Iterative reconstruction (CT)
Iterative reconstruction refers to an image reconstruction algorithm used in CT that begins with an image assumption, and compares it to real time measured values while making constant adjustments until the two are in agreement.
Computer technology limited early scanners in their ability to perform the iterative reconstruction. However, this image reconstruction algorithm is now widely used due to the improvement of computer technology over the past decade.
Its ability to overcome noise associated with filtered back projection without increasing radiation dose has had a significant impact on the computed tomography image reconstruction industry 1-4.
Stages of iterative reconstruction
Iterative reconstruction has three distinct stages. This is, of course, a simplified overview of iterative reconstruction without statistical modelling 1,3.
Using the raw data produced by the computed tomographic scanner a standard filtered back projection algorithm is utilised to create a primary image.
Image reconstruction loop
- forward projection to the primary image to create artificial raw data
- simulated data is then correlated to the measured raw data where an updated image is generated.
- filtered back projection is used to back-project the updated image onto the new updated imaged; this is repeated until the differences in the images reach a preset value.
The final back projection image that is produced.
Model-based iterative reconstruction
Iterative reconstruction has undergone notable improvement with the introduction of 'model-based iterative reconstruction'. Reconstructions models that can take into account optics, physics, scanner, or, noise statistics are proving to reduce image noise effectively while keeping the patient dose as low as reasonably achievable 1,2,5.
computed tomography (CT)
- CT technology
- CT image reconstruction
- CT image quality
- CT dose
- CT contrast
- patient-based artifacts
- physics-based artifacts
- hardware-based artifacts
- helical and multichannel artifacts
- windmill artifact
- cone beam effect
- zebra artifact
- stair-step artifact
- CT safety
- history of CT
- 1. Beister M, Kolditz D, Kalender WA. Iterative reconstruction methods in X-ray CT. Physica medica : PM : an international journal devoted to the applications of physics to medicine and biology : official journal of the Italian Association of Biomedical Physics (AIFB). 28 (2): 94-108. doi:10.1016/j.ejmp.2012.01.003 - Pubmed
- 2. Kim Milim, Jeong Min Lee and Jeong Hee Yoon et al. "Adaptive Iterative Dose Reduction Algorithm in CT: Effect on Image Quality Compared with Filtered Back Projection in Body Phantoms of Different Sizes". Korean Journal of Radiology 15, no. 2 (2014): 195. . doi:10.3348/kjr.2014.15.2.195.
- 3. Euclid Seeram. Computed Tomography. ISBN: 9780323323017
- 4. Euclid Seeram. Computed Tomography. ISBN: 9780323312882
- 5. Klink T, Obmann V, Heverhagen J, Stork A, Adam G, Begemann P. Reducing CT radiation dose with iterative reconstruction algorithms: the influence of scan and reconstruction parameters on image quality and CTDIvol. European journal of radiology. 83 (9): 1645-54. doi:10.1016/j.ejrad.2014.05.033 - Pubmed