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Non-Scaling FFAG gantry for proton/carbon gantry

Non-Scaling FFAG gantry for proton/carbon gantry. Dejan Trbojevic-BNL, Eberhard Keil-CERN, and Andrew Sessler-LBL. Introduction Motivation for a new way of isocentric gantry design Carbon/proton gantries today–(Heidelberg, PSI, …) Spot scanning – alternative option

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Non-Scaling FFAG gantry for proton/carbon gantry

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  1. Non-Scaling FFAG gantry for proton/carbon gantry Dejan Trbojevic-BNL, Eberhard Keil-CERN, and Andrew Sessler-LBL • Introduction • Motivation for a new way of isocentric gantry design • Carbon/proton gantries today–(Heidelberg, PSI, …) • Spot scanning – alternative option • The non-scaling FFAG gantries: • Smaller proton gantry • Carbon/proton gantry • Engineering design – magnets are available • Summary FFAG08 Manchester Workshop – Dejan Trbojevic

  2. MOTIVATION: large weight of the present gantries • Large Br=6.76 Tmfor carbon ions requires large magnetic fields. • Presently the beam scanning requires very large magnet at the end of the gantry to accommodate parallel beams to the patient. • Results are: very large magnets and large weight of the transfer line and the whole support. The carbon/proton cancer therapy facilities constraints are very difficult to fulfill with the warm temperature magnets. • This leads us to a new concept – non-scaling light small superconducting gantry. FFAG08 Manchester Workshop – Dejan Trbojevic

  3. Carbon Gantry in Heidelberg Weight of the transport components – 135 tons Total weight = 630 tons Length of the rotating part =19 m Carbon Ek=400 MeV/n Br = 6.76 Tm If: B=1.6 T then r ~ 4.2 m If: B=3.2 T then r ~2.1 m FFAG08 Manchester Workshop – Dejan Trbojevic

  4. Munich and PSI proton gantries FFAG08 Manchester Workshop – Dejan Trbojevic

  5. Proton Gantry at PSI 1.27 m 7.4 m FFAG08 Manchester Workshop – Dejan Trbojevic

  6. The proton gantry @ PSI counterweight 110 tons FFAG08 Manchester Workshop – Dejan Trbojevic

  7. Simulation Code: “SRNA” Vinca Institute @ Joanne Beebe-Wang BNL • Monte Carlo code SRNA-2KG originally developed by R. D. Ilic [Inst. of Nucl. Science Beograd, Yugoslavia, 2002] for proton transport, radiotherapy, and dosimetry. • Modified at BNL to include the production of positron emitter nuclei. • Proton energy range 0.1-250 MeV with pre-specified spectra are transported in a 3D geometry through material zones confined by planes and second order surfaces. • Can treat proton transport in 279 different kinds of materials including elements of Z=1-98 and 181 compounds and mixtures. • Use multiple scattering theory and on a model for compound nucleus decay after proton absorption in non-elastic nuclear interactions. • For each energy range, an average energy • loss is calculated with a fluctuation from • Vavilov’s distribution and with Schulek’s • correction. The deflection angle of protons • is sampled from Moliere’s distribution. • Benchmarked with GEANT-3 and PETRA. • A very good agreement was reached. FFAG08 Manchester Workshop – Dejan Trbojevic

  8. Energy deposition of the 169 MeV protons @ 12 cm Adsorbed energy in MeV-cm2/g Within slices of Ds=1 cm @ 11 cm @ 10 cm @ 9 cm @ 8 cm @12 cm @ 7 cm @ 6 cm @ 5 cm @ 3 cm @ 2 cm @a 1 cm depth FFAG08 Manchester Workshop – Dejan Trbojevic

  9. Vertical Profiles FFAG08 Manchester Workshop – Dejan Trbojevic

  10. Experimental results from: NSRL Laboratory at Brookhaven National Lab - Adam Rusek Ion: C6+ Peak position: 15.95 cm in high density polyethylene (r=0.97 gr/cm3) Kinetic Energy: 292.7 MeV/n LET(in water): 12.9 KeV/mm FFAG08 Manchester Workshop – Dejan Trbojevic

  11. Experimental results from: NSRL Laboratory at Brookhaven National Lab - Adam Rusek Ion: H+ Peak position: 37.1 cm in high density polyethylene (r=0.97 gr/cm3) Kinetic Energy: 250.0 MeV/n LET(in water): 0.392 KeV/mm FFAG08 Manchester Workshop – Dejan Trbojevic

  12. Spot scanning technique – at PSI, Heidelberg, … Problems with straggling and multiple Coulomb scattering require careful planning to achieve 1% accuracy in accumulated dose Courtesy of Stephen G. Peggs S. Peggs, "Fundamental Limits to Stereotactic Proton Therapy", IEEE TRANSACTIONS ON NUCLEAR SCIENCE, VOL. 51, NO. 3, JUNE 2004, 677 D. C. Williams, "The most likely path of an energetic charged particle through a uniform medium", Phys. Med. Biol. 49 (2004) 2899–2911 FFAG08 Manchester Workshop – Dejan Trbojevic

  13. Straggling and multiple Coulomb scattering Courtesy of Stephen G. Peggs Mult. Coulomb Straggling s ~6.5 mm MS s ~7.6 mm MS The total beam size quadrature of the multiple scattering beam size + optical beam size FFAG08 Manchester Workshop – Dejan Trbojevic

