Presentation is loading. Please wait.

Presentation is loading. Please wait.

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

Published byDwayne Dennis Modified over 6 years ago

Similar presentations

Presentation on theme: "Instrumentation for radiotherapy Imaging: 1. Fast Time Of Flight PET"— Presentation transcript:

1 Instrumentation for medical physics applications Barbara Camanzi, PPD/RAL
Instrumentation for radiotherapy Imaging: 1. Fast Time Of Flight PET 2. Electron Portal Imaging Devices In-vivo dosimetry Other non medical activities Conclusions

2 Instrumentation for radiotherapy
UK government is supporting expansion of radiotherapy for cancer treatment. New advanced instrumentation is needed => plenty of possibilities to apply particle physics techniques in the field of radiotherapy. Many thanks to RM/ICR colleagues. Instrumentation => Looking at the treatment from the patient end = to make sure that the right dose is delivered at the right side (tumour location). Right location = imaging P: Better and faster imaging of tumours (organs with high degree of movement) is needed to precisely located them in respect to the therapeutic beam. S: Development of a fast Time Of Flight PET. Development of fast Electron Portal Imaging Devices (EPIDs) with higher quantum efficiency than ones currently available (few %). Right dose = dosimetry P: EU directive for performing online dosimetry measurements for every patient and every treatment fraction. S: Development of an online in-vivo dosimetry system.

3 Imaging: Fast Time Of Flight PET
Fast high quality imagines to precisely locate the tumour: fast Time Of Flight PET that achieves sub-cm position resolution (50 ps timing resolution). Candidate technologies: fast scintillators coupled to SiPMs. 1. Fast and bright scintillators: new lanthanum halide materials by Saint- Gobain Crystals 2. SiPMs: fast and insensitive to magnetic fields => PET/MRI combined R&D required: 1. Preparation of scintillating material samples and coupling to SiPM. 2. Measurement of system performance: response time, light yield, energy resolution. 3. Design and optimisation of a simple demonstrator system: 2 channels. 4. Measurement of performance of demonstrator system: time of flight. Funds: 1. Just received some CLIK funds (£82.5k) for R&D stages 1. and 2. 2. Another application in with NHS (New and Emerging Applications of Technology call), outcome by end of May.

4 Imaging: Electron Portal Imaging Devices (EPIDs)
High quality radiography images taken during treatment using therapeutic beam to centre beam on tumour: fast and high quantum efficiency EPIDs placed behind patient. Candidate technologies: fast scintillators coupled to SiPMs. 1. fast scintillators: lanthanum halides, CsI, etc. 2. SiPMs: multipixels = high spatial resolution R&D required: 1. Design of an EPID based on scintillators coupled to SiPMs: dimensions, number of channels, etc. 2. Preparation of the scintillators and SiPMs matrixes and coupling of the two matrixes. 3. Measurement of the system performance: quantum efficiency, images. Funds: None yet. Planning to find a suitable funding scheme and apply during this year.

5 In-vivo dosimetry (See also Giulio Villani presentation)
In-vivo dosimetry at the tumour site: implantable + intracavitary applications. Candidate dosimeters: SiO2 devices sensitive to radiation = shift in threshold voltage following irradiation when biased with constant current. 1. Floating gate devices (see Giulio Villani talk) 2. RadFETs (Radiation sensitive MOSFETs; already used in particle physics experiments, for ex. BaBar and LHC) R&D required: 1. Characterisation of dosimeters under irradiation of “therapeutic” beams. 2. Implanted: development of a wireless miniaturised sensor combined with position sensor. 3. Intracavitary: development of a miniaturised sensor to fit in catheters. 4. Clinical trials. Funds: some CLIK funds to test floating gate devices (see Giulio Villani talk) and collaborations with Brunel (Akram Khan + PhD student) and possibly R.E.M. (Andrew Holmes-Siedle). Possibly look for other funds during this year.

6 Other non medical activities
Following invited talk at RADECS 2006, paper on dosimetry for particle accelerators and nuclear fusion reactors published in May 2008 issue of Nature Materials.

7 Conclusions Wealth of exciting projects to further take technologies developed for particle physics into the medical physics (radiotherapy) world. My plans: get for the moment three projects going. Potentials in other fields: nuclear fusion.

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

Similar presentations

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.

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.

