Abstract
While the imaging protocol determines radiation dose and image quality, it is difficult to find the lowest dose
protocol (kVp, mAs, filtration) that provides appropriate diagnostic quality images. Recently, we developed a
method for retrospectively synthesizing CT scans of arbitrary protocols using a previously acquired dual energy
scan that relies on projection space data. Here, we propose a new variant of synthetic CT that only requires
reconstructed dual energy images to simulate realistic images from arbitrary low dose protocols.
Axial scans of a phantom were acquired on a GE CT750 HD system at 80 kVp and separately at 140 kVp,
enabling material decomposition. Additional scans at 100 and 120 kVp and at different exposures were made
to compare with synthesized results. Raw data for any spectrum can be estimated by forward transmission
through the material decomposition images, but these have degraded spatial resolution. To avoid blurring, the
synthesized image is represented as a linear combination (i.e., mixed or blended image) of the 80/140 kVp images.
Noise with the correct statistics is then added so that the total noise matches the expected noise of the simulated
protocol (estimated from forward transmission). For the studied object, the resulting synthesized images are
indistinguishable from the actual images.
Synthetic CT enables users to visualize the impact of protocol changes on the contrast and noise of CT scans,
which can be used to develop lower dose protocols by demonstrating dose/noise/protocol trade-offs. Our new
image domain implementation significantly increases the accessibility of synthetic CT to potential users.