Abstract
Background and PurposeIron deposition and white matter (WM) maturation are very important for brain development in infants. It has been reported that the R2* and phase values originating from the gradient-echo sequence could both reflect the iron and myelination. The aim of this study was to investigate age-related changes of R2* and phase value, and compare their performances for monitoring iron deposition and WM maturation in infant brains.Methods56 infants were examined by enhanced T2 star weighted angiography (ESWAN) and diffusion tensor imaging in the 1.5T MRI system. The R2* and phase values were measured from the deep gray nuclei and WM. Fractional anisotropy (FA) values were measured only in the WM regions. Correlation analyses were performed to explore the relation among the two parameters (R2* and phase values) and postmenstrual age (PMA), previously published iron concentrations as well as FA values.ResultsWe found significantly positive correlations between the R2* values and PMA in both of the gray nuclei and WM. Moreover, R2* values had a positive correlation with the iron reference concentrations in the deep gray nuclei and the FA in the WM. However, phase values only had the positive correlation with PMA and FA in the internal capsule, and no significant correlation with PMA and iron content in the deep gray nuclei.ConclusionsCompared with the phase values, R2* may be a preferable method to estimate the iron deposition and WM maturation in infant brains.
Highlights
Iron deposition and white matter (WM) maturation in infants are of great importance for the human brain development [1]
R2* values in the PUT and globus pallidus (GP) exhibited a moderate correlation with postmenstrual age (PMA) (r = 0.664 and 0.670, respectively, P,0.05)
There was no significant correlation between phase value and PMA in each deep gray nucleus (P.0.05) (Figure 4)
Summary
Iron deposition and white matter (WM) maturation in infants are of great importance for the human brain development [1]. Iron and myelin have the magnetic susceptibility, which may change the local magnetic field when exposed to an external magnetic field [2] In light of this property, the current MR imaging techniques could be used to detect and quantify them in vivo and may provide the potential means to monitor the development of human brain [3,4,5,6,7,8]. Susceptibility weighted imaging based on a high-spatial-resolution three-dimensional gradient-echo sequence utilizes phase information as an extra source of contrast [15] It reveals the phase shift and enhances the visualization of iron, calcification, veins, as well as the blood byproducts according to their paramagnetic or diamagnetic properties [9,15,16]. The aim of this study was to investigate age-related changes of R2* and phase value, and compare their performances for monitoring iron deposition and WM maturation in infant brains
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