Toward a multi-modality approach to radiotherapy for cancer treatment in UK (Unity is strength) Barbara Camanzi STFC – RAL & University of Oxford.
Electrical transport and charge detection in nanoscale phosphorus-in-silicon islands Fay Hudson, Andrew Ferguson, Victor Chan, Changyi Yang, David Jamieson,

Electrical transport and charge detection in nanoscale phosphorus-in-silicon islands Fay Hudson, Andrew Ferguson, Victor Chan, Changyi Yang, David Jamieson,
Recent news about SiPM based applications R&D in DESY Nicola D’Ascenzo University of Hamburg - DESY.

Recent news about SiPM based applications R&D in DESY Nicola D’Ascenzo University of Hamburg - DESY.
Alexander Klyachko, IU Cyclotron, PTCOG51, Seoul, South Korea, May 17-19, 2012 A.V. Klyachko 1, D.F. Nichiporov 1, L. Coutinho 2, C.-W. Cheng 2, 3, M.

Alexander Klyachko, IU Cyclotron, PTCOG51, Seoul, South Korea, May 17-19, 2012 A.V. Klyachko 1, D.F. Nichiporov 1, L. Coutinho 2, C.-W. Cheng 2, 3, M.
D.G.Lewis Department of Medical Physics Velindre Cancer Centre Whitchurch, Cardiff RT-GRID: Grid Computing for Radiotherapy.

D.G.Lewis Department of Medical Physics Velindre Cancer Centre Whitchurch, Cardiff RT-GRID: Grid Computing for Radiotherapy.
The TrueBeam System ™ Clinic Name Presenter’s name Clinic location

The TrueBeam System ™ Clinic Name Presenter’s name Clinic location
Andrei Nomerotski 1 Instrumentation for Medical Applications Andrei Nomerotski (Oxford Particle Physics) VC Forum, 17 November 2009.

Andrei Nomerotski 1 Instrumentation for Medical Applications Andrei Nomerotski (Oxford Particle Physics) VC Forum, 17 November 2009.
Tagger Electronics Part 1: tagger focal plane microscope Part 2: tagger fixed array Part 3: trigger and digitization Richard Jones, University of Connecticut.

Tagger Electronics Part 1: tagger focal plane microscope Part 2: tagger fixed array Part 3: trigger and digitization Richard Jones, University of Connecticut.
The Tagger Microscope Richard Jones, University of Connecticut Hall D Tagger - Photon Beamline ReviewJan. 23-24, 2005, Newport News presented by GlueX.

The Tagger Microscope Richard Jones, University of Connecticut Hall D Tagger - Photon Beamline ReviewJan , 2005, Newport News presented by GlueX.
Stereotactic Body Radiation Therapy (SBRT): The optimal indication for operable tumors in inoperable patients D.Katsochi 1, S.Kosmidis 1, A.Fotopoulou.

Stereotactic Body Radiation Therapy (SBRT): The optimal indication for operable tumors in inoperable patients D.Katsochi 1, S.Kosmidis 1, A.Fotopoulou.
Detector technologies: from particle physics to radiotherapy

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

Instrumentation for medical physics applications Barbara Camanzi, PPD/RAL Instrumentation for radiotherapy Imaging: 1. Fast Time Of Flight PET 2. Electron.
WP4: Applications of Accelerators

WP4: Applications of Accelerators
B W Kennedy, CCLRC Rutherford Appleton Laboratory VPTs for the CMS experiment B W Kennedy CCLRC Rutherford Appleton Laboratory St Petersburg, 26 April.

B W Kennedy, CCLRC Rutherford Appleton Laboratory VPTs for the CMS experiment B W Kennedy CCLRC Rutherford Appleton Laboratory St Petersburg, 26 April.
Introduction to Nuclear Medicine

Introduction to Nuclear Medicine
1 Scintillators  One of the most widely used particle detection techniques Ionization -> Excitation -> Photons -> Electronic conversion -> Amplification.

1 Scintillators  One of the most widely used particle detection techniques Ionization -> Excitation -> Photons -> Electronic conversion -> Amplification.
In vivo dosimetry Eirik Malinen Eva Stabell Bergstrand Dag Rune Olsen.

In vivo dosimetry Eirik Malinen Eva Stabell Bergstrand Dag Rune Olsen.
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,

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,
Training Module 3 – Version 1.1 For Internal Use Only ® Radiation Therapy 

Training Module 3 – Version 1.1 For Internal Use Only ® Radiation Therapy 

Similar presentations

Ads by Google