IM Cardiology Lecture 7 PDF

Summary

This document is a lecture on cardiovascular disease, specifically heart failure. It covers the causes, pathophysiology, and complications of the condition. The lecture notes detail the impact of heart failure on cardiac output, and the compensatory mechanisms involved.

Full Transcript

4th Internal Medicine Dr. Faris
Stage Cardiology Lecture. 6

Heart Failure
Heart failure:
Heart failure describes the clinical syndrome that develops when the heart cannot maintain
an adequate cardiac output, or can do so only at the expense of an elevated filling
pressure.

In mild to moderate forms of heart failure, cardiac output is adequate at rest and only
becomes inadequate when the metabolic demand increases during exercise or some other
form of stress.

Worldwide, the incidence of heart failure is variable but increases with advancing age.
For example, in Scotland the prevalence of heart failure is high at 7.1 in 1000, increasing
with age to 90.1 in 1000 among people over 85 years. In the UK, overall incidence is about 2
in 1000.

The prognosis of heart failure has improved over the past 10 years, but the mortality rate
is still high with approximately 50% of patients dead at 5 years. Heart failure accounts for
5% of admissions to hospital medical wards. The cost of managing heart failure in the UK
exceeds £1 billion per year.

Coronary artery disease is the commonest cause of heart failure in western countries.

Almost all forms of heart disease can lead to heart failure. An accurate aetiological
diagnosis (Box 14.17) is important because in some situations a specific remedy may
be available.
Heart failure predominantly affects the elderly; the prevalence rises from 1% in
those aged 50-59 years to over 10% in those aged 80-89 years.
In the UK, most patients admitted to hospital with heart failure are more than 70
years old; they typically remain hospitalized for a week or more and may be left
with chronic disability.
Although the outlook depends, to some extent, on the underlying cause of the
problem, untreated heart failure generally carries a poor prognosis, approximately
50% of patients with severe heart failure due to left ventricular dysfunction will die
within two years because of either pump failure or malignant ventricular arrhythmias

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Pathophysiology:
− Cardiac output is a function of ⃰ the preload (the volume and pressure of blood
in the ventricle at the end of diastole), ⃰ the afterload (the volume and pressure
of blood in the ventricle during systole) and ⃰ myocardial contractility; this is the
basis of Starling’s Law.

− In patients without valvular disease, the primary abnormality is impairment of
ventricular function leading to a fall in cardiac output. This activates counter-
regulatory neurohumoral mechanisms that in normal physiological
circumstances would support cardiac function, but in the setting of impaired
ventricular function can lead to a deleterious increase in both afterload and
preload.

− A vicious circle may be established because any additional fall in cardiac
output will cause further neurohumoral activation and increasing peripheral
vascular resistance.

− Stimulation of the renin–angiotensin–aldosterone system (RAAS) leads to
vasoconstriction, salt and water retention, and sympathetic nervous system
activation.

− This is mediated by angiotensin II, a potent constrictor of arterioles in both
the kidney and the systemic circulation.

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− Activation of the sympathetic nervous system may initially maintain cardiac
output through an increase in myocardial contractility, heart rate and
peripheral vasoconstriction. However, prolonged sympathetic stimulation
leads to cardiac myocyte apoptosis, hypertrophy and focal myocardial
necrosis. Salt and water retention is promoted by the release of aldosterone,
endothelin-1 (a potent vasoconstrictor peptide with marked effects on the
renal vasculature) and, in severe heart failure, antidiuretic hormone (ADH).

− Natriuretic peptides are released from the atria in response to atrial stretch,
and act as physiological antagonists to the fluid conserving effect of
aldosterone.

− After MI, cardiac contractility is impaired and neurohumoral activation causes
hypertrophy of non-infarcted segments, with thinning, dilatation and
expansion of the infarcted segment (remodelling).
− This leads to further deterioration in ventricular function and worsening heart
failure.

− The onset of pulmonary and peripheral oedema is due to high atrial pressures
compounded by salt and water retention caused by impaired renal perfusion
and secondary hyperaldosteronism.

