Abstract
Multiparametric magnetic resonance imaging (mpMRI) data are emergingly used in the clinic e.g. for the diagnosis of prostate cancer. In contrast to conventional MR imaging data, multiparametric data typically include functional measurements such as diffusion and perfusion imaging sequences. Conventionally, these measurements are visualized with a one-dimensional color scale, allowing only for one-dimensional information to be encoded. Yet, human perception places visual information in a three-dimensional color space. In theory, each dimension of this space can be utilized to encode visual information. We addressed this issue and developed a new method for tri-variate color-coded visualization of mpMRI data sets. We showed the usefulness of our method in a preclinical and in a clinical setting: In imaging data of a rat model of acute kidney injury, the method yielded characteristic visual patterns. In a clinical data set of N = 13 prostate cancer mpMRI data, we assessed diagnostic performance in a blinded study with N = 5 observers. Compared to conventional radiological evaluation, color-coded visualization was comparable in terms of positive and negative predictive values. Thus, we showed that human observers can successfully make use of the novel method. This method can be broadly applied to visualize different types of multivariate MRI data.
Highlights
Sequence TR TE FOV Voxel size Matrix PAT factor Number of slices B-value No of measurements Temporal resolution
For computed tomography (CT) imaging, several studies have assessed the use of color transfer functions and their impact on observer performance[13,14]
To our knowledge, there is no color-coded visualization technique available that can be readily applied to three-channel, spatially aligned Multiparametric magnetic resonance imaging (mpMRI) data sets
Summary
Sequence TR (ms) TE (ms) FOV (mm2) Voxel size (mm3) Matrix PAT factor Number of slices B-value No of measurements Temporal resolution (sec). A simple way of visualizing more than two channels is to use the RGB color space that is used in computer displays: to encode tri-variate imaging data, each parameter map is assigned to one of the basic display colors red, green, blue. This method leads to distortions of the data and is prone to introduce artifacts, caused by the pronounced nonlinearity of the human perception of colors in the RGB color space[11,12]. We assess diagnostic performance of blinded observers in a typical diagnostic setting in the clinic
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