MLC Characteristics. Treatment Delivery Systems 2 Field Shaping; Design Characteristics and Dosimetry Issues. Presentation Outline

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Treatment Delivery Systems 2 Field Shaping; Design Characteristics and Dosimetry Issues Timothy D. Solberg David Geffen School of Medicine at UCLA TU-A-517A-1 Presentation Outline MLC Characteristics TG-50 / Definitions Description of Commercial MLC Standard MLC Mini/Micro MLC Dosimetry and QA of MLC Considerations for IMRT TU-A-517A-1 Field Shaping; Design Characteristics and Dosimetry Issues MLC Characteristics MLC Design Leaf Transmission Leaf Sizes Number of Leaves Leaf Travel Leaf Abutment Source-Leaf Distance / Isocenter Clearance Leaf Positioning Mechanism / Accuracy Leaf Positioning Constraints Leaf Speed

MLC Design Upper Jaw Replacement Lower Jaw Replacement Tertiary MLC TU-A-517A-1 Field Shaping; Design Characteristics and Dosimetry Issues Upper Jaw Replacement Courtesy Elekta Upper Jaw Replacement Leaves Upper Mini Diaphragm Lower Diaphragm Courtesy Elekta

Lower Jaw Replacement Upper Diaphragm Leaves Courtesy Siemens Tertiary MLC TG-50 Tertiary MLC Upper Diaphragm Lower Diaphragm Leaves Courtesy Varian

Isocenter Clearance MLC Elekta Largest 45 cm Block Tray 35.3 cm Wedge 35.3 cm Tray + Wedge 35.3 cm Siemens 43 cm 43 cm 43 cm 43 cm Varian 42 cm 35 cm 35 cm 31 cm Positioning Mechanism / Precision Elekta Video Siemens Linear Encoder Varian Standard Linear Encoder Varian Millennium Linear Encoder 0.01 cm 0.10 cm 0.01 cm 0.01 cm TG-50 Definitions TG-50

MLC Design Leaf Sides Leaf sides follow divergence Courtesy Siemens MLC Design Leaf Sides Tongue and Groove Construction - Beam - Beam Leaf Leaf Leaf...... # 7 # 8 # 9 N Agazaryan, R Aaronson MLC Design Leaf Ends Non-focused (rounded) Leaf Ends Leaf motion restricted to a single plane In principle, penumbra is somewhat greater than for focused collimators of divergent custom blocks Potential for greater leaf end transmission when leaves are abutted Both Varian and Elekta use the non-focused design

MLC Design Leaf Ends Penumbra relatively constant as a function of leaf position MLC Design Rounded Leaf Ends Light Field versus radiation field Light field underestimates radiation field by 0.5 to 1.2 mm per side Light Field Projection Radiation Field Projection MLC Design Leaf Ends Focused leaves maintain geometric divergence

Leaf Size and Number Elekta MLC 40 x 2 Leaves 1 cm Size Siemens Varian Standard Varian Standard Varian Millennium Varian Millennium Varian Millennium 29 x 2 26 x 2 40 x 2 26 x 2 40 x 2 60 x 2 1 cm (27) 6.5 cm (2) 1 cm 1 cm 1 cm 1 cm 1 cm (20) 0.5 cm (40) TG-50 Transmission Recommendation For upper or lower jaw replacement MLC, transmission requirements are the same as for standard collimators For tertiary MLC, transmission requirements are the same as for custom blocks (< 5%). However, leaf thickness should provide adequate attenuation to compensate for interleaf transmission TG-50 Definitions: Leaf Transmission Reduction of dose through the full height of the leaf

TG-50 Definitions: Interleaf Transmission Reduction of dose between adjacent leaves TG-50 Definitions: Leaf End Transmission Reduction of dose between the ends of opposed leaves Leaf Transmission N Agazaryan

Transmission Summary Transmission Summary Elekta: 1.8% - 2%, 11% (backup diaphragm only), <0.5% (leaves + backup diaphragm), 4-4.5% between leaves, 50-60% between leaf ends Siemens: 1%, < 1.5% between leaves Varian: 1.5-2.5%, 2-3.5% between leaves, 12-28% between leaf ends

Leaf Characteristic Summary Effective penumbra (80%/20%) of focused versus divergent leaf ends within 1-2 mm of each other Leaf side penumbra ~1 to 1.5 mm less than leaf end penumbra For focused leaf ends, light field underestimates radiation field Transmission characteristics on all systems <4% Tongue and groove construction produces a transmission distribution Leaf Travel - Elekta 12.5 cm 32.5 cm 40 x 40 cm 2 Leaf Abutment - Elekta 1 cm

Leaf Travel - Siemens 10 cm 30 cm 40 x 40 cm 2 Leaf Travel - Varian 14.5* cm 40 x 40 cm 2 *15 cm for Millennium MLC Leaf Travel - Varian 14.5 cm Carriage / Backup Jaw 40 x 40 cm 2

