Geant4-Genova Group Anthropomorphic Phantoms Susanna Guatelli Barbara Mascialino Maria Grazia Pia INFN Genova, Italy IEEE Nuclear Science Symposium San.

Slides:

Advertisements

Similar presentations

Computer Simulation for Emission Tomography: Geant4 and GATE Xiao Han Aug

Advertisements

1 COMPARISON BETWEEN PLATO ISODOSE DISTRIBUTION OF A 192 IR SOURCE AND THOSE SIMULATED WITH GEANT4 TOOLKIT F. Foppiano 1, S. Agostinelli 1, S. Garelli.

CT Organ Dose - Part 1 Estimating organ dose for patients Michael F. McNitt-Gray, Ph.D., DABR David Geffen School of Medicine at UCLA.

Maria Grazia Pia IEEE Nuclear Science Symposium and Medical Imaging Conference Short Course The Geant4 Simulation Toolkit Sunanda Banerjee (Saha Inst.

F. Foppiano, M.G. Pia, M. Piergentili Medical Linac IEEE NSS, October 2004, Rome, Italy

Geant4 for Microdosimetry

5 th September 2005 Paul Collins Computed Tomography Dosimetry Assessment of Effective Dose in Computed Tomography using an Anthropomorphic Phantom Paul.

Maria Grazia Pia, INFN Genova 1 Part V The lesson learned Summary and conclusions.

An Introduction to Visible Human Project Ku-Yaw Chang Assistant Professor, Department of Computer Science and Information Engineering.

1 Development of an FDA CT Organ Dose Handbook Thalia T. Mills, Ph. D. FDA Commissioner’s Fellowship project with Dr. Stanley.

Alexander Brandl ERHS 630 Radiation and Tissue Weighting Factors Environmental and Radiological Health Sciences.

Susanna GuatelliSPENVIS and Geant4 Workshop Geant4 anthropomorphic phantoms: models of the human body for radiation protection studies S. Guatelli, G.

Geant4-Genova Group Validation of Susanna Guatelli, Alfonso Mantero, Barbara Mascialino, Maria Grazia Pia, Valentina Zampichelli INFN Genova, Italy IEEE.

A general purpose dosimetric system for brachytherapy

Estimation of the effects of a lead vest on dose reduction for NPP workers using Monte Carlo calculations KIM JEONG-IN.

MOHAMMAD HUSSIEN, NICHOLAS SPYROU & ANDY MA ANTHROPOMORPHIC VOXEL PHANTOM EFFECTIVE NEUTRON DOSES OUTSIDE A LINAC ROOM Department of Physics, University.

Kirov A S, MSKCC Overview of Geant4 Use and Issues in Imaging: Emission Tomography (PET and SPECT) Assen S. Kirov Department of Medical Physics Memorial.

Radioactive Drug Research Committee

Quantities and Measurements - 2 Dosimetric Quantities

Chapter 16 CPT Radiology.

Maria Grazia Pia, INFN Genova CERN, 26 July 2004 Background of the Project.

1 M.G. Pia et al. The application of GEANT4 simulation code for brachytherapy treatment Maria Grazia Pia INFN Genova, Italy and CERN/IT

The brachytherapy advanced example Susanna Guatelli (CERN/INFN)

Medical Imaging Technology “Brainstorm” different types.

Witek Pokorski, Radovan Chytracek, Jeremy McCormick, Giovanni Santin

Md.Kausher ahmed Electrical department. Biomedical engineering Code:6875.

 An individual who performs radiography, radiation therapy, or nuclear medicine technology.

Body Planes, Directions and Cavities

Medical Imaging Technology

Anthropomorphic Phantoms Analytical and voxel models Status and perspectives Giorgio GuerrieriJuly 13 th, 2005.

 Cells – smallest unit of life  Tissue – a collection of cells that work for a common function.

