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بسم الله الرحمن الرحيم. Electrophysiology ( Conduction System of Heart) . Dr. Mohammed Sharique Ahmed Quadri Assistant Prof. physiology Al maarefa college . Objectives . Identify the components of conducting system of heart . Know the sequence of conduction of impulse in the heart
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بسم الله الرحمن الرحيم Electrophysiology (Conduction System of Heart) Dr. Mohammed Sharique Ahmed Quadri Assistant Prof. physiology Al maarefa college
Objectives • Identify the components of conducting system of heart . • Know the sequence of conduction of impulse in the heart • Recognize the concept associated with pacemaker • Appreciate the role of ANS in controlling rate of generation and conduction of impulse • Recognize the difference between A.P of SA Node and ventricular muscle fiber
Electrical Activity of Heart • Heart beats rhythmically as result of action potentials it generates by itself (Autorhythmicity) • Two specialized types of cardiac muscle cells • Contractile cells( atrial & ventricular muscles • 99% of cardiac muscle cells • Do mechanical work of pumping • Normally do not initiate own action potentials • Auto rhythmic cells ( conductive tissue ) • Do not contract • Specialized for initiating ( excitation)and conducting action potentials responsible for contraction of working cells
AUTORHYTHMICITY What is AutoRhythmicity? • Cardiac autorhythmic cells do not have resting potential instead they show PACE MAKER POTENTIAL • Membrane potential slowly depolarizes between action potential until threshold is reached. • This spontaneous depolarization to threshold is known as PACE MAKER POTENTIAL
Cause of Prepotential • Na+ going inside • Ca++ going inside • ↓ K+ going outside • After Prepotential we get Depolarization and Repolarization Cause of Depolarization - Ca++ going inside Cause of Repolarization - K+ going outside
S A NODE POTENTIAL PHASE 4 = Prepotential PHASE 0 = Depolarization PHASE 3 = Repolarization
Conducting Tissues of the Heart (autorhythmic cells) • APs spread through myocardial cells through gap junctions. • Impulses cannot spread to ventricles directly because of fibrous tissue. • Conduction pathway: • SA node. • AV node. • Bundle of His. • Purkinje fibers.
Conducting Tissues of the Heart • SinoatrialNode (SA node) • Specialized region in right atrial wall near opening of superior vena cava • Pacemaker of the heart • INTERNODAL FIBERS • Internodal Fibers – Anterior, Middle and Posterior [Bachman, Wenchkeback, Thorel]. • Atrioventricular Node (AV node) • Small bundle of specialized cardiac cells located at base of right atrium near inter atrial septum.
Conducting Tissues of the Heart • Bundle of His (atrioventricular bundle) • It is a tract of specialized cardiac cells that originate at AV Node and passes through the fibrous ring and enters interventricular septum • Divides to form right and left bundle branches which travel down septum, curve around tip of ventricular chambers, travel back toward atria along outer walls • NOTE – Lt Bundle Branch has 2 fascicles Left Anterior Fascicle and Left Posterior Fascicle. • Purkinje fibers • Small, terminal fibers that extend from bundle of His and spread throughout ventricular myocardium
CONDUCTIVE TISSUE • Why SA-Node is a Pace-maker? • Because its discharge rate is high 70-80/min. • This 70-80 action potential/min drive rest of the heart, therefore, it is known as pace-maker of the heart.
CONDUCTIVE TISSUE • Other auto - rhythmic tissue are firing at slow rate. • They can work as pace-maker, if SA-Node is not functioning e.g. if AV Node takes over as pace-maker, heart rate will be about 50/min. • Any pace-maker other than SA-Node is called ‘Ectopic Pace-maker’. ( associated with organic heart disease or lack of sleep, anxiety, excess caffeine, nicotine)
APPLIED – HEART BLOCKS • There are three types of heart blocks: • FIRST DEGREE HEART BLOCK – Every impulse is conducted but very slowly, therefore, there is increase in conduction time [we can see on ECG]. • SECOND DEGREE HEART BLOCK – Some impulses are conducted and other are not conducted.
APPLIED – HEART BLOCKS • THIRD DEGREE HEART BLOCK – Complete heart block, no conduction occurs from SA Node to the ventricle through AV node, therefore, atrial rate is separate [75/min] from the ventricular rate which follows the Purkinje fibers and is about 30/min. • IMPORTANT If ventricular rate is very slow e.g. complete heart block, we need artificial pace-maker [implanted device which generates impulse].
