Tomosynthesis
Tomosynthesis, also digital tomosynthesis, is a method for performing high-resolution limited-angle tomography at radiation dose levels comparable with projectional radiography. It has been studied for a variety of clinical applications, including vascular imaging, dental imaging, orthopedic imaging, mammographic imaging, musculoskeletal imaging, and chest imaging.
History
The concept of tomosynthesis was derived from the work of Ziedses des Plantes, who developed methods of reconstructing an arbitrary number of planes from a set of projections. Though this idea was displaced by the advent of computed tomography, tomosynthesis later gained interest as a low-dose tomographic alternative to CT.Reconstruction
Tomosynthesis reconstruction algorithms are similar to CT reconstructions, in that they are based on performing an inverse Radon transform. Due to partial data sampling with very few projections, approximation algorithms have to be used. Filtered back projection and iterative, expectation-maximization algorithms have both been used to reconstruct the data.Reconstruction algorithms for tomosynthesis are different from those of conventional CT because the conventional filtered back projection algorithm requires a complete set of data. Iterative algorithms based upon expectation maximization are most commonly used, but are computationally intensive. Some manufacturers have produced practical systems using off-the-shelf GPUs to perform the reconstruction in a few seconds.
Differences from other imaging modalities
Digital tomosynthesis combines digital image capture and processing with simple tube/detector motion as used in conventional computed tomography. However, though there are some similarities to CT, it is a separate technique. In modern CT, the source/detector makes at least a complete 180-degree rotation about the subject obtaining a complete set of data from which images may be reconstructed. Digital tomosynthesis, on the other hand, only uses a limited rotation angle with a lower number of discrete exposures than CT. This incomplete set of projections is digitally processed to yield images similar to conventional tomography with a limited depth of field. Because the image processing is digital, a series of slices at different depths and with different thicknesses can be reconstructed from the same acquisition. However, since fewer projections are needed than CT to perform the reconstruction, radiation exposure and cost are both reduced.Applications
Breast
Digital breast tomosynthesis is Food and Drug Administration approved for use in breast cancer screening. The benefit for screening has been debated, but consensus is being reached that the technology is improving sensitivity compared to two-view digital mammography while recall rates seem to be debated in different studies. Because the data acquired are 85 - 160 micron typical resolution, much higher than CT, digital breast tomosynthesis is unable to offer the narrow slice widths that CT offers. However, the higher resolution detectors permit very high in-plane resolution, even if the Z-axis resolution is less. Another interesting property of breast tomosynthesis is that image quality may vary substantially through the imaging volume. Digital breast tomosynthesis reading times are much higher, compared to mammography interpretation.Normal mammograms had been criticized for having too many false negatives and false positives. the fact that mammography had only two views limited the ability of the radiologists to identify findings. On the other hand other, other scans types are not a good fit for screening. for example, Breast Ultrasound or Breast MRI are very accurate, but take too much time and cannot be used for screening, CT scans can give the radiologist much more data, but also have much more radiation which might have adverse effect, and thus should not be done for screening, where most of the population is healthy.
Therefore tomosynthesis benefits both from low dose compared to a full CT scan, and contains much more data than a regular mammogram. Nevertheless it poses a new challenge as the time usually spent by radiologists for reading mammograms is very short, and reading Tomosynthesis may take more time
Photon-counting breast tomosynthesis has been investigated, and spectral imaging applications, such as breast density measurement and lesion characterization, have been investigated on that platform.