Kallenberg Kai, Bailey Damian M, Christ Stefan, Mohr Alexander, Roukens Robin, Menold Elmar, Steiner Thorsten, Bärtsch Peter, Knauth Michael
Department of Neuroradiology, Georg August University Medical Centre, University of Göttingen, Göttingen, Germany.
J Cereb Blood Flow Metab. 2007 May;27(5):1064-71. doi: 10.1038/sj.jcbfm.9600404. Epub 2006 Oct 4.
The present study applied T2- and diffusion-weighted magnetic resonance imaging to examine if mild cerebral edema and subsequent brain swelling are implicated in the pathophysiology of acute mountain sickness (AMS). Twenty-two subjects were examined in normoxia (21% O2), after 16 hours passive exposure to normobaric hypoxia (12% O2) corresponding to a simulated altitude of 4,500 m and after 6 hours recovery in normoxia. Clinical AMS was diagnosed in 50% of subjects during hypoxia and corresponding headache scores were markedly elevated (P<0.05 versus non-AMS). Hypoxia was associated with a mild increase in brain volume (+7.0+/-4.8 ml, P<0.05 versus pre-exposure baseline) that resolved during normoxic recovery. Hypoxia was also associated with an increased T2 relaxation time (T2rt) and a general trend toward an increased apparent diffusion coefficient (ADC). During the normoxic recovery, brain volume and T2rt recovered to pre-exposure baseline values, whereas a more marked reduction in ADC in the splenium of the corpus callosum (SCC) was observed (P<0.05). While changes in brain volume and T2rt were not selectively different in AMS, ADC values were consistently lower (P<0.05 versus non-AMS) and associated with the severity of neurologic symptoms. Acute mountain sickness was also characterized by an increased brain to intracranial volume ratio (P<0.05 versus non-AMS). These findings indicate that mild extracellular vasogenic edema contributes to the generalized brain swelling observed at high altitude, independent of AMS. In contrast, intracellular cytotoxic edema combined with an anatomic predisposition to a 'tight-fit' brain may prove of pathophysiologic significance, although the increase in brain volume in hypoxia was only about 0.5% of total brain volume.
本研究应用T2加权和扩散加权磁共振成像来检查轻度脑水肿及随后的脑肿胀是否与急性高原病(AMS)的病理生理学有关。22名受试者在常氧(21%氧气)状态下接受检查,在被动暴露于相当于模拟海拔4500米的常压低氧(12%氧气)16小时后以及在常氧恢复6小时后再次接受检查。50%的受试者在低氧期间被诊断为临床AMS,相应的头痛评分显著升高(与非AMS组相比,P<0.05)。低氧与脑容量轻度增加有关(+7.0±4.8毫升,与暴露前基线相比,P<0.05),在常氧恢复过程中这种增加消失。低氧还与T2弛豫时间(T2rt)增加以及表观扩散系数(ADC)总体呈增加趋势有关。在常氧恢复期间,脑容量和T2rt恢复到暴露前基线值,而胼胝体压部(SCC)的ADC有更明显降低(P<0.05)。虽然脑容量和T2rt的变化在AMS组与非AMS组之间没有选择性差异,但ADC值持续较低(与非AMS组相比,P<0.05),且与神经症状的严重程度相关。急性高原病的特征还包括脑与颅内体积比增加(与非AMS组相比,P<0.05)。这些发现表明,轻度细胞外血管源性水肿导致了在高海拔观察到的广泛性脑肿胀,这与AMS无关。相比之下,细胞内细胞毒性水肿加上大脑“紧密贴合”的解剖学易感性可能具有病理生理学意义,尽管低氧时脑容量增加仅约为全脑容量的0.5%。
