimination mainly through kidney by PgP → ↑ t1/2 in patients with renal
impairment • ADR
– narrow therapeutic window.
– Cardiac arrhythmia is most important ADR
– GI effects (nausea, vomiting)
– Neurological effects: fatigue, confusion, impaired coloured vision
– Treatment of toxicity – see stage 2, overdose
• Cautions
– Hypokalemia can exacerbate digoxin toxicity see diagram
» K+ inhibits digoxin binding to Na+/K+ ATPase hypokalemia promotes pharmacological and toxic effects of digoxin see diagram
– Hypothyroidism (see diagram) – potential for increased toxicity (see PK)
– elderly more susceptible (renal impairment - see PK)
• Contraindications
– heart block (digoxin inhibits AV node conduction)

Question 8

Effect of thyroid hormones on renal system

Answer 8

Thyroid hormones increase:
• renal blood flow, GFR
Hypothyroidism leads to reduced GFR
- can promote toxicity induced by digoxin

Question 9

Hypokalaemia, Diuretics and digoxin

Answer 9

draw

Question 10

Interaction between
positive and negative
inotropes

Answer 10

draw

Question 11

Interaction between β- antagonists and Digoxin

Answer 11

draw

Question 12

A brief reminder –adrenergic receptors

Answer 12

• β1
– Heart – increased rate & force of contraction
– Kidney (juxtaglomerular cells) - renin release
• β2
– some vascular smooth muscle – dilation (skeletal muscle)
– Bronchial muscle – relaxation
– GI tract – relaxation
– Liver & pancreas – glycogenolysis, gluconeogenesis, lipolysis
– Uterus –relaxation
– Bladder – detrusor muscle relaxation
• β3
– adipose tissue - lipolysis
• α1
– some vascular smooth muscle – constriction
• α1 &α2
– Liver & pancreas- glycogenolysis, gluconeogenesis, lipolysis
– Uterus –contraction
– Bladder sphincter – contraction
– Pupil -dilation

Question 13

Sympathomimetic inotropes

Answer 13

• β1 selective preferred to non-selective sympathomimetics – avoid α1 agonism (peripheral vasoconstriction)
• Dobutamine
– short t1/2 – i.v. not oral
– only used for acute emergencies
– repeated use can cause receptor down regulation and do opposite of what trying to achieve!
• Dopamine
– Is a neurotransmitter but also β1 agonist
– doesn’t cross blood brain barier
• Other β1 agonists avoided
– increase heart rate
– peripheral vasoconstriction α1

Question 14

PDE inhibitors

Answer 14

avoids receptor down regulation

• Enoximone
– selective for PDE III found in cardiac/smooth muscle ↑cAMP (hence also cause arterial vasodilation)
– avoids receptor down-regulation
– increase cardiac output
– can cause arrhythmia – need ECG monitoring so not for chronic therapy

Question 15

Hydralazine

Answer 15

• Vasodilator – relaxes smooth muscle, but uncertain mechanism of action
• Tolerance develops and causes reflex tachycardia so not widely used

Question 16

sacubitril-valsartan

Answer 16

• Combination of sacubitril and valsartan
• Sacubitril
– Inhibits neprilysin, an endopeptidase that degrades ANP, BNP, CNP
– Increased ANP, BNP and CNP promotes vasodilation, natriuresis and diuresis
• Valsartan
– Angiotensin receptor blocker
– See lectures on hypertension
– Included because neprilysin also degraded Angiotensin II, leading to increased Ang-II
– Valsartan blocks vasocontriction induced by Ang II

Question 17

Abbreviated Treatment guidelines for chronic heart failure

Answer 17

Left ventricular dysfunction
• First line: ACE inhibitor + β-antagonist
• Second line: specialist advice advised before second line treatment (eg aldosterone, hydralazine, nitrate)
• Digoxin recommended for severe/worsening heart failure after first and second line treatment
• Diuretics recommended for congestion relief

Question 18

Digoxin • Drug interactions

Answer 18

• Diuretics eg furosemide (not K+ sparing): hypokalemia, see diagram verapamil, quinidine, amiodarone – displace digoxin from tissue binding sites (reduce Vd)
• Antibiotics may increase Foral (gut flora may metabolise digoxin)
• b antagonists also inhibit AV conduction see diagram
• b antagonists and Ca2+ channel blockers both decrease contractility – opposite PD effect to digoxin so may antagonise therapy see diagram
• PgP inhibitors – reduced elimination

PGP pumps digoxin into renal tubule so inhibiting that will reduce elimination of digoxin

Question 19

Why can enoximone be used for a longer period than dobutamine?

Answer 19

enoximone avoids receptor down-regulation but repeated use of Dobutamine can cause receptor down regulation

Question 20

Heart failure due to LVSD (left ventricular systolic dysfunction) - first line treatment

Answer 20

give an ACE Inhibitor and beta-blocker

Question 21

Heart failure due to LVSD (left ventricular systolic dysfunction) - first line treatment intolerant to ACE inhibitor

Answer 21

give an ARB

Question 22

Heart failure due to LVSD (left ventricular systolic dysfunction) - 2nd line treatment

Answer 22

If patient remains symptomatic despite optimal first-line treatment, seek specialist advice and for second-line treatment ADD:
♦ an aldosterone antagonist licensed for treatment of heart failure e.g. spironolactone, especially in moderate to severe heart failure or MI in the past
month OR
♦ an ARB licensed for treatment of heart failure e.g. candesartan, valsartan, especially in mild to moderate heart failure OR
♦ hydralazine in combination with a nitrate*, especially in people of African or Caribbean origins with moderate to severe heart failure.

Question 23

Heart failure due to LVSD (left ventricular systolic dysfunction) - If symptoms persist after 2nd line treatment then consider

Answer 23

♦ If symptoms persist, consider:
- cardiac resynchronisation therapy – (CRT - pacing with or
without a defibrillator)
- digoxin*

Question 24

Heart failure due to LVSD (left ventricular systolic dysfunction) - If intolerant to ACE inhib and ARB then consider

Answer 24

hydralazine* in combination with a nitrate

Question 25

ACEIs and ARBs

Answer 25

Do NOT give to patients with suspected valve disease
until the valve disease has been assessed by a specialist.
♦ Start at low dose and titrate upwards every 2 weeks until
the optimal tolerated or target dose is achieved.
♦ Check renal function before starting treatment.
♦ Measure serum urea, creatinine, electrolytes and eGFR at initiation, after each dose increase and then every 3
months

Question 26

Beta-blockers

♦ Give to all patients with heart failure due to LVSD including older adults and patients with:

Answer 26

¾ peripheral vascular disease,
¾ erectile dysfunction,
¾ diabetes mellitus,
¾ interstitial pulmonary disease,
¾ chronic obstructive pulmonary disease without
reversibility.
♦ Use a beta-blocker licensed for heart failure
e.g. bisoprolol, carvedilol.
♦ Start at low dose and increase gradually.
♦ For patients who are stable and taking a beta-blocker for another indication: - switch to a beta-blocker licensed for treatment of heart failure.
♦ Measure heart rate, blood pressure and clinical status
after each dose increase.

Question 27

Aldosterone antagonists monitor

Answer 27

♦ Monitor potassium, creatinine levels and eGFR.

♦ Seek specialist advice if hyperkalaemia develops or renal function deteriorates.

Question 28

For congestion & fluid retention consider

Answer 28

Prescribe a loop diuretic up to 80 mg furosemide (or equivalent), if necessary, to relieve symptoms of fluid overload.