“Dosimetry and optimisation of Cone Beam CT for dentomaxillofacial applications” Safety and Efficacy of a New and Emerging Dental X-ray Modality Cone Beam.

Gean4 Human Phantom advanced example: A Geant4 anthropomorphic model

DIGITAL HIGH-RESOLUTION HEART PHANTOMS Abstract Background:X-ray based imaging modalities employ ionizing radiation with the potential for causing harmful.

1 Simulations and experimental verification of medical X-ray sources: CT case R. A. Miller C. Department of Biophysics, Medical Biophysics Centre University.

International Atomic Energy Agency Internal Dosimetry Software ASSESSMENT OF OCCUPATIONAL EXPOSURE DUE TO INTAKE OF RADIONUCLIDES.

Étienne Létourneau, Fabiola Vallejo Castaneda, Nancy El Bared, Danny Duplan, Martin Hinse Presented by: Étienne Létourneau 2015 Joint Congress, Montreal,

M.G. Pia et al. Brachytherapy at IST Results from an atypical Comparison Project Stefano Agostinelli 1,2, Franca Foppiano 1, Stefania Garelli 1, Matteo.

Radiophamaceuticals in Nuclear Cardiac Imaging Vasken Dilsizian, M.D. Professor of Medicine and Radiology Director of Cardiovascular Nuclear Medicine and.

Medical Imaging X-rays CT scans MRIs Ultrasounds PET scans.

VIII.3. Optimization of Protection for Medical Exposures in Nuclear Medicine 2. Dose to patient Postgraduate Educational Course in Radiation Protection.

IEEE Nuclear Science Symposium and Medical Imaging Conference Short Course The Geant4 Simulation Toolkit Sunanda Banerjee (Saha Inst. Nucl. Phys., Kolkata,

1 As Clinical Anatomy RADIOLOGY Speaker note Dr Mohamed El Safwany, MD.

Riccardo Capra 1, Stéphane Chauvie 2, Ziad Francis 3, Sebastien Incerti 4, Barbara Mascialino 1, Gerard Montarou 3, Philippe Moretto 4, Petteri Nieminen.

A General Purpose Brachytherapy Software Simulation + Analysis (isodose calculation) 2/10/2002 Geant4 Workshop CERN Susanna Guatelli Univ. and INFN Genova.

Medical Accelerator F. Foppiano, M.G. Pia, M. Piergentili

Geant4 DICOM Interface Susanna Guatelli INFN Genova, Italy 8 th March 2004 How to model human anatomy in a Geant4 application.

Evaluation of absorbed fractions for beta- gamma radionuclides in ellipsoidal volumes of soft tissue through Geant4 Ernesto Amato 1, Domenico Lizio 2 and.

TPS & Simulations within PARTNER D. Bertrand, D. Prieels Valencia, SPAIN 19 JUNE 2009.

1 As Clinical Anatomy RADIOLOGY. COURSE GOALS  Understand basics of image generation.  Relate imaging to gross anatomy.  See clinical relationship.

Preliminary External and Internal Dosimetry Data from a new set of mother/fetus models JY Zhang, V Taranenko, D Zhang, X. George Xu, Rensselaer Polytechnic.

Comparison of MC and TP Dosimetry Simulations for Cancer Treatment Raymond Mumme May 12, 2014 Supervisor: Thiago Lima (PhD student) Head Supervisor: Dr.

ESTRO, Geneva 2003 The importance of nuclear interactions for dose calculations in proton therapy M.Soukup 1, M.Fippel 2, F. Nuesslin 2 1 Department of.

Population of 4D Computational Phantoms for CT Imaging Research and Dosimetry W. Paul Segars, PhD Carl E. Ravin Advanced Imaging Labs Duke University.

Nuclear Medicine and PET rev this is now slide 1do not print it to pdf things to do (check off when complete): add revision date to cover page.

DIGESTION AND NUTRITION. Organs Organs are groups of tissues that are specialized to carry out specific functions Some examples are the stomach, lungs.

