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Printable Handouts
Navigable Slide Index
- Introduction
- Outline
- What is PET?
- Principles of PET imaging
- The PET process
- Why positron emitters
- Positron decay
- Nuclide production
- Decay schemes 18-F
- The PET process
- Image reconstruction
- Different views when using PET scan
- The process of image formation in details
- Annihilation
- LOR determination
- Singles detection and processing
- Event detection
- Physics properties of PET scintillators
- Detector/photomultiplier design
- Energy trigger, measurement and qualification
- Event positioning (1)
- Event positioning (2)
- Coincidence assessment of singles events
- Steps involved in coincidence assessment
- Coincidence acceptance angle (Transverse)
- Coincidence acceptance angle (Axial)
- Coincidence timing comparison
- Overall LOR determination process
- LOR data storage
- Sample sinograms
- Detector assembly
- Direct and cross planes
- Axial sampling and slice sensitivity
- Michelograms
- Further improvement in sensitivity
- 2D and 3D
- Inter-plane septa
- Type of recorded events
- Two ways of measuring randoms in PET
- Randoms estimation
- Scatter
- Extent of scatter in PET images
- KCPS vs. activity concentration
- Scatter correction
- Power of PET by quantification (1)
- Power of PET by quantification (2)
- Normalization
- Dead-time
- Decay correction
- Geometric correction
- Attenuation correction (1)
- Attenuation correction (2)
- Attenuation measurement
- Calculated attenuation correction
- Segmented attenuation correction
- Effect of attenuation correction on PET image
- CT based attenuation correction
- Calibration
- Factors affecting image resolution
- Detectors
- Detector size
- Depth of interaction
- Resolution improvement (1)
- Resolution improvement (2)
- Positron range (1)
- Positron range (2)
- Non co-linearity
- Linear and angular sampling
- Image matrix
- Reconstruction filter (1)
- Reconstruction filter (2)
Topics Covered
- Principles of PET imaging
- The PET process
- Positron decay
- Nuclide production
- Decay schemes of 18-F
- Image reconstruction
- Different views when using PET scanners
- The process of image formation in details
- Annihilation
- Detector/photomultiplier design
- Energy trigger, measurement and qualification
- Event positioning
- Coincidence assessment of singles events
- Steps involved in coincidence assessment
- Coincidence acceptance angles (Transverse & Axial)
- Coincidence timing comparison
- Overall LOR determination process
- LOR data storage
- Sample sinograms
- Detector assembly
- Direct and cross planes
- Axial sampling and slice sensitivity
- Michelograms
- Further improvement in sensitivity
- 2D and 3D
- Inter-plane septa
- Type of recorded events
- Two ways of measuring randoms in PET
- Randoms estimation
- Scatter and its extent in PET images
- KCPS vs. activity concentration
- Scatter correction
- Power of PET by quantification
- Normalization
- Dead-time
- Decay correction
- Geometric correction
- Attenuation measurement
- Calculated attenuation correction
- Segmented attenuation correction
- Effect of attenuation correction on PET image
- CT based attenuation correction
- Calibration
- Factors affecting image resolution
- Detector size
- Depth of interaction
- Resolution improvement
- Positron range
- Non co-linearity
- Linear and angular sampling
- Image matrix
- Reconstruction filter
Talk Citation
Mawlawi, O. (2022, July 14). Fundamental principles of positron emission tomography (PET) 1 [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 26, 2024, from https://doi.org/10.69645/TZLU4391.Export Citation (RIS)
Publication History
Financial Disclosures
- Dr. Osama Mawlawi has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Update Available
The speaker addresses developments since the publication of the original talk. We recommend listening to the associated update as well as the lecture.
- Full lecture Duration: 55:30 min
- Update interview Duration: 24:10 min
Fundamental principles of positron emission tomography (PET) 1
A selection of talks on Methods
Transcript
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0:00
This talk is on the fundamental principles of
positron emission tomography, or PET imaging.
My name is Osama Mawlawi, and I'm
an associate professor at the Department of Imaging Physics at the University of Texas
MD Anderson Cancer Center in Houston, Texas.
0:20
In this talk, we will cover PET signal detection,
processing, and image generation.
We will also cover factors affecting PET image resolution,
sensitivity and contrast, as well as quantification.
We will also discuss the data acquisition schemes such as static,
dynamic and gated, and cover scanner designs and their current status vis-a-vis
the dedicated scanners that are out there, as well as
the PET/CT scanners that are currently available from different manufacturers.
We will finish by giving a brief discussion
of radiation exposure using PET/CT imaging.
1:02
What is PET imaging?
PET is a functional imaging modality as compared to a structural modality.
By 'functional', we mean that the resulting images
show us biological processes such as blood-flow,
glucose metabolism, or receptor density.
Directly off the bat,
we can see that the PET image is not characterized by
high resolution as compared to their MR and CT counterparts seen on this slide.
However, what is unique about PET imaging is that it can give us
specific information about the underlying biological process.
For example, the image in the bottom left shows
the PET image of a patient undergoing visual stimulation.
The visual stimulation causes blood to rush to the occipital cortex,
which is involved in processing visual information.
The PET image captures this process, and also indicates the extent of blood flow
by also providing information about the intensity of the signal in the occipital region.
Similar information can be extracted from PET images on glucose metabolism,
receptor density, and other biological processes,
for example in the image in the middle of glucose metabolism,
we can assess whether there are any
laterality differences between the left and right hemisphere of this patient study.
Also in the image on the right,
we can see whether the patient is suffering from any neurological disorder,
by assessing the receptor densities in different parts of the brain.
This information is very helpful for physicians to
manage their patient in a superior manner.