PET Scans Show Dynamic Function of Multiple Organs
By MedImaging International staff writers Posted on 30 Jan 2020 |
Image: Full body PET/CT on the Explorer scanner (Photo courtesy of UCD)
A new study demonstrates a positron emission tomography (PET) image reconstruction method that helps researchers capture real-time videos of blood flow and heart function.
Researchers at the University of California Davis (UCD; USA) and Fudan University (Shanghai, China) have developed new methods to reduce noise and reconstruct video images from raw data of volunteers scanned by the Explorer, a full body PET and x-ray computed tomography (CT) scanner that can evaluate all body organs and tissues simultaneously. They were able to see changes on a scale of 100 milliseconds (one-tenth of a second), and use these to create high quality real-time movies of the scans.
For example, Explorer quantitatively measured blood flow, glucose uptake all over the body at the same time, cancer metastasis beyond the single tumor site, inflammation and infection, and immunological or metabolic disorders, as well as many other diseases. In one scan shown, a volunteer injected in with a short-lived radioactive tracer was scanned in real-time, showing the tracer moving up the body to the heart, flowing through the right ventricle to the lungs, back through the left ventricle and on to the rest of the body. Another video shows heart motion and cardiac contraction with clear delineation of the end-systolic and end-diastolic phases. The study was published on January 20, 2020, in Proceedings of the National Academy of Sciences (PNAS).
“It's a combination of the scanner and advanced data reconstruction methods that make this possible. The tradeoff between image quality, acquisition time, and injected radiation dose will vary for different applications,” said lead author Xuezhu Zhang , PhD, of UCD. “This has applications in real-time tracking of blood flow over the human circulatory system, motion-frozen heart beating, and breathing monitoring for cardiovascular and cerebrovascular disease and analysis of respiratory system function.”
PET is a nuclear medicine imaging technique that produces a 3D image of functional processes in the body. The system detects pairs of gamma rays emitted indirectly by a positron-emitting radionuclide tracer. Tracer concentrations within the body are then constructed into a 3D image by computer analysis. In modern PET-CT scanners, 3D imaging is often accomplished with the aid of a CT X-ray scan performed on the patient during the same session, in the same machine.
Related Links:
University of California Davis
Fudan University
Researchers at the University of California Davis (UCD; USA) and Fudan University (Shanghai, China) have developed new methods to reduce noise and reconstruct video images from raw data of volunteers scanned by the Explorer, a full body PET and x-ray computed tomography (CT) scanner that can evaluate all body organs and tissues simultaneously. They were able to see changes on a scale of 100 milliseconds (one-tenth of a second), and use these to create high quality real-time movies of the scans.
For example, Explorer quantitatively measured blood flow, glucose uptake all over the body at the same time, cancer metastasis beyond the single tumor site, inflammation and infection, and immunological or metabolic disorders, as well as many other diseases. In one scan shown, a volunteer injected in with a short-lived radioactive tracer was scanned in real-time, showing the tracer moving up the body to the heart, flowing through the right ventricle to the lungs, back through the left ventricle and on to the rest of the body. Another video shows heart motion and cardiac contraction with clear delineation of the end-systolic and end-diastolic phases. The study was published on January 20, 2020, in Proceedings of the National Academy of Sciences (PNAS).
“It's a combination of the scanner and advanced data reconstruction methods that make this possible. The tradeoff between image quality, acquisition time, and injected radiation dose will vary for different applications,” said lead author Xuezhu Zhang , PhD, of UCD. “This has applications in real-time tracking of blood flow over the human circulatory system, motion-frozen heart beating, and breathing monitoring for cardiovascular and cerebrovascular disease and analysis of respiratory system function.”
PET is a nuclear medicine imaging technique that produces a 3D image of functional processes in the body. The system detects pairs of gamma rays emitted indirectly by a positron-emitting radionuclide tracer. Tracer concentrations within the body are then constructed into a 3D image by computer analysis. In modern PET-CT scanners, 3D imaging is often accomplished with the aid of a CT X-ray scan performed on the patient during the same session, in the same machine.
Related Links:
University of California Davis
Fudan University
Latest General/Advanced Imaging News
- Bone Density Test Uses Existing CT Images to Predict Fractures
- AI Predicts Cardiac Risk and Mortality from Routine Chest CT Scans
- Radiation Therapy Computed Tomography Solution Boosts Imaging Accuracy
- PET Scans Reveal Hidden Inflammation in Multiple Sclerosis Patients
- Artificial Intelligence Evaluates Cardiovascular Risk from CT Scans
- New AI Method Captures Uncertainty in Medical Images
- CT Coronary Angiography Reduces Need for Invasive Tests to Diagnose Coronary Artery Disease
- Novel Blood Test Could Reduce Need for PET Imaging of Patients with Alzheimer’s
- CT-Based Deep Learning Algorithm Accurately Differentiates Benign From Malignant Vertebral Fractures
- Minimally Invasive Procedure Could Help Patients Avoid Thyroid Surgery
- Self-Driving Mobile C-Arm Reduces Imaging Time during Surgery
- AR Application Turns Medical Scans Into Holograms for Assistance in Surgical Planning
- Imaging Technology Provides Ground-Breaking New Approach for Diagnosing and Treating Bowel Cancer
- CT Coronary Calcium Scoring Predicts Heart Attacks and Strokes
- AI Model Detects 90% of Lymphatic Cancer Cases from PET and CT Images
- Breakthrough Technology Revolutionizes Breast Imaging