Detector technologies: from particle physics to radiotherapy

Slides:

Advertisements

Similar presentations

Advertisements

Detector R&D and Cancer Care Barbara Camanzi. NDI Kick-Off Meeting, 10/12/102/18 Outline  Why cancer  Detector R&D projects for cancer care: imaging.

Toward a multi-modality approach to radiotherapy for cancer treatment in UK (Unity is strength) Barbara Camanzi STFC – RAL & University of Oxford.

Harvard Medical School Massachusetts General Hospital.

Recent news about SiPM based applications R&D in DESY Nicola D’Ascenzo University of Hamburg - DESY.

DFNA-Ilie Cruceru PERSPECTIVES FOR A POSITRON EMISSION TOMOGRAPHY (PET) PLANT BASED ON RESISITIVE PLATE COUNTER (RPC) Ilie Cruceru, Mihai Petrovici, Florin.

Fysisk institutt - Rikshospitalet 1. 2 Overview Gamma camera Positron emission technology (PET) Computer tomography (CT) Proton therapy Electrical impedance.

1 Physics & Instrumentation in Positron Emission Tomography Paul Vaska, Ph.D. Center for Translational Neuroscience Brookhaven National Laboratory July.

Nuclear Medicine Spring 2009 FINAL. 2 NM Team Nuclear medicine MD Nuclear medicine MD Physicist Physicist Pharmacist Pharmacist Technologist Technologist.

Medical Imaging Mohammad Dawood Department of Computer Science University of Münster Germany.

Andrei Nomerotski 1 Instrumentation for Medical Applications Andrei Nomerotski (Oxford Particle Physics) VC Forum, 17 November 2009.

Observation of Fast Scintillation of Cryogenic PbI 2 with VLPCs William W. Moses, 1* W.- Seng Choong, 1 Stephen E. Derenzo, 1 Alan D. Bross, 2 Robert Dysert,

Lecture 2-Building a Detector George K. Parks Space Sciences Laboratory UC Berkeley, Berkeley, CA.

PHYSICS IN NUCLEAR MEDICINE: QUANTITAITVE SPECT AND CLINICAL APPLICATIONS Kathy Willowson Department of Nuclear Medicine, Royal North Shore Hospital University.

Paul Sellin Detector Research at the University of Surrey Dr Paul Sellin Centre for Nuclear and Radiation Physics Department of Physics University of Surrey,

Planar scintigraphy produces two-dimensional images of three dimensional objects. It is handicapped by the superposition of active and nonactive layers.

Radioisotopes in Medicine

Instrumentation for medical physics applications Barbara Camanzi, PPD/RAL Instrumentation for radiotherapy Imaging: 1. Fast Time Of Flight PET 2. Electron.

PET/CT & PET/MRI Radiopharmacy

8/18/2015G.A. Fornaro Characterization of diffractive optical elements for improving the performance of an endoscopic TOF- PET detector head Student: G.

Introduction to Nuclear Medicine

High spatial resolution measurement of depth-of-interaction of a PET LSO crystal Aliz Simon a László Balkay b, István Chalupa b, Gábor Kalinka a, András.

Very High Resolution Small Animal PET Don J. Burdette Department of Physics.

RAD2012, Nis, Serbia Positron Detector for radiochemistry on chip applications R. Duane, N. Vasović, P. LeCoz, N. Pavlov 1, C. Jackson 1,

Simulation Needs in PET (Positron Emission Tomography)

May 2015ECFA meeting1 Spin-off technologies for cancer diagnosis J. Varela, LIP Lisbon ECFA meeting, Coimbra, 15 May, 2015.

Fast Detectors for Medical and Particle Physics Applications Wilfried Vogel Hamamatsu Photonics France March 8, 2007.

Department of Radiology UNIVERSITY OF PENNSYLVANIA 1 Investigation of LaBr 3 Detector Timing Resolution A.Kuhn 1, S. Surti 1, K.S. Shah 2, and J.S. Karp.

