Presentation is loading. Please wait.

Presentation is loading. Please wait.

0 A Fast Time Incorporating Monte-Carlo Simulation of Wire Chamber Based Small Animal PET Scanners for Detector Scatter Correction M. Dawood 1, Don Vernekohl.

Published byHector Pitts Modified over 9 years ago

Similar presentations

Presentation on theme: "0 A Fast Time Incorporating Monte-Carlo Simulation of Wire Chamber Based Small Animal PET Scanners for Detector Scatter Correction M. Dawood 1, Don Vernekohl."— Presentation transcript:

1 0 A Fast Time Incorporating Monte-Carlo Simulation of Wire Chamber Based Small Animal PET Scanners for Detector Scatter Correction M. Dawood 1, Don Vernekohl 2, K. P. Schäfers 1 1 European Institute for Molecular Imaging, University of Münster 2 Institute for Mathematics, University of Münster

2 1 Scatter correction scheme Use measured (trues+scatter) data to simulate scatter Subtract simulated scatter from data Reconstrut correced data

3 2 HIghgDensity AvalanchingvCathode Detector quadHIDAC 16 cm 28 cm

4 3 quadHIDAC converter Photon Electrons Lead Insulation 0.4 mm Holes Converter for detection of the gamma photons

5 4 quadHIDAC module Anode wires Y-Cathode tracks X-Cathode tracks Converter A Converter B Photon

6 5 Detector scatter Detector scatter : compton & elastic scatter Detector Scatter:~ 40 % of all events Attenuated events:~ 8 % (mouse)

7 6 Remodeling the converters Lead density ρNew lead density ρ‘ 0.0113 g/mm 3 0.0018 g/mm 3 Lead density adjustment for change in volume and surface

8 7 Fast Monte-Carlo simulation Physics – All events are generated at once – Propogation until detectors are reached

9 8 Fast Monte-Carlo simulation Scattered True Undetected Physics – Simulation of photo, compton, and thompson events

10 9 Time component Time stamps assigned to all events Time windows – Coincidence window 40 ns – Dead time 160 ns – Coincidence deadtime 400 ns

11 10 Time component Even and odd converters are grouped Dead time is dependent on the even and odd converters

12 11 Dead time effects Trues vs Activity curve shows the effect of deadtime

13 12 Scatter distribution SimulationGeant Transversal cross section of a simulated point source

14 13 Scatter distribution on the detectors X-Coordinate # of events

15 14 Point source TruesTrues + ScatterCorrected EMrecon algorithm and scatter correction see: M13-7, Scatter and Random Corrections…, Vernekohl et al. Today, 16:30-18:30 Hall B2 10 Million annihilations simulated at the center of the FOV

16 15 Scatter estimate in a mouse Scatter estimated from a mouse dataset GEANT Simulation Coronal sliceSagital slice

17 16 Mouse data Uncorrected Mouse Data GEANT CorrectedSimulation Corrected

18 17 Computational efficiency The simulation in „Matlab“ – 1 Million positron annihilations ~ 1.2 hour vs. ~ 8 hours with GEANT (single processor) – Parallel computation implemented ~ 10 Min with 12 processors

19 18 Thank you for your attention!

Download ppt "0 A Fast Time Incorporating Monte-Carlo Simulation of Wire Chamber Based Small Animal PET Scanners for Detector Scatter Correction M. Dawood 1, Don Vernekohl."

Similar presentations

Topic 8. Gamma Camera (II)

Topic 8. Gamma Camera (II)
POLARIMETRY of MeV Photons and Positrons Overview Beam Characterization – undulator photons – positrons Basics of the Transmission Method – for photon.

POLARIMETRY of MeV Photons and Positrons Overview Beam Characterization – undulator photons – positrons Basics of the Transmission Method – for photon.
GEANT Simulation of RCS Vahe Mamyan Hall A Analysis Workshop December 10, 2003.

GEANT Simulation of RCS Vahe Mamyan Hall A Analysis Workshop December 10, 2003.
What are PET basics?.

What are PET basics?.
Computers and Computed Tomography

Computers and Computed Tomography
Image Reconstruction.

Image Reconstruction.
6: Positron Emission Tomography

6: Positron Emission Tomography
1 Continuous Scintillator Slab with Microchannel Plate PMT for PET Heejong Kim 1, Chien-Min Kao 1, Chin-Tu Chen 1, Jean-Francois Genat 2, Fukun Tang 2,

1 Continuous Scintillator Slab with Microchannel Plate PMT for PET Heejong Kim 1, Chien-Min Kao 1, Chin-Tu Chen 1, Jean-Francois Genat 2, Fukun Tang 2,
Fysisk institutt - Rikshospitalet 1. 2 Overview Gamma camera Positron emission technology (PET) Computer tomography (CT) Proton therapy Electrical impedance.

Fysisk institutt - Rikshospitalet 1. 2 Overview Gamma camera Positron emission technology (PET) Computer tomography (CT) Proton therapy Electrical impedance.
Medical Imaging Mohammad Dawood Department of Computer Science University of Münster Germany.

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

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

Medical Imaging Mohammad Dawood Department of Computer Science University of Münster Germany.
Imaging PET Course Layout Class + ContentDateClass Physical Principles of PET23.2.2005I Physical principles of MRI2.3.2005II Imaging applications9.3.2005III.

Imaging PET Course Layout Class + ContentDateClass Physical Principles of PET I Physical principles of MRI II Imaging applications III.
Mar 31, 2005Steve Kahn -- Ckov and Tof Detector Simulation 1 Ckov1, Ckov2, Tof2 MICE Pid Tele-Meeting Steve Kahn 31 March 2005.

Mar 31, 2005Steve Kahn -- Ckov and Tof Detector Simulation 1 Ckov1, Ckov2, Tof2 MICE Pid Tele-Meeting Steve Kahn 31 March 2005.
Transforming Static CT in Gated PET/CT Studies to Multiple Respiratory Phases M Dawood, F Büther, N Lang, X Jiang, KP Schäfers Department of Nuclear Medicine,

Transforming Static CT in Gated PET/CT Studies to Multiple Respiratory Phases M Dawood, F Büther, N Lang, X Jiang, KP Schäfers Department of Nuclear Medicine,
Slow Neutron Background Simulation Long-lived neutrons created, diffuse around collision hall They get captured by nuclei, emitting a photon Compton.

Slow Neutron Background Simulation " Long-lived neutrons created, diffuse around collision hall " They get captured by nuclei, emitting a photon " Compton.
Neutron Background Simulation Long-lived neutrons created, diffuse around collision hall They get captured by nuclei, emitting a photon Compton scattering.

Neutron Background Simulation Long-lived neutrons created, diffuse around collision hall They get captured by nuclei, emitting a photon Compton scattering.
Planar scintigraphy produces two-dimensional images of three dimensional objects. It is handicapped by the superposition of active and nonactive layers.

Planar scintigraphy produces two-dimensional images of three dimensional objects. It is handicapped by the superposition of active and nonactive layers.
Derek Liu E. Poon, M. Bazalova, B. Reniers, M. Evans

Derek Liu E. Poon, M. Bazalova, B. Reniers, M. Evans
Coincidence to Image: PET Imaging Jennifer White Marketing Manager SNS Workshop October 13, 2003.

Coincidence to Image: PET Imaging Jennifer White Marketing Manager SNS Workshop October 13, 2003.

Similar presentations

Ads by Google