  14. Skin depth and required number of voxels Form factor f=1 for a perfect circle D-entire depth of distance total number of voxels required number of pixels in each energy layer FFAG08 Manchester Workshop – Dejan Trbojevic

  15. Skin Depth and required number of voxels FFAG08 Manchester Workshop – Dejan Trbojevic

  16. Spot scanning preparation-longitudinal Courtesy of Stephen G. Peggs Varying the beam size during therapy at different energies and transverse positions. q=32 mrad= tan-1(10 cm/3.2 m) Adjusting btwiss Beam direction FFAG08 Manchester Workshop – Dejan Trbojevic

  17. “Parallel” and 30-40 mrad angle scanning sT Tumor sOPT FFAG08 Manchester Workshop – Dejan Trbojevic

  18. Transverse beam sizes Normalized emittance e @ 0.5 pmm, kinetic energy Ek=200 MeV sOPT= [(btwiss*e)/(6pbg)] g=1.138272/0.938272029=1.21316 bg=0.6868 sT qspread sOPT FFAG08 Manchester Workshop – Dejan Trbojevic

  19. Planning carefully the scan: find the right step size D(start at the end ~10 cm) #1 #2 Central position s=6.504 mm D~3.14 mm q2~30.3 mrad s=6.504 mm q2=(0.10-D)/3.2m Scanner magnet: lsc=0.2m Bscanner-max =(q*Br)/lsc Ek=250 MeV Brmax =2.432 Tm Bscanner-max = 0.38 T 12 mrad ~26 cm Qmax~32 mrad 10 -D cm ~ 9.37 cm qspread =12 mrad s=0.23 mm ~3.2 m D ~10 cm Towards the scanner FFAG08 Manchester Workshop – Dejan Trbojevic

  20. Example of the non-scaling FFAG carbon gantry-cell FFAG08 Manchester Workshop – Dejan Trbojevic

  21. Proton Gantry with triplet and scanning magnets(it could be built with small permanent magnetsF=2 cm) scanner magnified +-10 cm Magnet dimensions, magnetic fields and gradients: L_BD = 25 cm, GD =-33.7 T/m, Bmax= 1.5 T + 33.7 T/m*0.012 mm = 1.9 T L_BF = 30 cm, GF =+35.5T/m, Bmax=-0.25 T -+ 35.5 m*0.028 mm = 1.2 T FFAG08 Manchester Workshop – Dejan Trbojevic

  22. Tracking of protons @ fixed magnetic fields from 90 –250 MeV FFAG08 Manchester Workshop – Dejan Trbojevic

  23. Towards smaller size-proton gantry with superconducting magnets – height ~ 6 m FFAG08 Manchester Workshop – Dejan Trbojevic

  24. Proton gantry with superconducting magnets FFAG08 Manchester Workshop – Dejan Trbojevic

  25. Smaller non-scaling FFAG proton gantry – height 4.7 m FFAG08 Manchester Workshop – Dejan Trbojevic

  26. Smaller non-scaling FFAG proton gantry tracking protons with energies of 79-250 MeV @ fixed magnetic field FFAG08 Manchester Workshop – Dejan Trbojevic

  27. Adjustment of the height with different number of cells FFAG08 Manchester Workshop – Dejan Trbojevic

  28. PSI solution with the non-scaling FFAG FFAG08 Manchester Workshop – Dejan Trbojevic

  29. Carbon gantry design FFAG08 Manchester Workshop – Dejan Trbojevic

  30. FFAG08 Manchester Workshop – Dejan Trbojevic

  31. Lattice functions L= 22 cm Very strong focusing: bx,y~1-2 m Dmax~8.8 cm FFAG08 Manchester Workshop – Dejan Trbojevic

  32. Simulation of the particle transport through the gantry + 5mm -5 mm FFAG08 Manchester Workshop – Dejan Trbojevic

  33. Possible continuous coil magnet design for the non-scaling FFAG gantry FFAG08 Manchester Workshop – Dejan Trbojevic

  34. Magnets are available FFAG08 Manchester Workshop – Dejan Trbojevic

  35. Combined Function magnet for the Carbon Gantry FFAG08 Manchester Workshop – Dejan Trbojevic

  36. Summary • Isocentric gantries are necessary in proton/carbon facilities but presently made of too large and heavy magnets. • Spot scanning is very essential for therapy. We presented a real possibility of scanning at the end of the gantry. • A new solution for the isocentric gantry design present reduction in the gantry size and weight comes from the small superconducting magnets – already available. • The weight of 130 tons in the carbon isocentric gantry is reduced to 1.5 tons. • A follow up detail study of the spot scanning from the end of the gantry will be presented soon. FFAG08 Manchester Workshop – Dejan Trbojevic

  37. Experimental results from: NSRL Laboratory at Brookhaven National Lab - Adam Rusek Ion: H+ Peak position: 26.1 cm in high density polyethylene (r=0.97 gr/cm3) Kinetic Energy: 205.0 MeV/n LET(in water): 0.4457 KeV/mm FFAG08 Manchester Workshop – Dejan Trbojevic

  38. Experimental results from: NSRL Laboratory at Brookhaven National Lab - Adam Rusek Ion: C6+ Peak position: 8.375 cm in high density polyethylene (r=0.97 gr/cm3) Kinetic Energy: 200.2 MeV/n LET(in water): 16.23 KeV/mm FFAG08 Manchester Workshop – Dejan Trbojevic

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