QUANTITATIVE CEREBRAL MAGNETIC-RESONANCE-IMAGING DURING ACTH TREATMENT OF MULTIPLE-SCLEROSIS

被引：3

作者：

ARMSPACH, JP

GOUNOT, D

NAMER, IJ

OHLENBUSCH, HH

RUMBACH, L

CHAMBRON, J

机构：

[1] Institut de Physique Biologique, Faculté de Médecine

[2] CHU Service de Neurologie

来源：

MAGNETIC RESONANCE IMAGING | 1993年 / 11卷 / 08期

关键词：

MRI; T-2 RELAXATION TIMES; MULTIEXPONENTIAL RELAXATION; MULTIPLE SCLEROSIS; ACTH;

D O I：

10.1016/0730-725X(93)90242-6

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：

Serial MR scans were performed with the 2DFT imaging method and the filtered backprojection imaging method on 12 patients with multiple sclerosis in acute phase, 4 in a relapsing/remitting form, and 8 in a progressive form, before, during and after ACTH treatment. Both T-1 and T-2mono relaxation times, obtained by fitting transverse magnetization decay curves with a monoexponential function within the apparently normal white matter and the areas of increased signal, were measured. With the backprojection method it was possible to fit the transverse magnetization decay curve with a biexponential function and obtain T-2long and T-2short relaxation times. The T-2mono and T-1 relaxation times of the apparently normal white matter were significantly different from those obtained for volunteers, but no significant differences were found before, during, or after treatment. The transverse magnetization decay curves of the areas of increased signal were better fitted by a biexponential function. No significant changes in these relaxation times were observed after ACTH treatment. These results argue against an anti-oedematous action of ACTH and may suggest that it has an immunosuppressant effect.

引用

页码：1147 / 1153

页数：7

共 27 条

[1]

Young, Hall, Pallis, Et al., Nuclear magnetic resonance imaging of the brain in multiple sclerosis, Lancet, pp. 1063-1066, (1981)

[2]

Ormerod, Miller, McDonald, Et al., The role of NMR imaging in the assessment of multiple sclerosis and isolated neurological lesions A quantitative study, Brain, 110, pp. 1575-1616, (1987)

[3]

Gersonde, Felsberg, Tolxdorff, Ratzel, Strobel, Analysis of multiple T2 proton relaxation processes in human head and imaging on the basis of selective and assigned T2 values, Magn. Reson. Med., 1, pp. 463-477, (1984)

[4]

Schad, Brix, Semmler, Gukel, Lorenz, Two exponential analysis of spin spin proton relaxation time in MR imaging using surface coils, Magn. Reson. Imaging., 7, pp. 357-362, (1989)

[5]

Mulkern, Wong, Jakal, Bleier, Sandor, Jolesz, CPMG imaging sequences for high field in vivo transverse relaxation studies, Magn. Reson. Med., 16, pp. 67-79, (1990)

[6]

Larsson, Frederiksen, Petersen, Nordenko, Zeeberg, Et al., Assessment of demyelination, oedema, and gliosis by in vivo determination of T1 and T2 in the brain of patients with acute attack, Magn. Reson. Med., 11, pp. 337-348, (1989)

[7]

Armspach, Gounot, Rumbach, Chambron, In vivo determination of multiexponential T2 relaxation in the brain of patients with multiple sclerosis, Magn. Reson. Imaging, 9, pp. 107-113, (1991)

[8]

Mathur de Vre, Biochemical implication of the relaxation behaviour of water related to NMR imaging, Br. J. Radiol., 57, pp. 955-976, (1984)

[9]

Poser, Paty, Scheinberg, Et al., New diagnostic criteria for multiple sclerosis: guidelines for research protocols, Ann. Neurol., 13, pp. 227-231, (1983)

[10]

Kurtzke, Rating neurological impairement in multiple sclerosis: An expanded disability status scale (DSS), Neurology, 33, pp. 1444-1452, (1983)

← 1 2 3 →