通过1H-磁共振成像和光谱技术在体研究人脑对轻度脱水和再水化的反应
Responses of the Human Brain to Mild Dehydration and Rehydration Explored In Vivo by 1H-MR Imaging and Spectroscopy.
作者信息
Biller A, Reuter M, Patenaude B, Homola G A, Breuer F, Bendszus M, Bartsch A J
机构信息
From the Department of Neuroradiology (A.B., M.B., A.J.B.), University of Heidelberg, Heidelberg, Germany
Department of Radiology (M.R.), Massachusetts General Hospital/Harvard Medical School, Boston, Massachusetts Martinos Center for Biomedical Imaging (M.R.), Charlestown, Massachusetts Massachusetts Institute of Technology Computer Science and AI Lab (M.R.), Cambridge, Massachusetts.
出版信息
AJNR Am J Neuroradiol. 2015 Dec;36(12):2277-84. doi: 10.3174/ajnr.A4508. Epub 2015 Sep 17.
BACKGROUND AND PURPOSE
As yet, there are no in vivo data on tissue water changes and associated morphometric changes involved in the osmo-adaptation of normal brains. Our aim was to evaluate osmoadaptive responses of the healthy human brain to osmotic challenges of de- and rehydration by serial measurements of brain volume, tissue fluid, and metabolites.
MATERIALS AND METHODS
Serial T1-weighted and (1)H-MR spectroscopy data were acquired in 15 healthy individuals at normohydration, on 12 hours of dehydration, and during 1 hour of oral rehydration. Osmotic challenges were monitored by serum measures, including osmolality and hematocrit. MR imaging data were analyzed by using FreeSurfer and LCModel.
RESULTS
On dehydration, serum osmolality increased by 0.67% and brain tissue fluid decreased by 1.63%, on average. MR imaging morphometry demonstrated corresponding decreases of cortical thickness and volumes of the whole brain, cortex, white matter, and hypothalamus/thalamus. These changes reversed during rehydration. Continuous fluid ingestion of 1 L of water for 1 hour within the scanner lowered serum osmolality by 0.96% and increased brain tissue fluid by 0.43%, on average. Concomitantly, cortical thickness and volumes of the whole brain, cortex, white matter, and hypothalamus/thalamus increased. Changes in brain tissue fluid were related to volume changes of the whole brain, the white matter, and hypothalamus/thalamus. Only volume changes of the hypothalamus/thalamus significantly correlated with serum osmolality.
CONCLUSIONS
This is the first study simultaneously evaluating changes in brain tissue fluid, metabolites, volume, and cortical thickness. Our results reflect cellular volume regulatory mechanisms at a macroscopic level and emphasize that it is essential to control for hydration levels in studies on brain morphometry and metabolism in order to avoid confounding the findings.
背景与目的
迄今为止,尚无关于正常脑渗透压适应过程中组织水变化及相关形态学变化的体内数据。我们的目的是通过对脑容量、组织液和代谢物进行系列测量,评估健康人脑对脱水和再水化渗透压挑战的渗透适应性反应。
材料与方法
对15名健康个体在正常水合状态、脱水12小时以及口服补液1小时期间采集系列T1加权和氢质子磁共振波谱数据。通过血清指标监测渗透压挑战,包括渗透压和血细胞比容。利用FreeSurfer和LCModel分析磁共振成像数据。
结果
脱水时,血清渗透压平均升高0.67%,脑组织液平均减少1.63%。磁共振成像形态学显示皮质厚度以及全脑、皮质、白质和下丘脑/丘脑体积相应减小。这些变化在再水化过程中逆转。在扫描过程中持续1小时摄入1升水可使血清渗透压平均降低0.96%,脑组织液平均增加0.43%。同时,全脑、皮质、白质和下丘脑/丘脑的皮质厚度和体积增加。脑组织液变化与全脑、白质和下丘脑/丘脑的体积变化相关。仅下丘脑/丘脑的体积变化与血清渗透压显著相关。
结论
这是第一项同时评估脑组织液、代谢物、体积和皮质厚度变化的研究。我们的结果在宏观水平反映了细胞体积调节机制,并强调在脑形态学和代谢研究中控制水合水平至关重要,以避免混淆研究结果。
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