Automaticity, cardiac

Automaticity of cardiac fibers is controlled in part by activity of the sympathetic and parasympathetic nervous systems. Enhanced activity of the sympathetic nervous system may result in increased automaticity of the SA node or other automatic cardiac fibers. Enhanced activity of the parasympathetic nervous system tends to suppress automaticity conversely, inhibition of activity of the parasympathetic nervous system increases automaticity. Other factors may lead to abnormal increases in automaticity of extra-SA nodal tissues, including hypoxia, atrial or ventricular stretch [as might occur following long-standing hypertension or after the development of heart failure (HF)], and electrolyte abnormalities such as hypokalemia or hypomagnesemia. 

Local anaesthetics directly depress myocardial conduction and contractility in a dose-dependent manner. They bind to and inactivate myocardial sodium channels, reducing the velocity of the cardiac action potential and prolonging the QRS interval. As plasma concentrations approach toxic values sodium channels become progressively inactivated until there is a generalised reduction in automaticity (cardiac slowing) with negative inotropy. Slow increases to near- or above-toxic levels are better tolerated than rapid rises seen following intravascular injection. 

Fig. 13 Schematic illustration of the implantation of an automatic cardiac defibrillator. (By permission of World Medicine-. J,H, Tarme, 1981, 16(25), 64.)...

Automa-ticity. Special cardiac cells, such as SA and AV nodal cells, His-bundle cells, and Purkinje fibers, spontaneously generate an impulse. This is the property of automaticity. Ectopic sites can act as pacemakers if the rate of phase 4 depolarization or resting membrane potential is increased, or the threshold for excitation is reduced. 

The Cardiac Cycle. The heart (Eig. lb) performs its function as a pump as a result of a rhythmical spread of a wave of excitation (depolarization) that excites the atrial and ventricular muscle masses to contract sequentially. Maximum pump efficiency occurs when the atrial or ventricular muscle masses contract synchronously (see Eig. 1). The wave of excitation begins with the generation of electrical impulses within the SA node and spreads through the atria. The SA node is referred to as the pacemaker of the heart and exhibits automaticity, ie, it depolarizes and repolarizes spontaneously. The wave then excites sequentially the AV node the bundle of His, ie, the penetrating portion of the AV node the bundle branches, ie, the branching portions of the AV node the terminal Purkinje fibers and finally the ventricular myocardium. After the wave of excitation depolarizes these various stmetures of the heart, repolarization occurs so that each of the stmetures is ready for the next wave of excitation. Until repolarization occurs the stmetures are said to be refractory to excitation. During repolarization of the atria and ventricles, the muscles relax, allowing the chambers of the heart to fill with blood that is to be expelled with the next wave of excitation and resultant contraction. This process repeats itself 60—100 times or beats per minute... 

The Class I agents decrease excitability, slow conduction velocity, inhibit diastoHc depolarization (decrease automaticity), and prolong the refractory period of cardiac tissues (1,2). These agents have anticholinergic effects that may contribute to the observed electrophysiologic effects. Heart rates may become faster by increasing phase 4 diastoHc depolarization in SA and AV nodal cells. This results from inhibition of the action of vagaHy released acetylcholine [S1-84-3] which, allows sympathetically released norepinephrine [51-41-2] (NE) to act on these stmctures (1,2). 

Isoproterenol may also be used in cardiac arrest. It is often adrninistered as an iv or intracardiac bolus along with sustained external cardiac massage to circulate the dmg and stimulate the SA pacemaker to resume automaticity (86). 

O Cardiac arrhythmias may be caused by abnormal impulse formation (automaticity), abnormal impulse conduction (reentry), or both. 

