Provenzale James M, Liang Luxia, DeLong David, White Leonard E
Department of Radiology, Duke University Medical Center, Box 3808, Durham, NC 27710, USA.
AJR Am J Roentgenol. 2007 Aug;189(2):476-86. doi: 10.2214/AJR.07.2132.
The purpose of this study was to use diffusion-weighted and diffusion tensor imaging to investigate the status of cerebral white matter (WM) at term gestation and the rate of WM maturation throughout the first year of life in healthy infants.
Fifty-three children (35 boys) ranging in age from 1.5 weeks premature to 51.5 weeks (mean age, 22.9 weeks) underwent conventional MRI, diffusion imaging in three directions (b = 1,000 s/mm2), and diffusion tensor imaging with gradient encoding in six directions, all on a 1.5-T MRI system. Apparent diffusion coefficient (ADC) and fractional anisotropy (FA) were measured in three deep WM structures (posterior limb of internal capsule, genu, and splenium of corpus callosum) and two peripheral WM regions (associational WM underlying prefrontal and posterior parietal cortex) with a standard region of interest (44 +/- 4 cm2). ADC and FA were expressed as a percentage of corresponding values measured in a group of healthy young adults. Mean ADC and FA values for deep and peripheral WM were plotted against gestational age normalized to term. The data were fit best with a broken-line linear regression model with a breakpoint at 100 days. ADC and FA values at term were estimated according to the intercept of the initial linear period (before day 100) with day 0. The slope of the linear fits was used to determine the rate of WM maturation in both the early and the late (after day 100) periods. Multivariate analysis of variance tests were used to compare deep and peripheral WM structures at term and at representative early and late ages (days 30 and 200) and to compare rates of ADC and FA maturation in early and late periods within the first year.
At term, peripheral WM was less mature than deep WM according to results of extrapolation of ADC and FA values in the first 100 days of life to day 0 (p < 0.01). Mean ADC and FA value (percentage of mean adult value) for peripheral WM were 1.32 x 10(-3) mm2/s (163%) and 0.16 (32%), respectively, and 1.09 x 10(-3) mm2/s (143%) and 0.36 (54%), respectively, for deep WM. On day 30 and day 200, estimated mean ADC and FA continued to show greater diffusion (higher ADC) and less anisotropy (lower FA value) in peripheral WM (p <0.01). During the first year of postnatal life, both ADC and FA matured at higher rates before postnatal day 100 compared with a later time. Differences were observed in rates of maturation in the first 100 days when rates of decrease in ADC and increase in FA were compared between peripheral WM and deep WM; however, the maturational trends differed whether ADC or FA was examined. The early rate of ADC decrease (maturation) was twice as great for peripheral WM than for deep WM (p < 0.01) unexpectedly, but the opposite pattern was observed for FA. The early rate of FA increase (maturation) was approximately one half as great for peripheral WM as for deep WM (p = 0.01). Throughout the rest of the first year, no differences were observed in the rates of change in either index between peripheral WM and deep WM.
At term, both ADC and FA differ significantly in peripheral WM and deep WM, deep WM structures being more mature. Both deep WM and peripheral WM mature more rapidly during approximately the first 3 months in comparison with the rest of the first year. Unexpected differences in early (first 100 days) rates of maturation assessed with diffusion-weighted (ADC) and diffusion tensor (FA) imaging suggest that these two techniques may be sensitive to different aspects of WM maturation in the early perinatal period.
本研究旨在运用扩散加权成像和扩散张量成像,调查足月妊娠时脑白质(WM)的状态以及健康婴儿出生后第一年脑白质成熟的速率。
53名儿童(35名男孩),年龄从早产1.5周至51.5周(平均年龄22.9周),均在1.5-T磁共振成像系统上接受常规磁共振成像、三个方向的扩散成像(b = 1,000 s/mm2)以及六个方向梯度编码的扩散张量成像。在三个深部脑白质结构(内囊后肢、胼胝体膝部和压部)和两个外周脑白质区域(前额叶和顶叶后皮质下的联合脑白质),使用标准感兴趣区(44±4 cm2)测量表观扩散系数(ADC)和各向异性分数(FA)。ADC和FA表示为一组健康年轻成年人测量的相应值的百分比。将深部和外周脑白质的平均ADC和FA值与足月标准化的胎龄作图。数据最适合用折线线性回归模型拟合,断点在100天。根据初始线性期(第100天之前)与第0天的截距估计足月时的ADC和FA值。线性拟合的斜率用于确定早期和晚期(第100天之后)脑白质成熟的速率。使用多因素方差分析测试比较足月时以及代表性的早期和晚期(第30天和第200天)的深部和外周脑白质结构,并比较出生后第一年内早期和晚期ADC和FA成熟的速率。
根据出生后前100天的ADC和FA值外推至第0天的结果,足月时外周脑白质比深部脑白质成熟度低(p < 0.01)。外周脑白质的平均ADC和FA值(成人平均值的百分比)分别为1.32×10(-3) mm2/s(163%)和0.16(32%),深部脑白质分别为1.09×10(-3) mm2/s(143%)和0.36(54%)。在第30天和第200天,估计的平均ADC和FA继续显示外周脑白质中扩散更大(ADC更高)且各向异性更小(FA值更低)(p < 0.01)。在出生后第一年,与后期相比,出生后第100天之前ADC和FA的成熟速率都更高。在出生后前100天,比较外周脑白质和深部脑白质的ADC降低速率和FA增加速率时,观察到成熟速率存在差异;然而,无论检查ADC还是FA,成熟趋势都不同。外周脑白质早期ADC降低(成熟)速率比深部脑白质快两倍(p < 0.01),这出乎意料,但FA的情况则相反。外周脑白质早期FA增加(成熟)速率约为深部脑白质的一半(p = 0.01)。在出生后第一年的其余时间里,外周脑白质和深部脑白质在这两个指标的变化速率上均未观察到差异。
足月时,外周脑白质和深部脑白质的ADC和FA均存在显著差异,深部脑白质结构更成熟。与出生后第一年的其余时间相比,深部脑白质和外周脑白质在出生后大约前3个月成熟得更快。用扩散加权(ADC)和扩散张量(FA)成像评估的早期(前100天)成熟速率存在意外差异,这表明这两种技术可能对围产期早期脑白质成熟的不同方面敏感。
