Effects of diffusional kurtosis imaging parameters on diffusion quantification


Diffusional kurtosis imaging (DKI) is a new technique based on non-Gaussian water diffusion analysis. However, the original DKI protocol (six b values and 30 motion-probing gradient (MPG) directions) requires more than 10 min of scanning time, which is too long for daily clinical use. We aimed to find suitable b value, MPG direction, and diffusion time settings for faster DKI. Four normal healthy subjects participated in the study. All DKI data sets were acquired on a clinical 3T-MRI scanner (Philips Medical Systems) with use of three protocols of 0-7500 s/mm(2) b values, 6-32 MPG directions, and 23-80 ms diffusion time. There was a remarkable difference in the standard deviation (SD) of the mean DK values in the number of MPG directions. The mean DK values were significantly higher in the posterior limb of the internal capsule (p = 0.003, r = 0.924) and thalamus (p = 0.005, r = 0.903), whereas the mean DK values of the cerebrospinal fluid (CSF) (p = 0.001, r = -0.976) were significantly lower when we used a longer diffusion time. Our results indicate that the SD of the mean DK values was higher in 15 MPG directions than in 20 MPG directions and more. Because the mean DK values of the CSF were significantly lower when we used longer diffusion times, we expect longer diffusion times to be useful for DKI. We propose the following imaging parameters for clinical use: 0, 1000, and 2000 s/mm(2) b values; 20 MPG directions; Δ/δ 45.3/13.3 ms.

DOI: 10.1007/s12194-013-0206-5

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@inproceedings{Fukunaga2013EffectsOD, title={Effects of diffusional kurtosis imaging parameters on diffusion quantification}, author={Issei Fukunaga and Masaaki Hori and Yoshitaka Masutani and Nozomi Hamasaki and Shuji Sato and Yuriko Suzuki and Fumitaka Kumagai and Masatsugu Kosuge and Haruyoshi Hoshito and Koji Kamagata and Keigo Shimoji and Atsushi Nakanishi and Shigeki Aoki and Atsushi Senoo}, booktitle={Radiological physics and technology}, year={2013} }