Heart Failure - Pathophysiology
Introduction
The heart pumps deoxygenated blood from the venous circulation into the lungs, where it is oxygenated. Newly oxygenated blood travels via the pulmonary veins to the left atrium and left ventricle, where it is ejected via the aorta into the arterial circulation to supply oxygenated blood to peripheral tissue. Heart failure arises when structural or functional abnormalities prevent the heart adequately filling with or ejecting blood, resulting in the inability to meet metabolic needs of peripheral tissue. The cardiovascular system has a large reserve capacity, so overt clinical signs are only seen with severe disease when the heart cannot compensate for the decreased function.
The definition of heart failure is: a complex syndrome initiated by an inability of the heart to maintain a normal cardiac output at a normal filling pressure.
Heart failure can be further classified according to the cause, whether it leads predominantly to underperfusion or congestion (forward or backward failure) and whether the right or left side of the circulation is affected to a greater extent (right-sided failure or left-sided failure). In some cases, biventricular failure may occur.
- Forward failure (cardiogenic shock): underperfusion of the arterial circulation at normal pressure
- Backward failure (congestive heart failure): adequate output at abnormal pressures, too much fluid in the venous circulation
The most basic equations relating to regulation of circulation are: Cardiac Output (CO) = Heart Rate (HR) x Stroke Volume (SV) Blood Pressure (BP) = Cardiac Output (CO) x Total Peripheral Resistance (TPR) Cardiac Output (CO) = Venous Return (VR)
Mechanisms of failure
Myocardial failure e.g Dilated cardiomyopathy. Causes a failure in contractility.
Volume overload e.g. Valve regurgitation and shunts (PDA). Initial response based on the Frank-Starling Law and stroke volume increases as preload increases and enables the heart to expel the extra blood. Ultimately the heart decompensates and the chamber enlarges. Fluid will build up in the compartment preceding it. For example, failure of the left atrium in this manner due to mitral regurgitation leads to pulmonary oedema.
Pressure overload e.g. aortic stenosis or systemic overload increase afterload so heart muscle hypertrophies. The abnormally thick myocardium may predispose to diastolic failure and arrhythmias.
Compliance failure e.g. cardiac tamponade prevents adequate relaxation of the ventricles and doesn't allow sufficient filling therfore results in diastolic failure.
Abnormal rate/rhythm e.g sustained bradycardia leads to a low output failure.
Clinical Signs
Forward-Low Output Failure
Decreased blood supply to the lungs and other organs. Left failure results in decreased blood returning to the right and so both sides fail simultaneously and vice versa. There will be low systemic blood pressure, exercise intolerance, pallor, tachycardia, weak femoral pulses and pre-renal failure and azotaemia.
Backward-Congestive Failure
Clinical signs are different for each side. In left sided failure signs include dyspnoea and tachypnoea. There may also be lung crackling on ausculatation due to pulmonary oedema and a cough due to left cardiomegaly compressing the left main stem bronchus. In right sided failure there may be jugular distension, hepatomegaly and splenomegaly, ascites, positive Hepato-jugular reflux (Press firmly over the liver and abdomen. A positive test is distension of the jugular vein indicating right sided heart failure.) and pleural effusion.
Compensatory Mechanisms
Renin-angiotensin-aldosterone system
Causes sodium and water retention by the kidney as well as vasoconstriction.
Sympathetic Nervous System
Decreased blood pressure stimulates release of noradrenaline. Increase heart rate and contractility by the effect on beta-receptors. Peripheral vasoconstriction is activated by its action on alpha-receptors. Sinus arrhythmias are abolished. Increased heart rate and rhythm imposed by the sympathetic nervous system increases the heart's oxygen consumption. As diastole is shortened the time available for blood to enter the coronary circulation is also shortened, decreasing blood flow to the myocardium. Resulting myocardial hypoxia may cause arrhythmias.
Myocardial hypertrophy
Classification
New York Heart Association Classification
Classification of congestive heart failure used in human medicine.
- Class 1: No clinical signs but evidence of heart disease
- Class 2: Exercise intolerance or dyspnoea
- Class 3: Marked exercise intolerance
- Class 4: Cannot exercise, dyspnoea at rest
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References
Ettinger, S.J. and Feldman, E. C. (2000) Textbook of Veterinary Internal Medicine Diseases of the Dog and Cat Volume 2 (Fifth Edition) W.B. Saunders Company
Ettinger, S.J, Feldman, E.C. (2005) Textbook of Veterinary Internal Medicine (6th edition, volume 2) W.B. Saunders Company
Fossum, T. W. et. al. (2007) Small Animal Surgery (Third Edition) Mosby Elsevier
Merck & Co (2008) The Merck Veterinary Manual (Eighth Edition) Merial
Nelson, R.W. and Couto, C.G. (2009) Small Animal Internal Medicine (Fourth Edition) Mosby Elsevier
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