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The Heart.

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Presentation on theme: "The Heart."— Presentation transcript:

1 The Heart

2 Functions of the Heart The heart works in conjunction with cardiovascular centers and peripheral blood vessels to achieve this goal The function of the heart Generates blood pressure to produce a gradient that pushes blood through the vascular system Regulates blood supply - changes in contraction rate & force match blood delivery to metabolic needs Routes blood, ensuring one-way blood flow, separates pulmonary and systemic circulations

3 The Heart Heart – typically weighs 250–350 grams (healthy heart)
A muscular double pump Pulmonary circuit – takes blood to and from the lungs Systemic circuit – vessels transport blood to and from body tissues

4 Location and Orientation within the Thorax
Largest organ of the mediastinum Located between the lungs Apex lies to the left of the midline Base is the broad posterior surface Figure 18.2

5 Structure of the Heart Right and left atria - Superior chambers, receive blood from the pulmonary and systemic circuits Right and left ventricles - Inferior chambers, the pumping chambers of the heart External markings Left/right auricles Apex Internal Structures Interventricular septa Fossa ovalis

6 Chambers Right Atrium Right Ventricle Forms right border of heart
Receives blood from systemic circuit Fossa ovalis - depression in interatrial septum, remnant of foramen ovale Right Ventricle Receives blood from right atrium through the tricuspid valve (right atrioventricular valve) Pumps blood into pulmonary circuit via the pulmonary semilunar valve into pulmonary trunk Internal walls of right ventricle Trabeculae carneae Papillary muscles Chordae tendineae

7 Chambers Left atrium Left Ventricle Makes up heart’s posterior surface
Receives oxygen-rich blood from lungs Opens into the left ventricle through the Mitral valve (left atrioventricular valve) Left Ventricle Forms apex of the heart Internal walls of left ventricle Trabeculae carneae Papillary muscles Chordae tendineae Pumps blood through systemic circuit via the Aortic semilunar valve (aortic valve)

8 Heart Valves – Valve Structure
Each valve composed of - endocardium with connective tissue core Atrioventricular (AV) valves between atria and ventricles Aortic and pulmonary valves at junction of ventricles and great arteries

9 Function of the Atrioventricular Valves
Figure 18.9a

10 Function of the Semilunar Valves
Figure 18.10a, b

11 Structure of the Heart – Coverings
Pericardium – two primary layers Fibrous pericardium - strong layer of dense connective tissue Serous pericardium -formed from two layers Parietal pericardium Visceral pericardium Pericardial cavity

12 Structure of the Heart – Layers of the Heart Wall
Epicardium - Visceral layer of the serous pericardium Myocardium Consists of cardiac muscle Muscle arranged in circular and spiral patterns Endocardium Endothelium resting on a layer of connective tissue Lines the internal walls of the heart

13 Structure of Heart Wall
Walls differ in thickness Atria – thin walls Ventricles – thick walls Left ventricle – three times thicker than right Exerts more pumping force Flattens right ventricle into a crescent shape Systemic circuit Longer than pulmonary circuit Offers greater resistance to blood flow

14 Blood Flow Through the Heart
Beginning with oxygen-poor blood in the superior and inferior venae cavae Go through pulmonary and systemic circuits A blood drop passes through all structures sequentially Figure 18.6

15 Cardiac Muscle Tissue Forms a thick layer called myocardium
Striated like skeletal muscle Contractions pump blood through the heart and into blood vessels Contracts by sliding filament mechanism Cardiac muscle cells Short Branching Have one or two nuclei

16 Cardiac Muscle Tissue Cells join at intercalated discs
Complex junctions Form cellular networks Cells are separated by delicate endomysium Binds adjacent cardiac fibers Contains blood vessels and nerves

17 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 99% of cardiac muscle cells Do mechanical work of pumping Normally do not initiate own action potentials Autorhythmic cells Do not contract Specialized for initiating and conducting action potentials responsible for contraction of working cells

18 Cardiac Conduction System
SA node ~ 75 bpm - sets the pace of the heartbeat AV node ~ 50 bpm - delays the transmission of action potentials Purkinje fibers ~ 30 bpm - can act as pacemakers under some conditions 70-80/min 40-60/min 20-40/min Approximately 1% of the cardiac muscle cells are autorhythmic rather than contractile. * These specialized cardiac cells don’t contract but are specialized to initiate and conduct impulses through the heart to coordinate its activity. * These constitute the intrinsic cardiac conduction system. These autorhythmic cells constitute the following components of the intrinsic conduction system: * the sinoatrial (SA) node, just inferior to the entrance of the superior vena cava into the right atrium, * the atrioventricular node (AV) node, located just above the tricuspid valve in the lower part of the right atrium, * the atrioventricular bundle (bundle of HIS), located in the lower part of the interatrial septum and which extends into the interventricular septum where it splits into right and left bundle branches * which continue toward the apex of the heart and the purkinje fibers * which branch off of the bundle branches to complete the pathway into the apex of the heart and turn upward to carry conduction impulses to the papillary muscles and the rest of the myocardium. Although all of these are autorhythmic, they have different rates of depolarization. * For instance, the SA node * depolarizes at a rate of 75/min. * The AV node depolarizes at a rate of 40 to 60 beats per minute, * while the rest have an intrinsic rate of around 30 depolarizations/ minute. * Because the SA node has the fastest rate, it serves as the pacemaker for the heart. *


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