Imaging human intra-cerebral connectivity by PET during TMS

被引：318

作者：

Fox, P

Ingham, R

George, MS

Mayberg, H

Ingham, J

Roby, J

Martin, C

Jerabek, P

机构：

[1] UNIV TEXAS,HLTH SCI CTR,DEPT RADIOL,SAN ANTONIO,TX 78284

[2] UNIV TEXAS,HLTH SCI CTR,DEPT MED NEUROL,SAN ANTONIO,TX 78284

[3] UNIV TEXAS,HLTH SCI CTR,DEPT PSYCHIAT,SAN ANTONIO,TX 78284

[4] UNIV TEXAS,HLTH SCI CTR,DEPT PHYSIOL,SAN ANTONIO,TX 78284

[5] UNIV CALIF SANTA BARBARA,DEPT SPEECH & HEARING SCI,SANTA BARBARA,CA 93106

[6] MED UNIV S CAROLINA,DEPT PSYCHIAT,CHARLESTON,SC 29425

[7] MED UNIV S CAROLINA,DEPT RADIOL,CHARLESTON,SC 29425

[8] MED UNIV S CAROLINA,DEPT NEUROL,CHARLESTON,SC 29425

来源：

NEUROREPORT | 1997年 / 8卷 / 12期

关键词：

connectivity; human; M2; positron emission tomography (PET); primary motor cortex (M1); S1; S2; SMA; transcranial magnetic stimulation (TMS);

D O I：

10.1097/00001756-199708180-00027

中图分类号：

Q189 [神经科学];

学科分类号：

071006 ;

摘要：

NON-INVASIVE imaging of human inter-regional neural connectivity by positron emission tomography (PET) during transcranial magnetic stimulation (TMS) was performed. The hand area of primary motor cortex (M1) in the left cerebral hemisphere was stimulated with TMS while local and remote effects were recorded with PET. At the stimulated site, TMS increased blood flow (12-20%) in a highly focal manner, without an inhibitory surround. Remote covariances, an index of connectivity with M1, were also focal. Connectivity patterns established in non-human species were generally confirmed. Excitatory connectivity (positive covariance) was observed in ipsilateral primary and secondary somatosensory areas (S1 and S2), in ipsilateral ventral, lateral premotor cortex (M2) and in contralateral supplementary motor area (SMA). Inhibitory connectivity (negative covariance) was observed in contralateral M1.

引用

页码：2787 / 2791

页数：5

共 22 条

[1] BARKER AT, 1985, LANCET, V1, P1106
[2] FUNCTIONAL MAPPING OF THE HUMAN VISUAL-CORTEX BY MAGNETIC-RESONANCE-IMAGING
BELLIVEAU, JW
KENNEDY, DN
MCKINSTRY, RC
BUCHBINDER, BR
WEISSKOFF, RM
COHEN, MS
VEVEA, JM
BRADY, TJ
ROSEN, BR
[J]. SCIENCE, 1991, 254 (5032) : 716 - 719
[3] Brodal A., 1981, NEUROLOGICAL ANATOMY, Vthird, P180
[4] DUM RP, 1991, J NEUROSCI, V11, P445
[5] STIMULUS RATE DEPENDENCE OF REGIONAL CEREBRAL BLOOD-FLOW IN HUMAN STRIATE CORTEX, DEMONSTRATED BY POSITRON EMISSION TOMOGRAPHY
FOX, PT
RAICHLE, ME
[J]. JOURNAL OF NEUROPHYSIOLOGY, 1984, 51 (05) : 1109 - 1120
[6] A NONINVASIVE APPROACH TO QUANTITATIVE FUNCTIONAL BRAIN MAPPING WITH H-20-15 AND POSITRON EMISSION TOMOGRAPHY
FOX, PT
MINTUN, MA
RAICHLE, ME
HERSCOVITCH, P
[J]. JOURNAL OF CEREBRAL BLOOD FLOW AND METABOLISM, 1984, 4 (03) : 329 - 333
[7] A STEREOTACTIC METHOD OF ANATOMICAL LOCALIZATION FOR POSITRON EMISSION TOMOGRAPHY
FOX, PT
PERLMUTTER, JS
RAICHLE, ME
[J]. JOURNAL OF COMPUTER ASSISTED TOMOGRAPHY, 1985, 9 (01) : 141 - 153
[8] ENHANCED DETECTION OF FOCAL BRAIN RESPONSES USING INTERSUBJECT AVERAGING AND CHANGE-DISTRIBUTION ANALYSIS OF SUBTRACTED PET IMAGES
FOX, PT
MINTUN, MA
REIMAN, EM
RAICHLE, ME
[J]. JOURNAL OF CEREBRAL BLOOD FLOW AND METABOLISM, 1988, 8 (05) : 642 - 653
[9] Fox PT, 1997, HUM BRAIN MAPP, V5, P1, DOI 10.1002/(SICI)1097-0193(1997)5:1<1::AID-HBM1>3.0.CO
[10] 2-7

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