Fundamental Limits of Positron Emission Tomography

Slides:



Advertisements
Similar presentations
Topic 8. Gamma Camera (II)
Advertisements

6: Positron Emission Tomography
Study of plastic scintillators for fast neutron measurements
PET Design: Simulation Studies using GEANT4 and GATE - Status Report - Martin Göttlich DESY.
Chapter 8 Planar Scintigaraphy
Computed Tomography II
Semiconductor detectors for Compton imaging in nuclear medicine
High granularity to reduce the effect of the “prompt flash” radiation Polarization sensitivity Imaging capabilities for background suppression DESPEC (DEcay.
Fysisk institutt - Rikshospitalet 1. 2 Overview Gamma camera Positron emission technology (PET) Computer tomography (CT) Proton therapy Electrical impedance.
Synergies Between Calorimetry and PET William W. Moses Lawrence Berkeley National Laboratory March 26, 2002 Outline: –Fundamentals of PET –Comparison of.
Medical Imaging Mohammad Dawood Department of Computer Science University of Münster Germany.
Medical Imaging Mohammad Dawood Department of Computer Science University of Münster Germany.
BMME 560 & BME 590I Medical Imaging: X-ray, CT, and Nuclear Methods Tomography Part 3.
Examples of GATE simulation Yun Dong. Different systems available in GATE Scanner: most generic system; Cylindrical PET: cylindrical geometry; CPET: simulate.
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,
Signal Analysis and Processing David Scraggs. Overview Introduction to Position Resolution Induced Charges Wavelet Transform Future Work Discussion.
Images. Pinhole Lens Photons from a source can be focused by a small aperture. –Aperture radius a –Magnification m –Image is inverted Image is blurry.
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.
Simulations with MEGAlib Jau-Shian Liang Department of Physics, NTHU / SSL, UCB 2007/05/15.
VALENCIA b mass effects at the Z 0 peak from 3 and 4 jet events P. Bambade, M.J. Costa, J. Fuster and P. Tortosa b mass effects have been.
Planar scintigraphy produces two-dimensional images of three dimensional objects. It is handicapped by the superposition of active and nonactive layers.
8/18/2015G.A. Fornaro Characterization of diffractive optical elements for improving the performance of an endoscopic TOF- PET detector head Student: G.
Dose Distribution and Scatter Analysis
EDS Energy Dispersive Spectroscopy
Design and simulation of micro-SPECT: A small animal imaging system Freek Beekman and Brendan Vastenhouw Section tomographic reconstruction and instrumentation.
Medical Image Analysis Dr. Mohammad Dawood Department of Computer Science University of Münster Germany.
M. Alnafea1*, K. Wells1, N.M. Spyrou1 & M. Guy2
Review of Ultrasonic Imaging
Bayesian Estimation for Angle Recovery: Event Classification and Reconstruction in Positron Emission Tomography A.M.K. Foudray, C.S. Levin Department.
A Front End and Readout System for PET Overview: –Requirements –Block Diagram –Details William W. Moses Lawrence Berkeley National Laboratory Department.
Course 9 Texture. Definition: Texture is repeating patterns of local variations in image intensity, which is too fine to be distinguished. Texture evokes.
HEALTH Novel MR-compatible PET detectors for simultaneous PET/MRI imaging FP7-HEALTH-2009-single-stage The focus should be to develop novel.
BMI I FS05 – Class 4 “Nuclear Imaging: Math” Slide 1 Biomedical Imaging I Class 5 – Radionuclide Imaging (PET, SPECT), Part 3: Attenuation and Scatter.
Professor Brian F Hutton Institute of Nuclear Medicine University College London Emission Tomography Principles and Reconstruction.
PET/SPECT Phantom. Side View of Phantom Image Resolution Intrinsic resolution FWHM Intrinsic resolution FWHM Field of view Field of view Measurement:
Pedro Arce Introducción a GEANT4 1 GAMOS tutorial Compton Camera Exercises
Active Pixel Sensors in Nuclear Medicine Imaging RJ Ott, N Evans, P Evans, J Osmond, A Clark, R Turchetta Physics Department Institute of Cancer Research.
Li HAN and Neal H. Clinthorne University of Michigan, Ann Arbor, MI, USA Performance comparison and system modeling of a Compton medical imaging system.
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.
Development of a Segmented Planar Germanium Imaging Detector
Nuclear Medicine Principles & Technology_I
A Single Photon Emission Computer Tomograph for breast cancer imaging S. Vecchio a, N. Belcari a, P. Bennati b, M. Camarda a, R. Campanini c, M. N. Cinti.
Medical applications of particle physics General characteristics of detectors (5 th Chapter) ASLI YILDIRIM.
Tracking Background GRETINA Software Working Group Meeting September 21-22, 2012, NSCL MSU I-Yang Lee Lawrence Berkeley National Laboratory.
Improved Hybrid PET Imaging Using Variable Focal Length Fan-Slat Collimators Thomas C. Rust and Dan J. Kadrmas, Ph.D. Medical Imaging Research Laboratory.
1 Nuclear Medicine SPECT and PET. 2 a good book! SR Cherry, JA Sorenson, ME Phelps Physics in Nuclear Medicine Saunders, 2012.
Acquisition time6 min1 min 12 s Collimator height25 mm (Anger)12 mm (HiSens) Detector1 layer, 1 pixel / hole3 layers, 1 pixel / hole3 layers, 4 pixels.
Nuclear Medicine Physics and Equipment 243 RAD 1 Dr. Abdo Mansour Assistant Professor of radiology
Thickness of CZT detector 110 MeV140 MeV DETECTOR A (1 mm CZT + 5 mm CZT) DETECTOR B (1 mm CZT + 10 mm CZT) DETECTOR C (1 mm CZT + 15 mm CZT) A. Generation.
Chapter-2 The Planar Imaging Important points in chapter 2 (chapter 13 from the book) The gamma camera (the basic principles of the gamma camera) The types.
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,
Chapter-5 Positron emission tomography (PET)
P.E.T. Positron Emission Tomography
CT Multi-Slice CT.
Imaging molecolare ad alta risoluzione spaziale ed alta efficienza
Image quality and Performance Characteristics
Image quality and Performance Characteristics
Reconstructions with TOF for in-beam PET
Detailed simulations of a full-body RPC-PET scanner
Summary of the Compton-PET project
Chapter 8: Generic performance measures
Single Photon Emission Tomography
Review of Ultrasonic Imaging
Function and Structure in
Gamma Camera Ilker Ozsahin Oct
First demonstration of portable Compton camera to visualize 223-Ra concentration for radionuclide therapy Kazuya Fujieda (Waseda University) J. Kataoka,
Assist. Prof. Dr. Ilker Ozsahin Oct
COMPTON SCATTERING IN FORWARD DIRECTION
Presentation transcript:

Fundamental Limits of Positron Emission Tomography William W. Moses Lawrence Berkeley National Laboratory Department of Functional Imaging September 5, 2002 Outline: Spatial Resolution Efficiency Noise Other Modalities (Best Viewed in “Slide Show” Mode)

Positron Emission Tomography (PET) Ring of Photon Detectors Patient injected with positron (+ ) emitting radiopharmaceutical. + annihilates with e– from tissue, forming back-to-back 511 keV photon pair. 511 keV photon pairs detected via time coincidence. Positron lies on line defined by detector pair (i.e., chord). Reconstruct 2-D Image using Computed Tomography Multiple Detector Rings  3-D Volumetric Image

Fundamental Limits of Spatial Resolution Dominant Factor is Crystal Width Limit for 80 cm Ring w/ Block Detectors is 3.6 mm Ultimate Limit is 0.6 mm (Positron Range)

Radial Elongation Penetration of 511 keV photons into crystal ring blurs measured position. Blurring worsens as detector’s attenuation length increases. Effect variously known as Radial Elongation, Parallax Error, or Radial Astigmatism. Can be removed (in theory) by measuring depth of interaction. Tangential Projection Radial Projection

Spatial Resolution Away From Center Point Source Images in 60 cm Ring Diameter Camera 1 cm Near Tomograph Center 14 cm from Tomograph Center Resolution Degrades Significantly...

Theoretical Spatial Resolution (all units in mm) d = Crystal Width R = Detector Ring Radius r = Distance from Center of Tomograph

Spatial Resolution is Defined Assuming Infinite Statistics Caveat: Spatial Resolution is Defined Assuming Infinite Statistics Resolution Does Not Include Effects from Noise, but Image Quality Does...

Effect of Noise On Image Quality 55M Events 3 mm fwhm 1M Events 3 mm fwhm 1M Events 6 mm fwhm All Three Images Have Same Camera Resolution Statistical Noise  Reduced Image Resolution

Low Image Noise  High Sensitivity Sensitivity Definition: Place 20 cm diameter phantom in camera. Measure True Event Rate. Sensitivity = True Event Rate / µCi / cc. Sensitivity Measures Efficiency for Detecting Signal

Increase Sensitivity by Removing Septa Inter-Plane Septa No Septa 2-D (w/ Septa) Septa Reduce Scatter  Smaller Solid Angle for Trues 3-D (w/o Septa) No Scatter Suppression  Larger Solid Angle for Trues

Sensitivity Includes Noise from Background T = Trues S = Scatter R = Randoms Even when you subtract the background, statistical noise from the background remains. Image Noise Not Determined by Sensitivity Alone!

Noise Equivalent Count Rate (NECR) NECR Properties: Like a Signal / Noise Ratio (Sensitivity only Includes Signal) Includes Noise from Backgrounds Maximize NECR to Minimize Image Noise

NEC Properties T Obeys Counting Statistics Equals Signal x Contrast Phantom Geometry Must Be Defined Usually 20 cm diameter, 20 cm tall cylinder T

NEC Behavior: Ideal Camera (No Dead Time, No Coincidence Processor Limit) NEC Plateaus as Activity () Increases!

NEC Behavior (With Dead Time, No Coincidence Processor Limit) Tdead  e–( t) Rdead  2e–( t) Dead Time (t) reduces T and R by same factor. As  increases, NEC eventually decreases (paralyzing dead time).

