1Atlas SW.Magnetic Resonance Imaging of the brain and spine[M].3 rd ed.Philadelphia:lippincott williams and wilkins,2002:1189-97.
2Devous MD.Functional brain imaging in the dementias:role in early detection,differential diagnosis,and longitudinal studies[J].Eur J Nucl Med Mol imaging,2002 ;29 (12):1685-96.
3[1]Chee M, O'Craven K M, Bergida R, et al. Auditory and visual word processing studied with fMRI. Human Brain Mapping, 1999,7:15~28
4[2]Booth J R, Burman D D, Meyer J R, et al. Modality independence of word comprehension. Human Brain Mapping, 2002, 16:251~261
5[3]Rozin P, Poritsky S, Sotsky R. American children with reading problems can easily learn to read English represented by Chinese characters. Science, 1971, 171:1264~1267
6[4]Chee M, Tan E, Thiel T. Mandarin and English single word processing studied with functional magnetic resonance imaging. J Neurosci, 1999, 19:3050~3056
7[5]Tan L H, Spinks J A, Gao J H, et al. Brain activation in the processing of Chinese characters and words: a functional MRI study.Human Brain Mapping, 2000, 10:16~27
8[6]Tan L H, Liu H L, Perfetti C A, et al. The neural system underlying Chinese logograph reading. Neuroimage, 2001, 13:836~846
9[7]Tan L H, Feng C M, Fox P T, et al. An fMRI study with written Chinese. Neuroreport, 2001, 12:83~88
10[8]Luck K K, Liu H L, Wai Y Y, et al. Functional anatomy of syntactic and semantic processing in language comprehension. Human Brain Mapping, 2002, 16:133~145
4YANG YanHui1,3,LIANG PeiPeng2,3,LU ShengFu2,3,LI KunCheng1,3 & ZHONG Ning2,3,4 1 Xuanwu Hospital,Capital Medical University,Beijing 100053,China,2 The International WIC Institute,Beijing University of Technology,Beijing 100124,China,3 Beijing Municipal Lab of Brain Informatics,Beijing 100124,China,4 Department of Life Science and Informatics,Maebashi Institute of Technology,Maebashi 371-0816,Japan.The role of the DLPFC in inductive reasoning of MCI patients and normal agings:An fMRI study[J].Science China(Life Sciences),2009,52(8):789-795. 被引量:6
2Cornett CR, Markesbely WR, Ehmann WD. Imbalances of trace elements related to oxidative damage on Alzheimer's disease[J]. Neuro Toxicology, 1998, 19(3):339-345.
3House M J, Pierre TGS, Foster JK, et al. Quantitative MR imaging R2 relaxometry in elderly participants reporting memory loss[J]. AJNR, 2006, 27(2):430-439.
4Tayara N, Delatour B, Cudennee C, et al. Age-related evolution of amyloid burden, iron load, and MR relaxation times in a trausgenic mouse model of Alzheimer's disease[J]. Neurobiol Dis, 2006, 22(1): 199-208.
5Wang H, Yuan H, Shu L, et al. Prolongation of T (2) relaxation times of hippocampus and amygdala in Alzheimer's disease[J]. Neurosci Lett, 2004, 363(2):150-153.
6Bartzokis G, Sultzer D, Cummings J, et al. In vivo evaluation of brain iron in Alzheimer disease using magnetic resonance imaging [J]. Arch Gen Psychiatry, 2000, 57(1):47-53.
7Zywicke HA, Van Gelderen P, Connor JR. Microscopic R2* mapping of reduced brain iron in the Belgrade rat [J]. Ann Neurol, 2002, 52(1): 102-105.
8LeVine SM. Iron deposits in multiple sclerosis and Alzheimer's disease brains[J]. Brain Res, 1997, 760(1-2):298-303.
9Haley AP, Knight-Scott J, Fuchs KL, et al. Shortening of hippoeampal spin-spin relaxation time in probable Alzheimer's disease: a ^1H magnetic resonance spectroscopy study [J]. Neurosei Lett, 2004, 362(3):167-170.
10Schenck JF, Zimmerman EA, Li Z, et al. High-field magnetic resonance imaging of brain iron in Alzheimer disease [J]. Top Magn Reson Imaging, 2006, 17(1):41-50.