Echocardiography of Prosthetic Valves

1. Echocardiography of Prosthetic Valves Dr. Tehrani

2. Different Types of Valves • Homografts (allograft) • Cadaveric human aortic and pulmonary valves • Heterograft (Xenograft) • Prosthetic Valves • Bioprosthetic valves • Pig aortic valve • Bovine pericardial (other) • Mechanical • Urethane ball in a cage • Single or multiple discs

3. Homografts (allograft)

4. Homografts • Homograft Valves • Harvested soon after death w/ the endothelium still viable • Preparation for implantation • Storage in ABX • Cryopreservation (more recently) • No anticoagulation • Low incidence of endocarditis • Failure due to gradual aortic incompetence

5. Homografts • Position • Mitral • Fitted w/ stent, not proved successful (high failure rate at 5 years) • Stentless grafts not an option for MVR • Aortic • Stentless • Subcoronary • Root Replacement

6. Echocardiography of Stentless Aortic Homografts • Doppler flow characteristics similar to native valve. • Only 2-D evidence: Increased Echo intensity, and Thickness of aortic annulus.

7. Stentless Heterografts (Xenograft)

8. Stentless Heterografts (Xenograft) • Same utility as allografts for AVR: • Subcoronary implantation, and • Root replacement • Advantage over allografts is wider availability • Durability is at least as good as allografts

9. Prosthetic Valves

10. Prosthetic Valves Bio-Prosthetic and Mechanical Prosthetic • All Prosthetic valves have a sewing ring • anchored to the native tissue with sutures • The occluding portion of the valve: • Tissue leaflets  Bio-Prosthetic • Single or multiple discs/ Urethane ball in a cage  Mechanical Prosthetic

11. Bio-prosthetic Valves

12. Bioprosthetic Valves • Two types, of occluding mechanism • Porcine aortic valve (the valve size of the biggest pig is limiting) • Hancock, and • Carpentier-Edwards bioprosthesis Carpentier-Edwards bioprosthesis

13. Bioprosthetic valves • Bovine Pericadium leaflets are shaped to size. More choices • Echocardiographiaclly these two valves types are indistinguishable. Ionescu-Shiley (1976)

14. Bioprosthetic valvesMitral Position 2-D ECHOCARDIOGRAPHIC APPEARANCE

15. Bioprosthetic valvesAortic Position 2-D ECHOCARDIOGRAPHIC APPEARANCE

16. Bioprosthesis • Used extensively in a variety of sites: • Aortic • Mitral • Tricuspid • Advantage: • Low thrombogenicity => No anticoagulation

17. Bioprosthesis • Disadvantages: • Less durable than mechanical prosthesis • Mitral position worse • Due to greater backpressure gradient • Dysfunction: • Leaflet thickening, and Ca++ • Fracture, tears, or progressive stenosis • In vivo, roughly 10% of normal bioprosthetic valves have some leakage.

18. Overview of Various Devices Bio-Prosthetic Valves Mechanical Prosthetic Valves

19. Mechanical Vlaves • Ball-and-Cage Valves • Tilting disc Prosthesis • Single disk • Bileaflet

20. Mechanical Prosthesis • The occluding mechanism dictates both: • The echocardiographic appearance of the valve, and • The flow pattern through the valve • To assess performance, the type of valve implanted must be known

21. Ball-and-Cage Valves • First implanted by starr and Harken in 1960.

22. Ball-and-Cage Valves Opening and closure of the ball-valve

23. Ball-and-Cage Valves • Axisymmetric flow around the valve. • Stagnant flow in the shadow of the ball.

24. Ball-and-Cage Valves Doppler assessment at the margins of the ball

25. Ball-and-Cage Valves M-Mode assessment of Ball-Cage Valve

26. Ball-and-Cage Valves • Durable • Mitral position • Satisfactory profile with the largest size (34 or 32 mm diameter devices) • Can affect the interventricular septum • Aortic position • Small prosthesis required, which can be associated with significant gradient • Regurgitation limited to closure backflow.