Radiological Procedures By: Tori Melerine. CT Scans.

S. Guatelli, G. Guerrieri, M. G. Pia INFN Genova, Italy

Diagnostic Imaging.

Medical Imaging Technologies

A Brachytherapy Treatment Planning Software Based on Monte Carlo Simulations and Artificial Neural Network Algorithm Amir Moghadam.

Update on New Federal Guidance for Dose and Risk Assessment

4D eXtended CArdiac-Torso (XCAT) Phantoms

F. Foppiano, S. Guatelli, B. Mascialino, M. G. Pia, M. Piergentili

The Hadrontherapy Geant4 advanced example

Geant4 at IST Applications in Brachytherapy

Anthropomorphic Phantoms

Estimation of the effects of a lead vest on dose reduction for NPP workers using Monte Carlo calculations KIM JEONG-IN.

Skeletal system (body bones) Soft tissues Using Contrast Media

Presentation transcript:

Geant4-Genova Group Anthropomorphic Phantoms Susanna Guatelli Barbara Mascialino Maria Grazia Pia INFN Genova, Italy IEEE Nuclear Science Symposium San Diego, 30 October – 4 November 2006

Geant4-Genova Group Anthropomorphic phantoms Oncological radiotherapy Radiation protection studies Space science etc. A precise representation of the human body is important for accurate dosimetry Courtesy of ESA Anderson Rando phantom Total Body Irradiation

Geant4-Genova Group Mathematical Phantoms Many derivations from the MIRD5 phantom MIRD5 revised (1978) Rosenstein et al (1979) Kramer et al (1982): Adam and Eva Jones and Wall (1985) Cristy & Eckerman (1987): new-born and year old children Jones and Shrimpton (1991) Hart et al (1994): all organs of the ICRP91 Report etc. The size and form of the body and its organs are described by mathematical expressions (co m binations/intersections of planes, circular and elliptical cylinders, spheres, cones, tori, etc.) MIRD5: Estimates of Absorbed Fractions for Mono-energetic Photon Sources Uniformly Distributed in Various Organs of a Heterogeneous Phantom W. S. Snyder, Mary R. Ford, G. G. Warner, and H. L. Fisher, Jr, J. Nucl. Med. Vol.10, Suppl.3, 5-52 (1969)

Geant4-Genova Group M. Caon, Voxel-based computational models of real human anatomy: a review Rad. Env. Biophys. 42 (2004) 229–235 Voxel Phantoms Based on digital images recorded from scanning real people Computed Tomography (CT) or Magnetic Resonance Imaging (MRI)

Geant4-Genova Group Still a hot topic… GSF Male And Female Adult Voxel Models Representing ICRP Reference Man (K. Eckerman) Effective Dose Ratios for the Tomographic Max and Fax Phantoms (R. Kramer) Reference Korean Human Models: Past, Present and Future (C. Lee) The UF Family of Paediatric Tomographic Models (W. Bolch and C. Lee) Development and Anatomical Details of Japanese Adult Male/ Female Voxel Models (T. Nagaoka) Dose Calculation Using Japanese Voxel Phantoms for Diverse Exposures (K. Saito) Stylized versus Tomographic Models: an Experience on Anatomical Modelling at RPI (X. G. Xu) Use of MCNP with Voxel-Based Image Data for Internal Dosimetry Applications (M. Stabin) Application of Voxel Phantoms for Internal Dosimetry at IRSN Using a Dedicated Computational Tool (I. Aubineay-Laniece) The Use of Voxel-Based Human Phantoms in FLUKA (L. Pinsky) The Future of Tomographic Modelling in Radiation Protection and Medicine (Panel discussion) Monte Carlo 2005 Conference, Chattanooga (TN) Session on Tomographic Models for Radiation Protection Dosimetry

