1 / 46

Cardiac Embryology

Cardiac Embryology. Adel Mohamad Alansary, MD Ass. Prof. Anesthesiology and Critical Care Ain Shams University. The beginning. Function of each Layer. Endocardium : Endothelial lining ,Connective tissue precursor (Valves and fibrous skeleton).

vine
Download Presentation

Cardiac Embryology

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Cardiac Embryology Adel Mohamad Alansary, MD Ass. Prof. Anesthesiology and Critical Care Ain Shams University

  2. The beginning

  3. Function of each Layer • Endocardium: Endothelial lining ,Connective tissue precursor (Valves and fibrous skeleton). •  Myocardium: Myocytes, Conduction system (Purkinje fibres),Myoendocrine cells (Atrial Natriuretic Factor production) • Epicardium Coronary vessel precursors, Visceral pericardial lining.

  4. The beginning • Two lateral extensions of cardiac tissue become hollowed out to form a pair of endothelial tubes, which soon fuse to form the primitive cardiac tube. • Paired veins from the trunk (the cardinal system), liver, yolk sac and placenta enter the heart tube from below and a series of arterial arches emerge from the upper end.

  5. Heart tube

  6. arterial trunk bulbuscordis the ventricle • the atrium the sinus venosus

  7. Looping

  8. Looping

  9. Looping

  10. The fold of the loop is principally at the junction of bulbuscordis and ventricle. Note in panel C that the two end up side by side.

  11. Formation of the Cardiac Loop • Atrium grows dorsally to the left • Ventricle & bulbus cordis grows ventrally & to the right 28 days

  12. At the end of the loop formation 30 days

  13. normal d-loop l-loop

  14. Abnormalities of Heart Position Dextrocardia : cardiac loop to the left. = Heart in the right thorax associated with situs inversus (transposition of the viscera) Ectopia cordis = Heart on the surface of chest caused by failure to close the midline

  15. Endocardial cusion fusion

  16. Formation of Ventricular Septum 1. Growth of Endocardial cushions

  17. Septum Formation in A-V Canal

  18. Valve formation

  19. Valve Atresia

  20. Tricuspid Atresia

  21. Atrial septum

  22. Interatrial Septum

  23. Interatrial Septum

  24. ASD • Secundum type defects are observed in 80% of cases. These are characterized by defects involving the foramen ovale and (usually) a defect in the septum primum. • Sinus venosus defects are usually positioned near the entrance of the superior vena cava. These are generally associated with anomalous entry of the right superior pulmonary vein.

  25. ASD • Ostium primum defects are very similar to defects caused by failure of endocardial cushion fusion. • Rarely, complete agenesis of the septum occurs, giving a common atrium.

  26. Ventricular septum

  27. Interventricular Septum

  28. VSD • Type I defects are positioned in the infundibulum of the right ventricle, caudal to the pulmonary valve. These arise from defects in the formation of the bulbuscordis and truncusarteriosus. These are also referred to as supracristal, conal or infundibular VSD.

  29. VSD • Type II defects occur in the membranous portion of the septum, and are the most commonly observed defects. These are also referred to as paramembranous VSD.

  30. VSD • Type III defects are found in close proximity to the tricuspid valve, within the inlet of the right ventricle. These are thought to arise from defects in the partitioning of the AV canal by the endocardial cushions. Also identified as atrioventricular canal defects or inlet defects.

  31. VSD • Type IV defects are present in the muscular portion of the interventricular septum. These can be single or multiple, showing extremely irregular borders (variable in many planes). Type IV defects are not easily visualized or repaired.

  32. Great arteries

  33. Arterial Trunk • This structure does truly septate,butembryologically it is a simple coronal division in its embryonic straight position. • The septation extends upwards from the valves to end just beyond the origin of the paired sixth aortic arches, where it seals off against the posterior truncal wall. • As the sixth arch vessels are destined to be the branch pulmonary arteries, the posterior channel is now the main pulmonary artery. The anterior channel is the aorta.

  34. And so now you can compare the flow scheme on the left with the more lifelike image on the right RPA = right pulmonary artery LPA = left pulmonary artery APS = aortopulmonary (truncal) septum RVO = RV outflow LVO = LV outflow

  35. Fate of Truncus Arteriosus & Aortic Sac

  36. Fate of Aortic Arches

  37. Fate of Aortic Arches

  38. Tetralogy of Fallot

  39. Patent Ductus Arteriosus

  40. Questions • the truncal septum fails to fuse with the septal crest? • - perimembraneous VSD • the truncal septum is deviated to the PA side? • - tetralogy of Fallot • the truncal septum fails to develop? • - truncusarteriosus • the ventricular septum fails to reach the AV valve? • - AV septal defects

  41. Questions • the arterial trunk stays over the RV but does divide? • - double outlet RV • the aortic valve pushes up and right instead of the pulmonary? • - transposition of the great vessels • the ventricles fail to centralise over the AV valve • - double inlet left ventricle (commonest form of single ventricle.

More Related