|
[Abstract] Objective To explore the value of the differential regression analysis (DRA) technique in olfaction with functional magnetic resonance imaging. Methods 13 right-handed healthy volunteers without olfaction impediment underwent olfaction study by fMRI. The raw fMRI data were disposed by DRA at AFNI-fMRI software base( include realign、normalize、smooth). Results The activation areas of the olfaction fMRI(two sides) were hippocampus, gyrus front-orbitales, dorsal medial nucleus of thalamus, the dorsal anterior cingulate cortex (dACC) and the rostral ACC (rACC), amygdala, prefrontal lobe, interior-frontal lobe, temporal lobe, insular lobe, occipital lobe, brain stem and cerebellum. As for the activation areas, there was no significant difference between that induced by pleasant and unpleasant gases(P>0.005). Moreover, compared to left hemisphere, the activation areas in right hemisphere from both pleasant and unpleasant gases were more significant(P<0.005)
Conclusions DRA technique can be used as an effective method for the complicated olfactory BOLD-fMRI research, and it proved that the sensory and cognitive process of olfaction is a kind of complicated chronic reaction, and right hemisphere is the dominant hemisphere of olfaction.
[Key Words] Olfaction,functional magnetic resonance imaging (fMRI),brain function,differential Regression Analysis Technique(DRA)
引言
嗅觉是人体重要而复杂的感觉功能之一。目前已对嗅觉的中枢定位和分子生物学机制以及引起嗅觉障碍的疾病有了一定认识。应用功能磁共振成像(fMRI)进行活体嗅觉研究越来越深入[1、2],但有关嗅觉反应的动态响应函数不十分清楚,导致fMRI的数据分析面临挑战。差分回归分析技术(Differential Regression Analysis Technique,DRA)是建立在改良的组块设计之上,利用一连串变化有差别的窗口函数来实现不同的T值(回归分析)选择,提高了时间分辨率的同时又可引起效应器足够的兴奋,适用于生理学相关函数未知的复杂脑高级功能的fMRI研究,可有效地观测其动态功能反应模式[3]。本研究旨在尝试应用DRA技术来观察人脑嗅觉活动时相关中枢的动态激活区,以探讨其可行性与可能的脑机制。
1 对象和方法
1.1 对象 实验于**年**月/**年**月在**实验室完成
13例右利手、无嗅觉障碍的健康志愿者参加本实验并签署知情同意书,均为本科或硕士学历在读学生,其中男7例,女6例,年龄19-29岁,平均21.45岁。被试均于实验前进行相应的培训,以了解实验的过程。1例因实验过程中出现幽闭恐惧症而终止实验,1例实验过程出现明显的头动而舍弃,故11例符合要求而纳入全部实验。试验方案是否得到伦理委员会批准?
1.2方法
1.2.1 实验任务
志愿者平躺磁体内,平静呼吸,佩带眼罩。愉快气体(Pleasant,P)选择乙酸戊酯,非愉快气体(Unpleasant,U)选择吡啶,空气作为基线对照。不间断给气,空气通过乙酸戊酯时的流速控制在500ml/min,通过吡啶时流速控制在250ml/min。刺激方式采用组块设计,先给予30次Scan(S)刺激,再给予第二次刺激15次S,之间有55次S作为控制任务;每位被试先给予P气体,间隔足够长时间后,再给U气体(图1)。每位被试于实验结束后填写实验感受记录。文中缺乏对新方法可用于嗅觉磁共振成像的说明。实验设计为什么这么设计,两次刺激时间为什么不一致?应给予说明。
|