Abnormal initiation of electrical impulses occurs as a result of abnormal automaticity. If the automaticity of the SA node increases, this results in an increased rate of generation of impulses and a rapid heart rate (sinus tachycardia). If other cardiac fibers become abnormally automatic, such that the rate of initiation of spontaneous impulses exceeds that of the SA node, other types of tachyarrhythmias may occur. Many cardiac fibers possess the capability for automaticity, including the atrial tissue, the AV node, the Purkinje fibers, and the ventricular tissue. In addition, fibers with the capability of initiating and conducting electrical impulses are present in the pulmonary veins. Abnormal atrial automaticity may result in premature atrial contractions or may precipitate atrial tachycardia or atrial fibrillation (AF) abnormal AV nodal automaticity may result in junctional tachycardia (the AV node is also sometimes referred to as the AV junction). Abnormal automaticity in the ventricles may result in ventricular premature depolarizations (VPDs) or may precipitate ventricular tachycardia (VT) or ventricular fibrillation (VF). In addition, abnormal automaticity originating from the pulmonary veins is a precipitant of AF. 

Automaticity Ability of a cardiac fiber or tissue to spontaneously initiate depolarizations. 

Sinus bradycardia. An abnormally low sinoatrial impulse rate (<60/min) can be raised by parasympatholytics. The quaternary ipratropium is preferable to atropine, because it lacks CNS penetrability (p. 107). Sympathomimet-ics also exert a positive chronotropic action they have the disadvantage of increasing myocardial excitability (and automaticity) and, thus, promoting ectopic impulse generation (tendency to extrasystolic beats). In cardiac arrest epinephrine can be used to reinitiate heart beat... 

Propranolol is a prototype of this series of drugs and is the oldest and most widely used nonselective )3-adrenoblocker. It possesses antianginal, hypotensive, and antiarrhythmic action. Propranolol is a cardiac depressant that acts on the mechanic and electrophysio-logical properties of the myocardium. It can block atrioventricular conductivity and potential automatism of sinus nodes as well as adrenergic stimulation caused by catecholamines nevertheless, it lowers myocardial contractility, heart rate, blood pressure, and the myocardial requirement of oxygen. 

The general cardiodynamic effects of cardiac glycosides are quite complex because of the combination of their direct action on the heart and indirect action, which changes the electrophysiological properties of the heart (automatism, conductivity, and excitability). 

Bloomfield DM, Steinman RC, Namerow PB, et al. Microvolt T-wave alternans distinguishes between patients likely and patients not likely to benefit from implanted cardiac defibrillator therapy a solution to the multicenter automatic defibrillator implantation trial (MADIT) II conundrum. Circulation. Oct 5 2004 110(14) 1885-1889. 

The primary electrophysiological effects of moricizine relate to its inhibition of the fast inward sodium channel. Moricizine reduces the maximal upstroke of phase 0 and shortens the cardiac transmembrane action potential. The sodium channel blocking effect of moricizine is more significant at faster stimulation rates an action referred to as use dependence. This phenomenon may explain the efficacy of moricizine in suppressing rapid ectopic activity. An interesting effect of moricizine is its depressant effect on automaticity in ischemic... 

Myocardial cell membrane ATPase, the enzyme present in heart muscle, is the site of action of the cardiac steroid glycosides, which have a specific action on the heart muscle. These drugs increase the force of contraction of the muscle (positive inotropic effect) as well as its conductivity and automaticity. They are also valuable in treating congestive heart failure, in which the circulatory needs of organs are no longer satisfied, and heart arrhythmias, in which the rhythm of the cardiac contractions is upset. The effect of the drug is that the force of contraction increases and the heart rate is slowed (chronotropic effect). Consequently, the cardiac output is elevated while the size of the heart decreases. 

It is an alkaloid obtained from the bark of cinchona and is a dextro isomer of anti-malarial drug quinine. Its sodium channel blocking property results in an increased threshold for excitability and decreased automaticity. As a consequence of its potassium channel blocking properties, it prolongs action potential in most cardiac cells. 

The antiarrhythmic action is due to cardiac adrenergic blockade. It decreases the slope of phase 4 depolarization and automaticity in SA node, Purkinje fibres and other ectopic foci. It also prolongs the effective refractory period of AV node and impedes AV conduction. ECG shows prolonged PR interval. It is useful in sinus tachycardia, atrial and nodal extrasystoles. It is also useful in sympathetically mediated arrhythmias in pheochromocytoma and halothane anaesthesia. 

Propranolol 13- Adrenoceptor blockade Direct membrane effects (sodium channel block) and prolongation of action potential duration slows SA node automaticity and AV nodal conduction velocity Atrial arrhythmias and prevention of recurrent infarction and sudden death Oral, parenteral duration 4-6 h Toxicity Asthma, AV blockade, acute heart failure Interactions With other cardiac depressants and hypotensive drugs... 

