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Workshop on Physics and Applications of High Brightness Beams

This workshop will discuss the current situation and advancements in small field dosimetry in Cuba. Topics include issues with small fields, clinical consequences, and the joint IAEA/AAPM formalism. Various dosimetry equipment and phantom systems will also be available for demonstrations.

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Workshop on Physics and Applications of High Brightness Beams

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  1. Updates in small field dosimetry Current situation in CubaMarch 28-April 1, Havana, Cuba, 2016Dr. Fernando García Yip *Dr. Rodolfo Alfonso Laguardia ** Workshop on Physics and Applications of High Brightness Beams Round table on medical applications • * Instituto Nacional de Oncología y Radiobiología, INOR • ** Instituto Superior de Ciencias y Tecnologías Aplicadas, INSTEC

  2. INOR

  3. Introduction - Why bother with small fields? - Advancedtreatmentdevices (mini and micro MLC, Tomotherapy, Gammaknife, CyberKnife...) Complex treatment techniques using non standard /composites fields (IMRT, VMAT, SBRT, SRS/SRT)

  4. Issues with small fields- When a field is small ? - Beam related: - Lack of lateral charge particles equilibrium - Partial oclusion of primary source (collimation type) - Spectral changes => beam quality Detector related - Size of the detector as compare to the size of the field (Volume averaging effects) IPEM Report 103 (2010)

  5. Clinical consequences/ impact • Reduction of the dose rate (output) of the field • The FWHM of the resulting field is wider than the collimator settings (!) • The changes in beam quality (harder spectrum) carries the definition of beam quality (TPR20,10 or D10) index for the new small ref field • Severe influences on treatment planning data • Uncertainty in dose delivery (traceability) • Risk of misadministration/accident

  6. Small Beam Dosimetry Working Groups • IPEM– Report 103, UK • AAPM TG 155 – Small field relative dosimetry, USA • AAPM TG 178 – GammaKnifedosimetry , USA • IAEA/AAPM - Small and non-standard fields • ICRU Report committee on “Prescribing, recording and reporting of stereotactic radiation therapy” • DIN – Small field subcommittee, Germany • Other national efforts (France, Switzerland, …)

  7. Joint IAEA/AAPM formalism • Publication of the Code of Practice expected during 2016

  8. Static small fields Alfonso et al, MedPhys 35 (11), Nov 2008

  9. Small Static FieldsReference Calibration, ref field fmsr is a factor which corrects for the differences between the conditions of field size, geometry, phantom material and beam quality of the conventional reference field fref and the machine-specific reference field fmsr Capote R., Sánchez-Doblado F, Leal A, et al Med. Phys.31 (2004) 2416-2422 Bouchard H and Seuntjens J Med. Phys.31 (2004) 2454-2465 Sempau J, Andreo P, Aldana J, et al Phys. Med. Biol. 49 (2004) 4427

  10. Small Static Fields Relative dosimetry, clinical field fclin

  11. The concept of output factor is “redefined” Is a dose ratio, a field factor (output factor) -- converts absorbed dose to water ! Can be calculated directly as strict ratio of Dw using Monte Carlo alone or measure with a ‘fair’ detector or measured as a ratio of detector readings multiplied by a correction factor. Experimental values depend on the detector Corrects over the conventional output factor (“field correction factor”). Tabulated as function of the detector and field size

  12. for 6 MV linacswith FF, collimatedwith MLC or SRS cones , as function of equivalentfieldsize, (cm) Sánchez-DobladoF, Leal A, et al

  13. IAEA Coordinated Research Project Testing of the IAEA/AAPM Code of Practice for small field dosimetry , CRP E24061 • Saudi Arabia • Syria • Thailand • India • USA (Pittsburgh, PA) • Austria • Germany • Italy • Bangladesh • Cuba • Egypt • Mexico • South Africa Participating countries IAEA project officers • Karen Christaki & Brendan Healy