Geant4-Genova Group Anthropomorphic Phantoms revisited A fresh look at an old problem Exploit modern software technology architectural Focus on architectural issues, rather than implementation details Open source code  Based on Object Oriented technology  Powerful geometry modeling  Detailed material description  Versatility and precision of physics for dosimetry

Geant4-Genova Group Mathematical Phantom VoxelPhantom Which technique is better? Both! versus Each one has its pro and contra (precision, memory usage, speed of simulation execution…) Which one is “better” depends on one’s own specific use case mathematical-voxel Mix and match: composite mathematical-voxel phantoms Take the best of both worlds And what about a novel unorthodox approach?

Geant4-Genova Group Which one is the best for my dosimetry study? All None of the existing phantoms My own phantom ORNL MIRD Adam&Eva VoxelMan NORMAN Golem VIP-man Otoko Frank Max ADELAIDE Donna Helga Irene etc. ORNL liver + MIRD heart + Max frame + Frank head… Mix & match And what about embedding an organ from my own CT scanning into a standard phantom model?

Geant4-Genova Group Analysis & Design Domain decompositionAbstraction of the process of building a phantomAbstraction of the model of body organs

Geant4-Genova Group Builder Pattern Builder The process of assembling a phantom is handled through a Builder design pattern Assembling a phantom G4PhantomBuilder Concrete builders treated polymorphically through their base class Build a phantom by adding anatomy components one by one Implementations G4MaleBuilder G4FemaleBuilder Customization Derive your own class Build just the components you want (e.g. head only)

Geant4-Genova Group Standard Phantom Models An Abstract Factory (G4VBodyFactory) is responsible for the creation of anatomy components Concrete factories (e.g. G4ORNLBodyFactory,G4MIRDBodyFactory) implement specific phantom models Abstract Factory Pattern A Builder may instantiate more than one BodyFactory and pick organs from different phantom models, or mix organs from standard phantom models with user-created ones Mix & Match

Geant4-Genova Group Phantom parameters Parameters of anatomy components –Geometry, sizes –Position and rotation of body elements –Materials Stored in satellite files for some standard phantom models –Use GDML (Geometry Description Markup Language) –GDML Reader can create a Geant4 geometry out of the stored GDML description Easy to provide user-defined phantom parameters –Supply your own GDML file with parameters –Use one of the standard Factories/Builders to assemble a phantome with your own sizes, materials, positions etc. But you are not forced to use GDML, if you don’t wish so…

Geant4-Genova Group Thyroid Skull Lungs Arm Bones Spine Esophagus Spleen Stomach Kidneys Pelvis Ovaries Lower Large Intestine Leg Bones Urinary Bladder Uterus Upper Large Intestine Liver Breasts Heart Not visible: Brain (inside the skull) Pancreas Components in G4PhantomBuilder

Geant4-Genova Group Female ORNL Anthropomorphic Phantom G4FemaleBuilder + G4ORNLBodyFactory 3 materials skeleton lung soft tissue

Geant4-Genova Group Anatomical components can be defined as Geant4 SensitiveDetectors Energy deposit collected in Geant4 Hits Dosimetry

Geant4-Genova Group Mix & Match Mathematical phantom with one voxel breast MIRD mathematical breast Dance & Hunt voxel breast D. R. Dance and R. A. Hunt, REPORT RMTPC 02/1005

Geant4-Genova Group Dosimetry in mixed mathematical-voxel phantom Energy deposit Arm bone Brain Breast Head Heart Kidney Leg bone Liver Intestine Lungs Spine Ovary Pancreas Pelvis Skull Spleen Stomach Thyroid Bladder Uterus Dose in analytical organs Dose in each breast voxel

Geant4-Genova Group Conclusions OO technology Geant4 powerful functionality Versatility of modeling Precision of Geant4 physics A novel approach to an old problem anthropomorphic phantoms + + = Public release in Geant4 8.2 – December 2006 Open source