Verapamil Calcium channel (ICa-i type) blockade Slows SA node automaticity and AV nodal conduction velocity decreases cardiac contractility t reduces blood pressure Supraventricular tachycardias Oral, IV hepatic metabolism caution in patients with hepatic dysfunction Toxicity Interactions See Chapter 12... 

Potassium and digitalis interact in two ways. First, they inhibit each other s binding to Na+,K+ ATPase therefore, hyperkalemia reduces the enzyme-inhibiting actions of cardiac glycosides, whereas hypokalemia facilitates these actions. Second, abnormal cardiac automaticity is inhibited by hyperkalemia (see Chapter 14). Moderately increased extracellular K+ therefore reduces the effects of digitalis, especially the toxic effects. 

Calcium ion facilitates the toxic actions of cardiac glycosides by accelerating the overloading of intracellular calcium stores that appears to be responsible for digitalis-induced abnormal automaticity. Hypercalcemia therefore increases the risk of a digitalis-induced arrhythmia. The effects of magnesium ion appear to be opposite to those of calcium. These interactions mandate careful evaluation of serum electrolytes in patients with digitalis-induced arrhythmias. 

Calcium antagonists can cause serious toxicity or death with relatively small overdoses. These channel blockers depress sinus node automaticity and slow AV node conduction (see Chapter 12). They also reduce cardiac output and blood pressure. Serious hypotension is mainly seen with nifedipine and related dihydropyridines, but in severe overdose all of the listed cardiovascular effects can occur with any of the calcium channel blockers. 

Certain cardiac cells are able to initiate and maintain a spontaneous automatic rhythm. Even in the absence of any neural or hormonal input, these cells will automatically generate an action potential. They are usually referred to as pacemaker cells in the myocardium. Pacemaker cells have the ability to depolarize spontaneously because of a rising phase 4 in the cardiac action potential (see Fig. 23-1). As described previously, the resting cell automatically begins to depolarize during phase 4 until the cell reaches threshold and an action potential is initiated. 

Pacemaker cells are found primarily in the sinoatrial (SA) node and the atrioventricular (AV) node (Fig. 23-2). Although many other cardiac cells also have the ability to generate an automatic rhythm, the pacemaker cells in the SA node usually dominate and control cardiac rhythm in the normal heart. 

Abnormal impulse generation. The normal automatic rhythm of the cardiac pacemaker cells has been disrupted. Injury and disease may directly render the SA and AV cells incapable of maintaining normal rhythm. Also, cells that do not normally control cardiac rhythm may begin to compete with pacemaker cells, thus creating multiple areas of automaticity. 

Drugs that block beta-1 receptors on the myocardium are one of the mainstays in arrhythmia treatment. Beta blockers are effective because they decrease the excitatory effects of the sympathetic nervous system and related catecholamines (norepinephrine and epinephrine) on the heart.5,28 This effect typically decreases cardiac automaticity and prolongs the effective refractory period, thus slowing heart rate.5 Beta blockers also slow down conduction through the myocardium, and are especially useful in controlling function of the atrioventricular node.21 Hence, these drugs are most effective in treating atrial tachycardias such as atrial fibrillation.23 Some ventricular arrhythmias may also respond to treatment with beta blockers. 

A serious deleterious outcome associated to date primarily with myoblasts (and with thawed BM in chemotherapy patients) (50) is the incidence of cardiac electrical instability for a presumed transient period after cell delivery. These early reports of electrical instability in patients after the receipt of autologous skeletal myoblasts have led to doubts about the safety of these cells as a treatment in the injured heart. Patients who received myoblasts in the earliest clinical studies (33,38) were extremely ill patients with an expected high potential for negative electrical events. In fact, many of the patients who were included in the early trials met the Multicenter Automatic Defibrillator Implantation Trial MADIT-II criteria, which were presented after those trials began, and suggested that all patients who met those criteria be treated with AlCDs. As a result, in more recent clinical studies, many investigators have only enrolled patients who receive AlCDs... 

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