𝔖 Bobbio Scriptorium
✦   LIBER   ✦

Evaluation of cerebral gray and white matter metabolite differences by spectroscopic imaging at 4.1T

✍ Scribed by Hoby P. Hetherington; Graeme F. Mason; Jullie W. Pan; Steven L. Ponder; J. Thomas Vaughan; Donald B. Twieg; Gerald M. Pohost

Publisher
John Wiley and Sons
Year
1994
Tongue
English
Weight
644 KB
Volume
32
Category
Article
ISSN
0740-3194

No coin nor oath required. For personal study only.

✦ Synopsis

Abstract

Using a 4.1 T whole body system, we have acquired ^1^H spectroscopic imaging (SI) data of N‐acetyl (NA) compounds, creatine (CR), and choline (CH) with nominal voxel sizes of 0.5 cc (1.15 cc after filtering). We have used the SI data to estimate differences in cerebral metabolites of human gray and white matter. To evaluate the origin of an increased CWNA and CWNA ratios in gray matter relative to white matter, we measured the T~1~ and T~2~ of CR, NA, and CH in gray and white matter using moderate resolution SI imaging. In white matter the T~2~s of NA, CR, and CH were 233 Β± 27,141 Β± 18, and 167 Β± 20 ms, respectively, and 227 Β± 27,140 Β± 16, and 189 Β± 25 ms in gray matter. The T, values for NA, CR, and CH were 1267 Β±141, 1487 Β± 146, and 1111 Β± 136 ms in gray matter and 1260 Β± 154, 1429 & 233, and 1074 Β± 146 ms in white matter. After correcting for T~1~ and T~2~ losses, creatine content was significantly lower in white matter than gray (P < e 0.01, t‐test), with a white/gray content ratio of 0.8, in agreement with biopsy and in vivo measurements at 1.5 and 2.0T.

πŸ“œ SIMILAR VOLUMES

Evaluation of 31P metabolite differences
Evaluation of 31P metabolite differences in human cerebral gray and white matter
✍ Graeme F. Mason; Wen-Jang Chu; J. Thomas Vaughan; Steven L. Ponder; Donald B. Tw πŸ“‚ Article πŸ“… 1998 πŸ› John Wiley and Sons 🌐 English βš– 829 KB

## Abstract ^31^P NMR is commonly used to study brain energetics in health and disease. Due to sensitivity constraints, the NMR measurements are typically made in volumes that do not contain pure gray or white matter. For accurate evaluation of abnormalities in brain metabolite levels, it is necess

Evaluation of multiple sclerosis by 1H s
Evaluation of multiple sclerosis by 1H spectroscopic imaging at 4.1 T
✍ Jullie W. Pan; Hoby P. Hetherington; J. Thomas Vaughan; Galen Mitchell; Gerald M πŸ“‚ Article πŸ“… 1996 πŸ› John Wiley and Sons 🌐 English βš– 692 KB

## Abstract The authors report on high‐field (4.1 T) magnetic resonance ^1^H spectroscopic imaging studies on eight patients with relapsing remitting multiple sclerosis (mean expanded disability status scale (EDSS) 1.0) and eight normal controls. Using __T__~1~ weighted imaging to determine lesion

Diffusion tensor eigenvector directional
Diffusion tensor eigenvector directional color imaging patterns in the evaluation of cerebral white matter tracts altered by tumor
✍ Aaron S. Field; Andrew L. Alexander; Yu-Chien Wu; Khader M. Hasan; Brian Witwer; πŸ“‚ Article πŸ“… 2004 πŸ› John Wiley and Sons 🌐 English βš– 726 KB

## Abstract ## Purpose To categorize the varied appearances of tumor‐altered white matter (WM) tracts on diffusion tensor eigenvector directional color maps. ## Materials and Methods Diffusion tensor imaging (DTI) was obtained preoperatively in 13 patients with brain tumors ranging from benign t

Assessment of absolute metabolite concen
Assessment of absolute metabolite concentrations in human tissue by 31P MRS in vivo. Part I: Cerebrum, cerebellum, cerebral gray and white matter
✍ Reto Buchli; Corinne O. Duc; Ernst Martin; Peter Boesiger πŸ“‚ Article πŸ“… 1994 πŸ› John Wiley and Sons 🌐 English βš– 652 KB

## Abstract Absolute metabolite concentrations were determined in four different brain regions using phosphorus magnetic resonance spectroscopy (^31^P MRS) on 10 healthy adult volunteers. Localized spectra were collected simultaneously from the cerebellum and the cerebrum and, later, from deep whit