Leaf Travel - Varian 14.5 cm Carriage / Backup Jaw 40 x 40 cm 2 Leaf Abutment Siemens / Varian Abutting Leaves OK Interleaving OK Field Size Summary MLC Elekta Siemens Varian Standard Varian Millennium Regular Field 40 x 40 cm 2 40 x 40 cm 2 40 x 40 cm 2 40 x 40 cm 2 Irregular Field 40 x 40 cm 2 40 x 27 cm 2 29 x 40 cm 2 30 x 40 cm 2

Acceptance Testing, Commissioning and Quality Assurance Alignment of mechanical and optical axes Leaf position calibration, leaf travel characteristics, as a function of collimator and gantry position Follower jaw calibration Transmission characteristics Interlocks Field shaping software, data transfer, reproduction of standard shapes Dosimetric comparison with treatment planning system Alignment of mechanical and optical axes Collimator Rotation Gantry Rotation Leaf Positioning 120 100 80 60 40 20 0

Leaf Positioning 120 100 80 60 40 20 0 Leaf Positioning 120 100 80 60 40 20 0 Leaf Positioning off axis

Leaf Positioning off axis + =

+ = Tongue and Groove 120 100 80 60 40 20 0 MLC Dosimetry

MLC Dosimetry 80% 50% 20% 3D Line DMLC # Leaf Pairs Leaf Width (@ Isocenter) Maximum Field Size Leakage Leakage (interleaf) Penumbra (not specified) Maximum Leaf Speed Weight Clearance to Isocenter 24 ~5 mm 11.5 x 12.0 cm 2 < 1% N/A 3 mm 1 cm/sec 40 kg N/A BrainLAB m3 # Leaf Pairs Leaf Width (@ Isocenter) Maximum Field Size Leakage Leakage (interleaf) Penumbra (80/20) Maximum Leaf Speed Weight Clearance to Isocenter 26 3.0, 4.5, 5.5 mm 10 x 12 cm 2 < 1% < 2% < 4.0 mm 1.5 cm/sec 30 kg 37.9 cm / 31 cm* *for Varian w/o MLC / other linacs

MRC Systems MicroMLC # Leaf Pairs Leaf Width (@ Isocenter) Maximum Field Size Leakage Leakage (interleaf) Penumbra (80/20) Maximum Leaf Speed Weight Clearance to Isocenter 40 1.6 mm 7.3 x 6.4 cm 2 < 1% N/A 3-4 mm (6 MV) 1.2 cm/sec 38 kg N/A MRC Systems ModuLeaf # Leaf Pairs Leaf Width (@ Isocenter) Maximum Field Size Leakage Leakage (interleaf) Penumbra (80/20) Maximum Leaf Speed Weight Clearance to Isocenter 40 2.5 mm 10 x 12 cm 2 < 2% < 2.5% < 4.0 mm 2.0 cm/sec 43 kg N/A Radionics MMLC # Leaf Pairs Leaf Width (@ Isocenter) Maximum Field Size Leakage ( Leakage (interleaf) Penumbra (80/20) Maximum Leaf Speed Weight Clearance to Isocenter 31 4 mm 10 x 12 cm 2 < 1% < 2% max < 4.0 mm 2.5 cm/sec 38 kg 33 cm* *linear accelerator not specified

Zmed BIGMINI # Leaf Pairs Leaf Width (@ Isocenter) Maximum Field Size Leakage Leakage (interleaf) Penumbra (80/20) Maximum Leaf Speed Weight Clearance to Isocenter 40 2.5 mm 10 x 12 cm 2 < 2% < 2.5% < 4.0 mm 2.0 cm/sec 43 kg N/A Vendor Websites 3D Line (DMLC) BrainLAB (m3) Elekta MRC Systems (micro-mlc and ModuLeaf) Radionics (MMLC) Siemens Varian ZMED (BigMini) www.3dline.com www.brainlab.com www.elekta.com www.imrt.de www.radionics.com www.siemensmedical.com www.varian.com www.zmed.com Acknowledgements Jim Billich, Siemens Medical Bruce Curran, Nomos Corporation Call Huntzinger, Varian Medical Systems Steve Leadley, Elekta

References AAPM Report No. 72 - Basic Applications of Multileaf Collimators, Report of Task Group 50 JM Galvin et al Evaluation of multileaf collimator design for a photon beam. IJROBP 23(4): 789-801 (1992). EE Klein et al Clinical implementation of a commercial multileaf collimator: dosimetry, networking, simulation, and quality assurance. IJROBP 33(5): 1195-1208 (1995). MN Graves et al Calibration and quality assurance for rounded leaf-end MLC systems, Med. Phys. 28(11): 2227-2233 (2001). See Also: E Klein Multileaf collimators I: general description, systems and technology assessment J Galvin Acceptance testing, commissioning, and routine QA for multileaf collimator systems J Palta and S Kim Multileaf collimator dosimetry