Fundamental Limits of Positron Emission Tomography

Response of the sensors to different doses from tests in Israel Radiotherapy is used as a treatment in around 50% of cancer cases in the UK. Predominantly,

Medical Image Analysis Dr. Mohammad Dawood Department of Computer Science University of Münster Germany.

Cancer Therapy and Imaging Cancer Therapy and Imaging Rob Edgecock STFC Rutherford Appleton Laboratory.

HEALTH Novel MR-compatible PET detectors for simultaneous PET/MRI imaging FP7-HEALTH-2009-single-stage The focus should be to develop novel.

October 16thPicosecond Lyon1 INNOTEP Project Using HEP technologies to improve TEP imaging: Development of innovative schemes for front-end electronic,

Ragnar Hellborg Lund University PRODUCTION OF CLINICALLY USEFUL QUANTITIES OF 18 F BY AN ELECTROSTATIC TANDEM ACCELERATOR Ragnar Hellborg Lund University,

RICH Detectors for Particle ID 1 F. Sabatie Bochum Meeting CLAS12 JLab: Base configuration: 2 sectors ~1 m 2 photon detector per sector Extension.

Optimization of Detectors for Time of Flight PET Marek Moszyński, Tomasz Szczęśniak, Soltan Institute for Nuclear Studies, Otwock-Świerk, Poland.

Nuclear Medicine: Tomographic Imaging – SPECT, SPECT-CT and PET-CT Katrina Cockburn Nuclear Medicine Physicist.

16. January 2007Status Report On Compton Imaging Projects 1 Status Of Compton Imaging Projects Carried Out In The CIMA Collaboration HPD Brain PET Meeting.

Enhancing InBeam PET with single Photon (Compton) Detection CERN September 2nd 2008 VALENCIA GROUP, IFIMED José M. Benlloch (PET hardware, speaker) José.

Nuclear Medicine Principles & Technology_I

Rebecca Barrett CRYSTAL LAB. PET Detects gamma rays Interact with the crystals and release photons Smaller the crystal, the less uncertainty.

Medical applications of particle physics General characteristics of detectors (5 th Chapter) ASLI YILDIRIM.

Advanced Biomedical Imaging Dr. Azza Helal A. Prof. of Medical Physics Faculty of Medicine Alexandria University.

Scintillators suitable for PET applications must be characterized by a high efficiency for gamma-ray detection, determined by a high density and atomic.

1 Nuclear Medicine SPECT and PET. 2 a good book! SR Cherry, JA Sorenson, ME Phelps Physics in Nuclear Medicine Saunders, 2012.

Peter Dendooven LaBr 3 and LYSO monolithic crystals coupled to photosensor arrays for TOF-PET Physics for Health in Europe Workshop February 2-4, 2010,

1 Rome, 14 October 2008 Joao Varela LIP, Lisbon PET-MRI Project in FP7 LIP Motivations and Proposals.

F. Garibaldi 1,, F. Cusanno 1), S. Majewski 3), N. Clinthorne, P. Musico 4),…………………………. TOPEM: a PET TOF probe, compatible with MRI and MRS for diagnosis.

Nuclear Medicine Physics and Equipment 243 RAD 1 Dr. Abdo Mansour Assistant Professor of radiology

Atoms for Health Prof. Dr. Werner Burkart Skolkovo Conference on: Accelerators and Radiation Technologies for the Future of Russia Saint Petersburg,

Nuclear Medicine Introduction

PET Imaging Positron Emission Tomography

Simulations in Medical Physics Y. TOUFIQUE*, R.CHERKAOUI EL MOURSLI*, M.KACI**, G.AMOROS**, *Université Mohammed V –Agdal, Faculté des Sciences de Rabat,

P. Lecoq CERN2 February ENVISION WP2 Meeting CERN Group contribution to ENVISION WP2 Paul Lecoq CERN, Geneva.

Towards a picosecond fully- photonic detector module for direct 3D PET and future HL colliders R. Graciani & D. Gascón Institut de Ciències del Cosmos.