27. Tilting Disc Prosthesis • All essentially similar consisting of • Circular prosthetic material, and • One or two hinged and mobile disc(s) • Disc attachment to the ring is eccentric Closure occurs by backpressure on the largest portion of the disk

28. Single Disc Prosthesis • Single Disc devices: • Hall-Medtronics monostrut • Bjork-Shiley • Opening arch is 55-70 degrees • Flow orifice: • Major and minor flow orifices • Streamlines of flow passing through the sewing ring and then laterally out and around the prosthetic disc

29. Single Disc Prosthesis • Bjork-Shiley • Standard • Convex-concave • Many other variations in the market • All of these devices have a zone of stagnation behind the disc  thrombus formation

30. Single Disc Prosthesis Bjork-Shiley in the Mitral position

31. Single Disc Prosthesis • Leak around: • Central strut • Dominant jet • Between the occluding disc and sewing ring. • Two smaller peripheral jets • Normal hemodynamics • Reg.Frac. approx. 12% • Tachycardia, and low output • Reg.Frac. upto 37%

32. Single Disc Prosthesis

34. Single Disc Prosthesis • Dysfunction • Gradual ingrowth of fibrous tissue (panus) • Flow obstruction • Intermittent sticking of the valve with associated flash pulmonary edema

35. Bileaflet Mechanical Prosthesis • St. Jude prosthesis • The most commonly used. • Two equal sized semi-circular leaflets attached by a midline hinge. • Discs can tilt in excess of 80 degrees, resulting in larger: Orifice area

36. Bileaflet Mechanical Prosthesis • St. Jude prosthesis • The most commonly used. • Two equal sized semi-circular leaflets attached by a midline hinge. • Discs can tilt in excess of 80 degrees, resulting in larger: Orifice area Regurgitant back flow

37. Bileaflet Mechanical Prosthesis • Regurgitation occurs at the disc margins • The regurgitant jets converge toward the center of the valve

38. Bileaflet Mechanical Prosthesis St. Jude valve in the mitral position.

39. Imaging of Prosthetic Valves

40. Special Problems of 2-D Imaging Artificial Valves • Echocardiographs are calibrated to measure distance based on the speed of sound in tissue. • Prosthetic valves have different acoustic properties than tissue. Hence, distortion of: • Size • Location, and • Appearance, of the prosthesis.

41. Special problems of artificial valves • Intense reverberation, and • Shadowing • Less gain leads to less: • Reverberation, and • Shadowing, as well as • Better visualization of non-biologic components of the valve • HOWEVER  Decreased definition of cardiac structures

42. Special problems of artificial valves • First image at normal settings, then • Reduce the gainto interrogate the leaflets of Bio-prosthetic valves. • Utilize multiple views.

43. Prosthetic Valve Pathology • Prosthetic Valve Stenosis • Aortic • Mitral • Prosthetic Valve Regurgitation • Aortic • Mitral

44. G E N E R A L L Y Prosthetic Stenosis (and Regurgitation) is: • A question of degree, • Not a question of whether.

45. Prosthetic Valve Stenosis • Determinants of gradients across normal prosthetic valves include: • Valve type, i.e., Manufacturer • Valve size • Flow through the valve Wide range of “Normals”

46. Aortic Prosthesis Gradients as a Function of ValveTYPE and SIZE • Dependence on: • Valve type, and • Size No.21 No.27

47. Gradient as a Function of Valve Type Normal Dopplar data in patients with various types of prosthetic valves in the Aortic Position

48. Gradient as a Function of Valve Size • Valve specifications and doppler echocardiographic data in 67 St. Jude medical valves in the Aortic position Chafizadeh ER, Circ. 83:213, 1991

49. Gradient as a Function of Flow Valve type, i.e., Manufacturer Valve size No.21 Flow through the valve

50. Indicies of Valve Stenosis which are LessFlow Depenent • Contour of jet velocity • Doppler velocity index • Effective orifice area • Valve resistance