ULTRAFAST MR IMAGING OF WATER MOBILITY - ANIMAL-MODELS OF ALTERED CEREBRAL PERFUSION

被引：15

作者：

MCKINSTRY, RC ^{[1
]}

WEISKOFF, RM ^{[1
]}

BELLIVEAU, JW ^{[1
]}

VEVEA, JM ^{[1
]}

MOORE, JB ^{[1
]}

KWONG, KW ^{[1
]}

HALPERN, EF ^{[1
]}

ROSEN, BR ^{[1
]}

机构：

[1] MASSACHUSETTS GEN HOSP,DEPT RADIOL,CTR MGH NMR,BLDG 149,13TH ST,BOSTON,MA 02129

来源：

JMRI-JOURNAL OF MAGNETIC RESONANCE IMAGING | 1992年 / 2卷 / 04期

关键词：

BRAIN; PERFUSION; CEREBRAL BLOOD VESSELS; FLOW DYNAMICS; DIFFUSION IMAGING; ECHO-PLANAR IMAGING; RAPID IMAGING;

D O I：

10.1002/jmri.1880020404

中图分类号：

R8 [特种医学]; R445 [影像诊断学];

学科分类号：

1002 ; 100207 ; 1009 ;

摘要：

Single shot magnetic resonance (MR) diffusion imaging was used to study the details of signal decay curves in experimental perturbations of cerebral perfusion induced by hypercapnia or death. Despite large perfusion increases observed with dynamic susceptibility-contrast MR imaging, no correlation with these changes was seen in either the diffusion coefficient or any other intravoxel incoherent motion (IVIM) model parameters in dog gray matter as arterial carbon dioxide pressure increased. Non-monoexponential signal decay in cat gray matter was seen both before and after death. In addition, cat gray matter demonstrated a steady decrease in the diffusion coefficient after death. These data are strong evidence that the fast component of the non-monoexponential diffusion-related signal decay is not due solely to perfusion. The authors believe that a second compartment of nonexchanging spins, most likely cerebrospinal fluid, accounts for the non-monoexponential decay.

引用

页码：377 / 384

页数：8

共 47 条

[1]

Le Bihan D, Breton E, Lallemand D, Aubin ML, Vignaud J, Laval-Jeantet M, Separation of diffusion and perfusion in intravoxel incoherent motion MR imaging, Radiology, 168, pp. 497-505, (1988)

[2]

McKinstry RC, Weisskoff RM, Cohen MS, Et al., (1990)

[3]

McKinstry RC, (1991)

[4]

Perman WH, Gado M, Sandstrom JC, White PF, Van Hemelrijck J, MR imaging assessment of brain perfusion at 1.5 T, Workshop syllabus: Future directions in MRI of diffusion and microcirculation, pp. 250-259, (1990)

[5]

Maki JH, MacFall JR, Johnson GA, The use of gradient flow compensation to separate diffusion and microcircula‐tory flow in MRI, MagnReson Med, 17, pp. 95-107, (1991)

[6]

Chenevert TL, Brunberg JA, Pipe JG, Quantitative perfusion and diffusion measurement of human brain lesions in vivo (abstr), (1990)

[7]

Chenevert TL, Pipe JG, Williams DM, Brunberg JA. Quantitative measurement of tissue perfusion and diffusion in vivo, Magn Reson Med, 17, pp. 197-212, (1991)

[8]

Stejskal EO, Tanner JE, Spin diffusion measurements: spin echoes in the presence of a time‐dependent field gradient, J Chem Phys, 42, pp. 288-292, (1965)

[9]

McKinstry RC, Belliveau JW, Buchbinder BR, Et al., Instant NMR diffusion and susceptibility‐contrast CBV imaging of patients with increased blood‐brain barrier permeability (abstr), (1990)

[10]

Le Bihan D, Turner R, Patronas N, Douek P, Comparison of two approaches to real‐time brain perfusion MR imaging: IVIM‐EPI and magnetic susceptibility induced contrast enhanced EPI (abstr), Book of abstracts: Society of Magnetic Resonance in Medicine 1990, (1990)

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