Chapter-5 Positron emission tomography (PET)

Abstract The shape of the current pulse produced by a SiPM in response to an incident photon is sensibly affected by the characteristics of the FE used.

Instrumentation for radiotherapy Imaging: 1. Fast Time Of Flight PET

Positron emission tomography without image reconstruction

Performance of LYSO and CeBr3 crystals readout by SiPM

Organization of the lecture

Advances in Imaging Instrumentation for Nuclear Cardiology

Quantitative Nuclear Medicine Imaging

Learning Objectives By the end of this lesson you should…

Very High Energy Electron for Radiotherapy Studies

Reconstructions with TOF for in-beam PET

Application of Nuclear Physics

Positron Emission tomography

Assist. Prof. Dr. Ilker Ozsahin Oct

Presentation transcript:

Detector technologies: from particle physics to radiotherapy B. Camanzi STFC – RAL & University of Oxford

SEPnet RDI Kick-off Meeting 19/04/10 Outline Why cancer The detector challenges: dosimetry and imaging Positron Emission Tomography (PET) Time-Of-Flight PET Future activities Conclusions B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

The challenge of cancer in UK Cancer is the leading cause of mortality in people under the age of 75. 1 in 4 people die of cancer overall. 293k people/year diagnosed with cancer, 155k people/year die from cancer. Incidence of cancer is rising due to: Population ageing Rise in obesity levels Change in lifestyle Cancer 3rd largest NHS disease programme. B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

Radiotherapy and cancer in UK Radiotherapy given to 1/3 of cancer patients (10-15% of all population). Overall cure rate = 40%. In some instances 90-95% (for ex. breast and stage 1 larynx cancers). Radiotherapy often combined with other cancer treatments: Surgery Chemotherapy Hormone treatments B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

Radiotherapy treatments External beam radiotherapy: X-ray beam Electron beam Proton/light ion beam Internal radiotherapy: Sealed sources (brachytherapy) Radiopharmaceuticals Binary radiotherapy: Boron Neutron Capture Therapy (BNCT) Photon Capture Therapy (PCT) B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

The technological challenges The challenge of radiotherapy from the patient end Make sure that the right dose is delivered at the right place = improved dosimetry + improved imaging The challenge of early diagnosis “See” smaller tumours = improved imaging New advanced technologies desperately needed for dosimetry and imaging B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

How particle physics can help "The significant advances achieved during the last decades in material properties, detector characteristics and high-quality electronic system played an ever-expanding role in different areas of science, such as high energy, nuclear physics and astrophysics. And had a reflective impact on the development and rapid progress of radiation detector technologies used in medical imaging." “The requirements imposed by basic research in particle physics are pushing the limits of detector performance in many regards, the new challenging concepts born out in detector physics are outstanding and the technological advances driven by microelectronics and Moore's law promise an even more complex and sophisticated future.” D. G. Darambara "State-of-the-art radiation detectors for medical imaging: demands and trends" Nucl. Inst. And Meth. A 569 (2006) 153-158 B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 In-vivo dosimetry Radiation sensitive MOSFET transistors (RadFETs) used in particle physics experiments (BaBar, LHC, etc.) for real-time, online radiation monitoring. Development of RadFET based miniaturised wireless dosimetry systems to be implanted in patient body at tumour site for real-time, online, in-vivo dosimetry. B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 Imaging Most medical imaging systems, CT, gamma cameras, SPECT, PET, use particle physics technologies: scintillating materials, photon detectors, CCDs, etc. Courtesy Mike Partridge (RMH/ICR) Collimator Scintillator Diode CT scanner Gamma camera (SPECT) B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

Positron Emission Tomography 511 keV g 18F labelled glucose given to patients: e+ annihilates in two back-to-back 511 keV g. A ring of scintillating crystals and PMTs detects the g. Courtesy Mike Partridge (RMH/ICR) B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 Conventional PET Conventional PET scanner: Coincidences formed within a very short time window Straight line-of-response reconstructed Position of annihilation calculated probabilistically Courtesy Mike Partridge (RMH/ICR) PET CT PET + CT B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

