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Review of Cardiac Structure and Function

Explore the anatomy of the heart, its chambers, valves, and the cardiac cycle. Learn about the conduction system, muscle contraction, and regulation of heart rate. Review the role of the pericardium, blood flow path, valves, and the ECG in this comprehensive overview.

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Review of Cardiac Structure and Function

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  1. Review of Cardiac Structure and Function

  2. Location • Heart lies in the mediastinum behind the sternum • 1/3 of bulk of the heart lies to the right of the midline; 2/3 lies to the left • Apex lies between the 4th & 5th ribs when lying down and between the 5th and 6th ribs when sitting or standing

  3. Pericardium • The heart lies within the pericardium • Outer layer of the pericardium is fibrous connective tissue – fibrous pericardium • Anchors the pericardium to the great vessels, the sternum and diaphragm

  4. Two inner layers of serous membranes- parietal pericardium and visceral pericardium (epicardium) • Between the serous membranes is the pericardial space, filled with 15- 50 ml of fluid to reduce friction • Fibrous pericardium and parietal pericardium are called the pericardial sac • Visceral pericardium is the epicardium

  5. Heart Wall • Epicardium • Myocardium – muscular layer • Thickest layer • Attached to fibrous skeleton of the heart • Bands of muscle arranged longitudinally • Fibers from one side enter other side • Better integration of contractions • Pathology of one ventricle can affect the other

  6. Endocardium • Internal lining of squamous epithelium • Continuous throughout cardiovascular system

  7. Four chambers (two pumps) • Right heart acts as a volume pump – through low-resistance vessels of the pulmonary system • Left heart acts as a pressure pump – through high-resistance vessels of the systemic circulation

  8. Atria • Two upper, thin walled chambers that collect blood returning to the heart • Their contraction aids in filling the ventricles • Right atrium receives blood from superior and inferior vena cavae and coronary sinus • Left atrium receives blood from pulmonary veins

  9. Ventricles • Thick walled pumping chambers of the heart • Make up about 60 % of the mass of the heart and receive most of coronary blood flow • Blood from right ventricle enters the pulmonary trunk • Blood from left ventricle enters the aorta

  10. Path of Blood Flow Vena cavae → RA→ RV→ Pulmonary trunk→ Lungs→ Pulmonary veins→ LA→ LV→ Aorta → Systemic circulation→ Vena cavae

  11. Valves • Made of connective tissue covered by endothelium • Prevent back flow of blood • Open and close passively in response to ventricular contraction • Anchored to the annuli fibrosi cordis to prevent dilation during contraction of the heart

  12. Atrioventricular valves • Lie between the atria and ventricles • Tricuspid valve on the right • Bicuspid or mitral valve on left • Anchored against high pressure by the chordae tendineae and papillary muscles

  13. Semilunar Valves • Lie between ventricles and great vessels • Pulmonary on right side • Aortic on left side

  14. Cardiac Cycle • Sequence of events that compose the repeating pumping action of the heart • Typically, systole refers to ventricular contraction and diastole refers to ventricular relaxation • If referring to atria, specify atrial systole, etc.

  15. Review • Coronary arteries and cardiac veins – note that it is the right coronary artery that supplies blood to the SA and AV nodes

  16. Review • Pressures in chambers: look over the next figure - note especially the pressures in the right atrium – central venous pressure, and the pressures in the aorta – systemic blood pressure

  17. Cardiac muscle - Myocytes • Contractile fibers • Fibers are branched • Intercalated discs - contain desmosomes and gap junctions • Gap junctions connect cytoplasm of adjoining cells so that the action potentials pass from one cell to the next • Cells contract as if one cell - syncytium

  18. Muscle contraction • Striated muscle – contains actin and myosin • Action potential stimulates release of Ca++ • Ca++ binds to troponin • Troponin moves the tropomyosin exposing myosin binding sites on the actin • Myosin pulls on the actin, filaments slide past each other and muscle shortens

  19. Remember, that unlike skeletal muscle, much of the Ca++ used in cardiac muscle contraction comes from the extracellular fluid.

  20. Conduction System • Conduction system cells are specialized myocardial fibers • Heart has autorhythmicity- beats spontaneously at about 100 beats/min • Impulse begins at sinoatrial (SA) node or pacemaker – sinus rhythm • Spreads through atria via conducting myofibers to atrioventricular (AV) node in fibrous skeleton of heart

  21. Signal pauses briefly, for ventricular filling by atrial contraction. • Signal continues into ventricle through conduction pathways: • AV bundle ( bundle of His) →right and left bundle branches→ Purkinje fibers→ ventricular contraction (bottom up)

  22. Regulation of Heart Rate • Sympathetic N.S. increases heart rate and force of contraction – secrete norepinephrine –accelerator nerves • Parasympathetic N.S. decrease heart rate and force of contraction through the vagus nerve. Sends continuous impulses. Secretes acetylcholine

  23. Electrocardiogram ECG • Measures electrical activity of the heart • P wave – represents atrial contraction (depolarization) • QRS complex – represents ventricular contraction (depolarization) • T wave – represents ventricular relaxation (repolarization)

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