  14. Small Beam defining systems available in Cuba • Current • Elektalinacs (IMRT) • Precise MLCi (1 cm) • 3dline mMLC (0.3 cm) • Agility MLC (0.5 cm) • SRS Cones set (5 – 15 mm) • Purchased/Projected • micro MLC APEX (4) • Icon LGK, (Gamma knife w/IGRT)

  15. Dosimetry equipment available for the project • Ionization chambers for absolute dosimetry • Detectors for relative dosimetry • Several electrometers • Water and plastic phantoms • Anthropomorphic phantoms • Other ancillary devices for dosimetry

  16. Ionization chambers available for absolute dosimetry o Farmer type (0.6 cc) • Four PTW 30013 (waterproof) • One PTW 30004 (graphite/Al) • One PTW 30002 (all graphite) o Semiflex type (0.125 cc) • Six PTW 31010 o Pinpoint type • two PTW 310016

  17. Detectors available for relative dosimetry o Pinpoint chambers o Two Markus advanced 34045 o Si diodes PTW 60016 (shielded) and 60017 (unshielded) o Two microdiamond PTW 60019 o One liquid ion chamber PTW microlion 31018 o Two bidimensional chamber arrays model PTW Seven29 o EBT2 and EBT3 gafchromic films & transmission scanner o One RPL glass dosimetry system, model FGD-1000SE, with Glass Dosimeters GD-301 1.5 x 8.5mm

  18. Water and plastic phantoms O 1D CNMC water phantom o Three PTW MP3 w/software o PMMA slab phantoms o Solid water (RW3) slabs phantoms

  19. Anthropomorphicphantoms available o Thorax phantoms including holders for semiflex ion chamber CIRS 002LFC and CIRS 008A o Alderson RANDO, including holders for films o EasyCube for IMRT o Locally developed phantom for SRS (Diaz&Pico)

  20. Scientific Background in Cuba MSc thesis conducted on the subject of small beam dosimetry • Asencio Y. Procedure for preclinical commissioning of the radiosurgery system based on mMLC collimators (Jan 2013) • González Y. Accuracy Assessment of an Extracraneal Stereotactic System (Jan 2013) • De la Fuente L. Improvingphysical dosimetry in SRS withsmallbeams (Mar, 2013) • Valdes G. Monte Carlo Monte Carlo calculations of corrections factors for 4 different detectors in non-standard radiation fields settings (Sep 2015) • Argota R. Clinical testing of the new formalism for SBD (on going)

  21. National Introductory Course on Small Field Dosimetry • 6 - 7 November 2014 at INOR • 9 medical physicists attended • Theoretical and practical

  22. Expected output / outcome of IAEA - CRP • Based on the contribution of participating institutions and the results of tests, to release guidelines to Member States on the clinical implementation of the small field Code of Practice • Finalize a TECDOC report with recommendations on changes to the CoP and publish other papers • The ultimate benefit will be the reduction in the uncertainty to the dose delivered to the patients receiving radiotherapy that includes small static photon fields

  23. Conclusions (i) • Standard dosimetry methods do not apply to small and composite non-standard beams. Constrains are due both to machine and detector issues • Dosimetry errors in SBD may be related to both reference and relative determinations • The IAEA/AAPM new formalism (from TRS-398) keeps traceability to a broad beam calibration • The new CoP will standardize recommendations for dosimetry procedures and detectors

  24. Conclusions (ii) • Due to the technology injection, there is and there will be an increased use of small beams for therapy in Cuba • Contribution of local/external capacities is recommended since investigations on SBD are multidisciplinary • Through the IAEA coordinated project (CRP) we can make a modest contribution to the clinical implementation of the CoP.

  25. Acknowledgement • The clinical medical physicist colleagues at INOR and HHA, InsTec faculty and students who contributed to the SBD national efforts is very valuable • IAEA/AAPM joint working group: R. Alfonso, P. Andreo, R. Capote, M. SaifulHuq, J. Izewska, J. Johansson, W. Kilby, T. R. Mackie, A. Meghzifene, H. Palmans, K. Kristaki, J. Seuntjens, W. Ullrich • The support of IAEA through the research contract 19149/RB is recognized

  26. Thank you to the Workshop organizers for including this medical applications round table in the program

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