Introduction to Robotics in Medicine Part 2: Robotics and Navigation in Radiosurgery

1. Introduction to Robotics in MedicinePart 2: Robotics and Navigation in Radiosurgery Achim Schweikard

2. Stereotactic Radiosurgery beam

4. Conventional Procedure

5. Stereotaxic Frame

6. Arc motion

7. Local Anesthesia

8. Concept

9. Image-Guidance

10. Robot System

11. Robot System

12. System without dynamic tracking

13. B . . . . . Planning

14. Sample Case

15. Phantom (Sample Case)

16. Donut Shape Dose Distribution GafChromic film TPS

17. B . . . . . Planning

18. Planning - Beam Selection - Beam Weighting

19. Planning - Beam Selection PTV OAR - Beam Weighting

20. Planning - Beam Selection PTV OAR - Beam Weighting

21. Planning - Beam Selection PTV OAR - Beam Weighting

22. Planning - Beam Selection PTV OAR - Beam Weighting

23. Planning - Beam Selection PTV OAR - Beam Weighting

24. Planning - Beam Selection PTV OAR More systematic choice? - Beam Weighting

25. Planning - Beam Selection PTV OAR Nothing is known on exact methods - Beam Weighting

26. Planning - Beam Selection PTV OAR  Current method is only empirical - Beam Weighting

27. Planning - Beam Selection - Beam Weighting OAR2 PTV OAR1

28. Planning - Beam Selection - Beam Weighting OAR2 PTV OAR1

29. Planning - Beam Selection - Beam Weighting OAR2 PTV OAR1

30. Planning - Beam Selection - Beam Weighting OAR2 PTV OAR1

31. Planning - Beam Selection - Beam Weighting OAR2 PTV OAR1

32. Beam Weighting • Optimization: • Adjust weights s.t. given dose constraints can be met

33. Beam Weighting • Optimization: • Adjust weights s.t. given dose constraints can be met Zhang P, Dean D, Metzger A, Sibata C. Optimization of Gamma knife treatment planning via guided evolutionary simulated annealing. Med Phys. 2001 Aug;28(8):1746-52.

34. Beam Weighting • Optimization: • Adjust weights s.t. given dose constraints can be met Zhang P, Dean D, Metzger A, Sibata C. Optimization of Gamma knife treatment planning via guided evolutionary simulated annealing. Med Phys. 2001 Aug;28(8):1746-52. Lessard E, Pouliot J. Inverse planning anatomy-based dose optimization for HDR-brachytherapy of the prostate using fast simulated annealing algorithm and dedicated objective function. Med Phys. 2001 May;28(5):773-9.

35. Beam Weighting • Optimization: • Adjust weights s.t. given dose constraints can be met Zhang P, Dean D, Metzger A, Sibata C. Optimization of Gamma knife treatment planning via guided evolutionary simulated annealing. Med Phys. 2001 Aug;28(8):1746-52. Lessard E, Pouliot J. Inverse planning anatomy-based dose optimization for HDR-brachytherapy of the prostate using fast simulated annealing algorithm and dedicated objective function. Med Phys. 2001 May;28(5):773-9. Rosen II, Lane RG, Morrill SM, Belli JA.Treatment plan optimization using linear programming. Med Phys. 1991 Mar-Apr;18(2):141-52.

36. c Linear Programming

37. Linear Programming a11·x1 + ...+ a1n ·xn <= d1 ... ak1 ·x1 + ...+ akn ·xn >= dk ... Max: c1·x1+ ... + cn·xn

38. Linear Programming • Global Minima /Convergence • fast

39. Linear Programming for RT

40. Linear Programming

41. Linear Programming x1 x2 x3

42. Linear Programming x1 x2 x3 5

43. Linear Programming x1 x2 Constraints (Tumor) x1+ x3 >= 5 x3 5

44. Linear Programming x1 x2 Constraints (Tumor) x1+ x3 >= 5 x3 5 x2+ x3 >= 5 5

45. Linear Programming x1 x2 Constraints (Tumor) x1+ x3 >= 5 x3 5 x2+ x3 >= 5 . 5 . .

46. Linear Programming x1 x2 Constraints (Tumor) x1+ x3 >= 5 x3 5 x2+ x3 >= 5 . 5 . . Constraints (Healthy T) x1<= 3 x2<= 3

47. Linear Programming x1 x2 Constraints (Tumor) x1+ x3 >= 5 x3 5 x2+ x3 >= 5 . 5 . . Constraints (Healthy T) x1<= 3 x2<= 3

48. Sample Case

49. Phantom (Sample Case)

50. Donut Shape Dose Distribution GafChromic film TPS