Effect 0f Sympathetic and parasympathetic Stimulation on Prepotential(Pace Maker Potential) • Epinephrine & Norepinephrine (Adrenaline and Noradrenaline) causes Prepotential to occur faster therefore increase the heart rate • Acetylcholine causes Prepotential to occur at slow rate therefore decrease the heart rate
Effect 0f Sympathetic Stimulation on Prepotential Why Sympathetic Stimulation causes Prepotential to occur faster? • Because Sympathetic Stimulation causes - more Na+ influx [entry] - more Ca2+ influx [entry] - decreased K+ efflux [going outside] • Therefore, membrane potential changes quickly from -60mV to -40mV [increases the slope of Prepotential] and when it reaches the threshold level, AP starts.
Effect 0f parasympathetic Stimulation on Prepotential Why parasympathetic causes Prepotential to occur after long time? • Because Parasympathetic Stimulation causes - decreased Na+ influx [entry] - decreased Ca2+ influx [entry] - increased K+ efflux [going outside] • Therefore, membrane potential changes slowly from -60mV to -40mV [decreases the slope of Prepotential] and when it reaches the threshold level, AP starts.
Control of heart rate: • Heart rate is determined by balance between Inhibition of SA node by vagus(parasympathetic) & stimulation by sympathetic • Under resting condition parasympathetic discharge dominates
POINT TO PONDER • In Transplanted Heart, where there is no sympathetic and parasympathetic nerve supply, what will be the rate of SA Node discharge [Heart Rate] ?
SPREAD OF CARDIAC EXCITATION • Cardiac impulse originates at SA node and spread to the atria [via gap junction] – Atrial Syncytium, therefore, both atria depolarize same time. • Impulse [AP] goes to AV-Node by Internodal pathway. • AV-Node is the only point of electrical contact between atria and ventricle [as atria and ventricle are separated by fibrous ring which is non-conductive].
SPREAD OF CARDIAC EXCITATION • AV – Node • At AV-Node, there is delay of 0.1 sec [100 milli- sec]. • This delay is important to allow complete ventricular filling • because it allows the atria to contract and empty their blood into the ventricle, before impulse reaches the ventricle and causes ventricular depolarization and contraction
SPREAD OF CARDIAC EXCITATION • Ventricular Excitation • After AV delay of 0.1sec, impulse [AP] travels quickly via Right Bundle Branch and Left Bundle Branch [branches of Bundle of His] to Purkinje Fibers to the ventricles. • Both ventricle depolarize, than contract at same time. • Conduction in Purkinje Fiber is fastest 2-4 meter/sec, therefore, both ventricle depolarize quickly and at the same time.
Normal Impulse Conduction Sinoatrial node AV node Bundle of His Bundle Branches Purkinje fibers
Conduction speed in cardiac tissue • Slowest Conduction at AV – Node • Fastest Conduction – Purkinje Fibers
SPREAD OF CARDIAC EXCITATION • Why Conduction is slow at AV-Node? • Because there are less gap junctions. • Diameter of the fiber is small.
Myocardial Action Potential ( Excitability ) • Once myocardial cells are stimulated by action potential originating in SA node, it produces its own action potential • Ventricular Muscle membrane has resting membrane potential of -90mV. • Action Potential of ventricular muscle fiber has four phases 0, 1, 2, 3 ,4.
Ventricular action potential • Rapid depolarization (Phase 0) – due to Na+ influx • Rapid Repolarization (Phase 1) - Due to closure of Na+ channels • Slow depolarization (Phase 2) - this is called Plateau phase and is maintained for 200 – 300 ms – due to Ca++ influx • Repolarization (Phase 3) – due to K+ efflux • Resting Membrane Potential (Phase 4)
Relationship of an Action Potential and the Refractory Period to the Duration of the Contractile Response in Cardiac Muscle
Electrical Activity of Heart • Because long refractory period occurs in conjunction with prolonged plateau phase, summation and tetanus of cardiac muscle is impossible • Ensures alternate periods of contraction and relaxation which are essential for pumping blood
References • Human physiology by Lauralee Sherwood, seventh edition • Text book physiology by Guyton &Hall,11th edition • Text book of physiology by Linda .s contanzo,third edition