Time-Of-Flight PET (TOF-PET) TOF-PET scanner: Time difference between signals from two crystals measured Annihilation point along line-of-response directly calculated Goal: 100 ps timing resolution (ideally 30 ps and below) = 3 cm spatial resolution (ideally sub-cm) Advantages: higher sensitivity and specificity, improved S/N Technology needed: fast scintillating materials and fast photon detectors B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

Fast scintillating materials Decay time (ns) Light yield (g/keV) Density (g/cm3) Latt at 511keV (cm) LaBr3(Ce) BrilLanCeTM380 16 63 5.3 2.23 LYSO PreLudeTM420 41 32 7.1 1.20 LSO 40 27 7.4 1.14 BGO 300 9 1.04 GSO 60 8 6.7 1.43 BaF2 0.8 1.8 4.9 2.20 NaI(Tl) 250 38 3.7 2.91 BrilLanCeTM380 and PreLudeTM420 produced by Saint-Gobain Cristaux et Detecteurs B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

Photon detectors: SiPMs Array of Silicon Photodiodes on common substrate each operating in Geiger mode SiPMs have speed (sub ns) and high gain (106), small size and work in high magnetic fields (7T) Hamamatsu Inc. 1x1 mm2 3x3 mm2 B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

Tests on TOF-PET prototypes LaBr3(Ce) and LYSO scintillating crystals from Saint-Gobain SiPMs from Hamamatsu, SensL and Photonique Various two-channel demonstrator systems tested at RAL and RMH Timing resolution analysis still ongoing B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 Preliminary results Best SiPMs: Hamamatsu (electrical problem with 11-25) and SensL. Best timing resolutions measured: 20 ps for single SiPM 40 ps for pairs of SiPMs Hamamatsu performance as function of pitch still under investigation. Prototypes with Hamamatsu 3x3 mm2 best of all. SensL blind to LaBr3. Best timing resolutions measured: 430 ps with 3x3x10 mm3 LYSO 790 ps with 3x3x30 mm3 LaBr3 Performance of prototypes with LaBr3 highly dependent from SiPM-crystal coupling. B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 Where next Preliminary results very encouraging. Need to investigate technology further: build a dual-head demonstrator system. Two planar heads with identical number of channels. Use of fast scintillators can be expanded to other imaging systems (CT, SPECT, etc.). Use of SiPMs opens up the possibility of designing a compact PET/MRI scanner. B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 Future activities Participation through Oxford to FP7 project ENVISION (European NoVel Imaging Systems for ION therapy). Development of a technology roadmap for cancer care, to move toward a multi-modality approach to radiotherapy. B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 ENVISION Participation in WP2: development of TOF in-beam PET systems. Oxford/STFC contributions: Characterisation of scintillating materials (LYSO and LaBr3) Characterisation of SiPMs Construction and test of a TOF-PET dual-head demonstrator system Simulations of component (crystals and SiPMs) and system performance B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

My vision: toward multi-modality Multi-modality = bringing together the different forms of radiotherapy treatments: Select best treatment depending on tumour type Combine different treatments when appropriate New advanced imaging and dosimetry systems of paramount importance → Technology roadmap Roadmap to be developed in consultation with end-user groups, universities, etc. B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 Conclusions Cancer is a leading cause of mortality in UK. Its incidence is rising. Radiotherapy is and will be given to a large number of patients. Patients will benefit from a multi-modality approach to radiotherapy. This requires the development of new, advanced technologies. Particle physics holds the key to the development of these technologies. B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10

SEPnet RDI Kick-off Meeting 19/04/10 Acknowledgements Prof Ken Peach (John Adams Institute) Dr Phil Evans and Dr Mike Partridge (Royal Marsden Hospital / Institute of Cancer Research) Gareth Derbyshire (STFC Healthcare Futures Programme) Dr John Matheson and Matt Wilson (STFC-RAL) B. Camanzi RAL & Oxford University SEPnet RDI Kick-off Meeting 19/04/10