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 Mechanisms Of Heart Failure
MI (segmental dysfunction) In coronary artery disease, ‘akinetic’ or
‘dyskinetic’ segments contract poorly and may
impede the function of normal segments by
Reduced distorting their contraction and relaxation
Ventricular patterns
contractlity ⃰ Myocarditis/cardiomyopathy
(global dysfunction) ⃰ Progressive ventricular dilatation

Ventricular Hypertension, aortic stenosis Initially, concentric ventricular hypertrophy
(left heart failure) allows the ventricle to maintain a normal output
outflow
Pulmonary hypertension, by generating a high systolic pressure. Later,
obstruction pulmonary valve stenosis (right secondary changes in the myocardium and
(pressure heart failure) increasing obstruction lead to failure with
Overload) ventricular dilatation and rapid clinical
deterioration
Mitral stenosis, tricuspid stenosis Small vigorous ventricle, dilated hypertrophied
Ventricular atrium.
inflow Atrial fibrillation is common cause more
obstruction detoration because ventricular filling depends
heavily on atrial contraction
Ventricular Ventricular septal defect Dilatation and hypertrophy allow the ventricle
Right ventricular volume to generate a high stroke volume and help to
volume overload (e.g. atrial septal maintain a normal cardiac output.
overload defect) However, secondary changes in the
Increased metabolic demand myocardium lead to impaired contractility and
(high output) worsen heart failure

Atrial fibrillation⃰ ⃰ Tachycardia does not allow for adequate filling
of the heart result in reduce cardiac output
Arrhythmia Tachycardia cardiomyopathy Incessant tachycardia causes myocardial
fatigue

Complete heart block Bradycardia limits cardiac output even if
stroke volume is normal
Constrictive pericarditis Marked fluid retention and peripheral oedema,
ascites, pleural effusion and rise JVP
Diastolic
Restrictive cardiomyopathy Bi-atrial enlargement (restrictive filling
dysfunction pattern and high atrial pressures).
Left ventricular hypertrophy Good systolic function but poor diastolic
and fibrosis filling
Hypotension, elevated jugular veins, pulsus
cardiac tamponade paradoxus, poor urine output

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Types of Heart Failure: (Clinical syndromes of heart failure)
The left side of the heart comprises the functional unit of the LA and LV, together
with the mitral & aortic valves; the right heart comprises the RA, RV, with the
tricuspid & pulmonary valves.

1- Left-Sided Heart Failure:
− There is a reduction in the left ventricular output and an increase in the
left atrial or pulmonary venous pressure.
− An acute increase in left atrial pressure causes pulmonary congestion or
pulmonary oedema.
− A more gradual increase in left atrial pressure, as occurs with mitral
stenosis, leads to reflex pulmonary vasoconstriction, which protects the
patient from pulmonary oedema at the cost of increasing pulmonary
hypertension.

2- Right-Sided Heart Failure:
− There is a reduction in right ventricular output for any given right atrial
pressure.
− Causes of isolated right heart failure include chronic lung disease (cor
pulmonale), multiple pulmonary emboli and pulmonary valvular stenosis.

3- Biventricular Heart Failure:
− Failure of the left and right heart may develop because the disease
process, such as dilated cardiomyopathy or ischaemic heart disease,
affects both ventricles or because disease of the left heart leads to chronic
elevation of the left atrial pressure, pulmonary hypertension and right
heart failure.

Diastolic and systolic dysfunction:
− Heart failure may develop as a result of impaired myocardial contraction
(systolic dysfunction) but can also be due to poor ventricular filling and
high filling pressures caused by abnormal ventricular relaxation (diastolic
dysfunction).

− The latter is caused by a stiff non-compliant ventricle and is commonly
found in patients with left ventricular hypertrophy.

− Systolic and diastolic dysfunction often coexist, particularly in patients with
coronary artery disease.

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 High-output failure
− Conditions can occasionally cause heart failure due to an excessively high
cardiac output such as:
1) large arteriovenous shunt,
2) Beri-beri (Cardiac)
3) Severe anemia.
4) Thyrotoxicosis

Acute & Chronic Heart failure:
− Heart failure may develop suddenly, as in MI, or gradually, as in progressive
valvular heart disease. When there is gradual impairment of cardiac function,
a variety of compensatory changes may take place.

− The term ‘compensated heart failure’ is sometimes used to describe those
with impaired cardiac function in whom adaptive changes have prevented
the development of overt heart failure.

− A minor event, such as an intercurrent infection or development of atrial
fibrillation, may precipitate overt or acute heart failure (Box 18.13).

− Acute left heart failure occurs either de novo or as an acute decompensated
episode on a background of chronic heart failure, so-called acute-on-chronic
heart failure.

