- Chenevert, Thomas L;
- Malyarenko, Dariya I;
- Newitt, David;
- Li, Xin;
- Jayatilake, Mohan;
- Tudorica, Alina;
- Fedorov, Andriy;
- Kikinis, Ron;
- Liu, Tiffany Ting;
- Muzi, Mark;
- Oborski, Matthew J;
- Laymon, Charles M;
- Li, Xia;
- Thomas, Yankeelov;
- Jayashree, Kalpathy-Cramer;
- Mountz, James M;
- Kinahan, Paul E;
- Rubin, Daniel L;
- Fennessy, Fiona;
- Huang, Wei;
- Hylton, Nola;
- Ross, Brian D
Purpose
To evaluate the ability of various software (SW) tools used for quantitative image analysis to properly account for source-specific image scaling employed by magnetic resonance imaging manufacturers.Methods
A series of gadoteridol-doped distilled water solutions (0%, 0.5%, 1%, and 2% volume concentrations) was prepared for manual substitution into one (of three) phantom compartments to create "variable signal," whereas the other two compartments (containing mineral oil and 0.25% gadoteriol) were held unchanged. Pseudodynamic images were acquired over multiple series using four scanners such that the histogram of pixel intensities varied enough to provoke variable image scaling from series to series. Additional diffusion-weighted images were acquired of an ice-water phantom to generate scanner-specific apparent diffusion coefficient (ADC) maps. The resulting pseudodynamic images and ADC maps were analyzed by eight centers of the Quantitative Imaging Network using 16 different SW tools to measure compartment-specific region-of-interest intensity.Results
Images generated by one of the scanners appeared to have additional intensity scaling that was not accounted for by the majority of tested quantitative image analysis SW tools. Incorrect image scaling leads to intensity measurement bias near 100%, compared to nonscaled images.Conclusion
Corrective actions for image scaling are suggested for manufacturers and quantitative imaging community.