NEC Behavior (With Dead Time and Coincidence Processor Limit) RCP = Max. Rate TCP = Max. Rate Tdead  e–( t) Rdead  2e–( t) Tdead Rdead Total throughput becomes constant (T+2R = Max. Rate). True / Randoms ratio not affected by rate limit. R  constant, T  1/.

More Solid Angle Is Not Always Better... 20 cm Phantom 3-D has Higher NECR at Low Activity Peak NECR in 2-D > Peak NECR in 3-D (Less Scatter)

Noise From Reconstruction Algorithm Basic measurement of chord (crystal-crystal coincidence) represents the integral of the activity along that line. Measurements from other chords needed to constrain activity to its source voxel. Activity in other voxels complicates the image reconstruction. Signals from Different Voxels are Coupled Statistical Noise from One Voxel Affects All Voxels

Point-Like Objects Reconstruct with Less Noise Object Dependence “Point-Like” Object 100,000 Events “Uniform” Object 1,000,000 Events Point-Like Objects Reconstruct with Less Noise

PET Take-Home Messages Spatial Resolution Dominated by Crystal Size Other effects can be important at high resolution No Intrinsic Resolution / Efficiency Tradeoff, but Effective Tradeoffs Because of Noise Noise from Counting Statistics: Depends on Camera Efficiency / Geometry Higher Efficiency Doesn’t Always Imply Lower Noise! Noise from Reconstruction Algorithm: Depends on Object Geometry Think About Signal/Noise, Not Just Signal!!!

How Does PET Compare to Other Modalities? Parallel Hole Collimator Pinhole Collimator Coded Aperture Compton Camera

Parallel Hole Collimator Properties Gamma Detector Typical Values: w= 2 mm L= 30 mm t= 0.25 mm Collimator Collimator Geometry Defines Acceptance Angle 

Spatial Resolution Resolution Proportional to  Typical Values: R= 6 mm (@ 5 cm) R= 12 mm (@ 10 cm) Resolution Proportional to  Resolution Proportional to Distance from Source

Efficiency Efficiency Proportional to 2 Typical Values: Efficiency = 0.02% Efficiency Proportional to 2 Efficiency Independent of Distance from Source

Pinhole Camera Compared to Parallel Hole Collimator, Pinhole  Different Resolution / Efficiency Tradeoff Higher Resolution, but Smaller Field of View

Coded Aperture Camera Compared to Pinhole Camera, Many (n) Pinholes  Similar Resolution w/ Higher Efficiency

Image Overlap with Coded Apertures “Point-Like” Object “Uniform” Object Removing the Overlap Increases the Noise Noise Increase Depends on Object

Intrinsic Resolution / Efficiency Dependency Dependence on: w d L Par. Hole Resol. w d L-1 Effic. w2 – L-2 Area – – – Pinhole/CA Resol. w – – Effic. w2 d-2 – Area – d L-1 Gamma Detector Generic Collimating Structure Very Different Geometrical Dependencies Pinhole / Aperture Best for Small Area, High Resol.

No Collimator, but Reconstruction Difficult Compton Cameras How They Work: • Measure first interaction with good Energy resolution. • Measure first and second interaction with moderate Position resolution. • Compton kinematics determines scatter angle. • Source constrained to lie on the surface of a cone. No Collimator, but Reconstruction Difficult

Compton Camera Tradeoffs Advantages: No Intrinsic Resolution / Efficiency Tradeoff (Resolution Limited by Energy Resolution) No Collimator  Much Higher Efficiency Large Imaging Volume Disadvantages: “Value” of Each Gamma is Lower Difference in “Value” Depends on Object (“Point-Like” Objects are Better) Random Coincidence Background / NEC

Detected Events Can Have Different Values Compton Cone Surface PET Thin Line Collimator Thin Cone Pinhole Thin Cone Coded Aperture Thin Cones Value Inversely Proportional to Volume of Object that the Gamma Could Have Come From?

Conclusions Different Modalities Have Different Imaging Tradeoffs Resolution, Efficiency, Noise, Imaging Volume Consider Noise As Well As Signal Counting Statistics Background Events Reconstruction Algorithms Complex Sources Some Gammas Are Worth More Than Others Volume that Detected Gamma Could Have Come From Value Can Be Estimated Using Simulation Use Reasonable Source Geometry & Number of Events Include All Background Sources

Acknowledgements U.S. Department of Energy Office of Environmental and Biological Research Laboratory Technology Research Division National Institutes of Health National Cancer Institute University of California Office of the President Breast Cancer Research Program U.S. Army Breast Cancer Directive Commercial Partners Capintec, Inc. Digrad, Inc.

Principle of Computed Tomography 2-Dimensional Object 1-Dimensional Horizontal Projection 1-Dimensional Vertical Projection By measuring all 1-dimensional projections of a 2-dimensional object, you can reconstruct the object

Separates Objects on Different Planes Computed Tomography Planar X-Ray Computed Tomography Separates Objects on Different Planes Images courtesy of Robert McGee, Ford Motor Company