High-b diffusivity of MS lesions in cervical spinal cord using ultrahigh-b DWI (UHb-DWI)

Ultrahigh-b diffusion-weighted imaging for quantitative evaluation of myelination in shiverer mouse spinal cord

PURPOSE

To perform a quantitative evaluation of myelination on WT and myelin-deficient (shiverer) mouse spinal cords using ultrahigh-b diffusion-weighted imaging (UHb-DWI).

METHODS

UHb-DWI of ex vivo on spinal cord specimens of two shiverer (C3HeB/FeJ-shiverer, homozygous genotype for MbP_shi ) and six WT (Black Six, C3HeB/FeJ) mice were acquired using 3D multishot diffusion-weighted stimulated-echo EPI, a homemade RF coil, and a small-bore 7T MRI system. Imaging was performed in transaxial plane with 75 × 75 μm² in-plane resolution, 1-mm-slice thickness, and radial DWI using b_max = 42,890 s/mm² . Histological evaluation was performed on upper thoracic sections using optical and transmission electron microscopy. Numerical Monte Carlo simulations (MCSs) of water diffusion were performed to facilitate interpretation of UHb-DWI signal-b curves.

RESULTS

The white matter ultrahigh-b radial DWI (UHb-rDWI) signal-b curves of WT mouse cords behaved biexponentially with high-b diffusion coefficient D_H < 0.020 × 10^-3 mm² /s. However, as expected with less myelination, the signal-b of shiverer mouse cords behaved monoexponentially with significantly greater D_H = 0.162 × 10^-3 , 0.142 × 10^-3 , and 0.164 × 10^-3 mm² /s at anterodorsal, posterodorsal, and lateral columns, respectively. The axial DWI signals of all mouse cords behaved monoexponentially with D = (0.718-1.124) × 10^-3 mm² /s. MCS suggests that these elevated D_H are mainly induced by increased water exchange at the myelin sheath. Microscopic results were consistent with the UHb-rDWI findings.

CONCLUSION

UHb-DWI provides quantitative differences in myelination of spinal cords from myelin-deficit shiverer and WT mice. UHb-DWI may become a powerful tool to evaluate myelination in demyelinating disease models that may translate to human diseases, including multiple sclerosis.

Diffusion kurtosis imaging as an imaging biomarker for predicting prognosis in chronic kidney disease patients

BACKGROUND

Renal fibrosis is the strongest prognosis predictor of end-stage renal disease (ESRD) in chronic kidney disease (CKD). Diffusion kurtosis imaging (DKI) is a promising method of magnetic resonance imaging (MRI) successfully used to assess renal fibrosis in IgA nephropathy. This study first evaluated the long-term prognostic value of DKI in CKD patients.

METHODS

Forty-two patients with CKD were prospectively enrolled, and underwent DKI on a clinical 3 T MR scanner. We excluded patients with comorbidities that could affect the volume or the components of the kidney. DKI parameters, including mean kurtosis (K), mean diffusivity (D) and apparent diffusion coefficient (ADC) of kidney cortex were obtained by region-of-interest measurement. We followed up these patients for a median of 43 months and investigated the correlations between each DKI parameter and overall renal prognosis.

RESULTS

Both K and ADC values were correlated well with the eGFR on recruitment and the eGFR of the last visit in follow-up (p＜0.001). K and ADC values were also well associated with the eGFR slopes in CKD patients, both with the first-last time point slope (p = 0.011 and p＜0.001, respectively) and with the regression slope (p = 0.010 and p＜0.001, respectively). Cox proportional hazard regression indicated that lower eGFR and ADC values independently predicted eGFR loss of more than 30% and ESRD. The receiver operating characteristic analysis showed that K and ADC values were predictable for renal prognosis, and ADC displayed better capabilities for both ESRD (AUC 0.936, sensitivity 92.31%, specificity 82.76%) and the composite endpoint (eGFR loss>30% or ESRD) (AUC 0.881, sensitivity 66.67%, specificity 96.3%).

CONCLUSIONS

Renal ADC values obtained from DKI showed significant predictive value for the prognosis of CKD patients, which could be a promising noninvasive technique in follow-up.