3.Maintenance of heart rate is not directly controlled by the nervous system, it is controlled by tw

biology

3.Maintenance of heart rate is not directly controlled by the nervous system, it is controlled by two nodes of

1. the Sinu-atrial node (S.A. node).

2. the Atrio-Ventricular node (A.V.node).

3.Maintenance of heart rate is not directly controlled by the nervous system, it is controlled by two nodes of

it controlled by 2 nodes ....SA node that located in the right atrium ...and Av node....

3.Maintenance of heart rate is not directly controlled by the nervous system, it is controlled by two nodes of

At the basic level, this topic summary is very good:

The coordinated contraction of the heart is produced because the cells with the fastest rate of depolarisation %26quot;capture%26quot; the rest of the heart muscle cells. These cells with the fastest rate of depolarisation are in the sinoatrial node (SA node), the %26quot;pacemaker%26quot; of the heart, found in the right atrium. As the SA node depolarises, a wave of electrical activity spreads out across the atria to produce atrial contraction. [Fig 1]

Electrical activity then passes through the atrioventricular node (AV node) and through into the ventricles via the Purkinje fibres in the Bundle of His to produce a ventricular contraction. If there is any disease of the conducting system of the heart, then this process may be interfered with and the heart rate altered. If, for example, there is disease of the AV node, then there is an electrical block between the atria and the ventricles. The ventricles will beat with their own inherent rhythm, which is much slower, usually 30-50 beats per minute.

Anaesthetic drugs, like halothane, may depress the rate of depolarisation of the SA node, and the AV node may become the pacemaker of the heart. When this occurs it is frequently termed nodal or junctional rhythm.

This automatic rhythm of the heart can be altered by the autonomic nervous system. The sympathetic nervous system supply to the heart leaves the spinal cord at the first four thoracic vertebra, and supplies most of the muscle of the heart. Stimulation via the cardiac beta-1 receptors causes the heart rate to increase and beat more forcefully. The vagus nerve also sup plies the atria, and stimulation causes the heart rate to decrease (bradycardia). Surgical proce dures can cause vagal stimulation and produce severe bradycardia. Examples include pulling on the mesentery of the bowel, anal dilatation or pulling on the external muscles of the eye. Under normal conditions the vagus nerve is the more important influence on the heart. This is especially noticeable in athletes who have slow heart rates.

There are nervous reflexes that effect heart rate. The afferents are nerves in the wall of the atria or aorta that respond to stretch. The aorta contains high pressure receptors. When the blood pressure is high these cause reflex slowing of the heart to reduce the cardiac output and the blood pressure. Similarly, when the blood pressure is low, the heart rate increases, as in shock. Similar pressure receptors are found in the atria. When the atria distend, as in heart failure or overtransfusion, there is a reflex increase in the heart rate to pump the extra blood returning to the heart. When there is a sudden reduction in the pressure in the atria the heart slows. This is called the Bainbridge Reflex and is the cause for the marked bradycardia sometimes seen during spinal anaesthesia. It is best treated by raising the legs to increase the venous return.

Circulatory substances can also affect the heart rate. Catecholamines, like adrenaline, are released during stress, and will cause an increase in heart rate. Drugs are another common cause of change in the heart rate and most anaesthetic drugs can do this. Halothane affects the SA node and will also depress the force of contraction of the heart. Isoflurane, by contrast has little direct affect on the heart, but causes peripheral vasodilation of the blood vessels. This will then decrease the blood pressure, and hence produce a reflex tachycardia as explained above. Ketamine causes stimulation of the sympathetic nervous system, and therefore produces a tachycardia. Other circulating substances may also affect the heart rate, acting indirectly through the autonomic nervous system. For example increased blood concentrations of carbon dioxide will cause stimulation of the sympathetic nervous system and tachycardia, and is an important sign of respiratory failure.

3.Maintenance of heart rate is not directly controlled by the nervous system, it is controlled by two nodes of

Please see the web page for more details on Electrical conduction system of the heart.

3.Maintenance of heart rate is not directly controlled by the nervous system, it is controlled by two nodes of

sa node and av node.