New Classification of Heart failure types:
1. HFrEF (Heart Failure with reduced Ejection Fraction):
It’s means that the bottom left chamber of the heart (left ventricle), which
sends blood around the body, is not pumping effectively.
HFrEF is classified as an EF under 40%.
2. HFmrEF (Heart Failure with mid-range Ejection Fraction):
It’s means that the bottom left chamber of the heart (left ventricle), which
sends blood around the body, is not pumping effectively.
HFmrEF is classified as an EF between 41% and 49%.
3. HFpEF (Heart Failure with preserved Ejection Fraction):
It’s means that the heart is failing to fill efficiently, therefore it fails to send
enough blood to meet the body's needs

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Clinical assessment
Acute Left Heart Failure
− Acute de novo left ventricular failure presents with a sudden onset of
dyspnoea at rest that rapidly progresses to acute respiratory distress,
orthopnoea and prostration.

− The patient appears agitated, pale and clammy. The peripheries are cool to
the touch and the pulse is rapid. Inappropriate bradycardia or excessive
tachycardia should be identified promptly, as this may be the precipitant for
the acute episode of heart failure.

− The BP is usually high because of sympathetic nervous system activation, but
may be normal or low if the patient is in cardiogenic shock.

− The jugular venous pressure (JVP) is usually elevated, particularly with
associated fluid overload or right heart failure. In acute de novo heart failure,
there has been no time for ventricular dilatation and the apex is not displaced.

− Auscultation occasionally identifies the murmur of a catastrophic valvular or
septal rupture, or reveals a triple ‘gallop’ rhythm. Crepitations are heard at
the lung bases, consistent with pulmonary oedema.
− Acute-on-chronic heart failure will have additional features of long-standing
heart failure (see below).

− Potential precipitants, such as an upper respiratory tract infection or
inappropriate cessation of diuretic medication, should be identified.

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Chronic heart failure
− Patients with chronic heart failure commonly follow a relapsing and remitting
course. The clinical picture depends on the nature of the underlying heart
disease, the type of heart failure that it has evoked, and the neurohumoral
changes that have developed.

− A low cardiac output causes fatigue, listlessness and a poor effort tolerance;
the peripheries are cold and the BP is low. To maintain perfusion of vital
organs, blood flow is diverted away from skeletal muscle and this may
contribute to fatigue and weakness. Poor renal perfusion leads to oliguria and
uraemia.

− Pulmonary oedema due to left heart failure presents as described above and
with inspiratory crepitations over the lung bases.

− In contrast, right heart failure produces a high JVP with hepatic congestion
and dependent peripheral oedema. In ambulant patients, the oedema affects
the ankles, whereas in bed-bound patients it collects around the thighs and
sacrum. Ascites or pleural effusion occurs in some cases.

− Chronic heart failure is sometimes associated with marked weight loss
(cardiac cachexia) caused by acombination of anorexia and impaired
absorption due to gastrointestinal congestion, poor tissue perfusion due to a
low cardiac output, and skeletal muscle atrophy due to immobility.

Complications:
In advanced heart failure, the following may occur:
Renal failure is caused by poor renal perfusion due to a low cardiac output
and may be exacerbated by diuretic therapy, angiotensin-converting enzyme
(ACE) inhibitors and angiotensin receptor blockers.

Hypokalaemia may be the result of treatment with potassium-losing
diuretics or hyperaldosteronism caused by activation of the renin–
angiotensin system and impaired aldosterone metabolism due to hepatic
congestion. Most of the body’s potassium is intracellular and there may be
substantial depletion of potassium stores, even when the plasma potassium
concentration is in the normal range.

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 Hyperkalaemia may be due to the effects of drug treatment, particularly
the combination of ACE inhibitors and spironolactone (which both promote
potassium retention), and renal dysfunction.

Hyponatraemia is a feature of severe heart failure and is a poor prognostic
sign. It may be caused by diuretic therapy, inappropriate water retention due
to high ADH secretion, or failure of the cell membrane ion pump.

Impaired liver function is caused by hepatic venous congestion and poor
arterial perfusion, which frequently cause mild jaundice and abnormal liver
function tests; reduced synthesis of clotting factors can make anticoagulant
control difficult.

Thromboembolism. Deep vein thrombosis and pulmonary embolism may
occur due to the effects of a low cardiac output and enforced immobility,
whereas systemic emboli may be related to arrhythmias, atrial flutter or
fibrillation, or intracardiac thrombus complicating conditions such as mitral
stenosis, MI or left ventricular aneurysm.

Atrial and ventricular arrhythmias are very common and may be related
to electrolyte changes (e.g. hypokalaemia, hypomagnesaemia), the
underlying structural heart disease, and the pro-arrhythmic effects of
increased circulating catecholamines or drugs. Sudden death occurs in up to
50% of patientswith heart failure and is often due to a ventricular arrhythmia.
Frequent ventricular ectopic beats and runs of non-sustained ventricular
tachycardia are common findings in patients with heart failure and are
associated with an adverse prognosis.

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