𝔖 Bobbio Scriptorium
✦   LIBER   ✦

Magnetic resonance properties of ex vivo breast tissue at 1.5 T

✍ Scribed by Simon J. Graham; Sola Ness; Bradford S. Hamilton; Michael J. Bronskill

Publisher
John Wiley and Sons
Year
1997
Tongue
English
Weight
942 KB
Volume
38
Category
Article
ISSN
0740-3194

No coin nor oath required. For personal study only.

✦ Synopsis

Abstract

The magnetic resonance absorption spectrum, T~1~ and T~2~ relaxation time distributions, and magnetization transfer properties of ex vivo breast tissue have been characterized at 1.5 T and 37Β°C. The fraction of fibroglandular tissue within individual tissue samples (n = 31) was inferred from the tissue volumetric water content obtained by integration of resolvable broad‐line fat and water resonances. The spectroscopically estimated water content was strongly correlated with that extracted enzymatically (Pearson correlation coefficient 0.98, P Β« 0.01), which enabled the assignment of principal relaxation components for fibroglandular tissue (T~2~ = 0.04 Β± 0.01, T~1~ = 1.33 Β± 0.24 s), and for adipose tissue (T~2~ = 0.13 Β± 0.01, T~1~ = 0.23 Β± 0.01 s, and T~2~ = 0.38 Β± 0.03, T~1~ = 0.62 Β± 0.16 s). The relaxation components for fibroglandular tissue exhibited strong magnetization transfer, whereas those for adipose tissue showed little magnetization transfer effect. These results ultimately have applicability to the optimization of clinical magnetic resonance imaging and research investigations of the breast.

πŸ“œ SIMILAR VOLUMES

In vivo magnetic resonance elastography
In vivo magnetic resonance elastography of human brain at 7 T and 1.5 T
✍ Uwe Hamhaber; Dieter Klatt; Sebastian Papazoglou; Maurice Hollmann; JΓΆrg Stadler πŸ“‚ Article πŸ“… 2010 πŸ› John Wiley and Sons 🌐 English βš– 845 KB

## Abstract ## Purpose: To investigate the feasibility of quantitative in vivo ultrahigh field magnetic resonance elastography (MRE) of the human brain in a broad range of low‐frequency mechanical vibrations. ## Materials and Methods: Mechanical vibrations were coupled into the brain of a health

In vivo high-resolution magnetic resonan
In vivo high-resolution magnetic resonance skin imaging at 1.5 T and 3 T
✍ JoΓ«lle K. Barral; Neal K. Bangerter; Bob S. Hu; Dwight G. Nishimura πŸ“‚ Article πŸ“… 2010 πŸ› John Wiley and Sons 🌐 English βš– 336 KB πŸ‘ 1 views

As a noninvasive modality, MR is attractive for in vivo skin imaging. Its unique soft tissue contrast makes it an ideal imaging modality to study the skin water content and to resolve the different skin layers. In this work, the challenges of in vivo high-resolution skin imaging are addressed. Three

Ex Vivo Evaluation of Ferromagnetism, He
Ex Vivo Evaluation of Ferromagnetism, Heating, and Artifacts of Breast Tissue Expanders Exposed to a 1.5-T MR System
✍ Linda-Lynn Pagan; Frank G. Shellock; R. James Brenner; Barry Rothman πŸ“‚ Article πŸ“… 1995 πŸ› John Wiley and Sons 🌐 English βš– 357 KB

## Abstract Three breast tissue expanders were evaluated for compatibility with MR imaging (1.5 Tesla). The metallic components of the breast tissue expanders were shown to be nonferromagnetic, heating .2Β°C and the artifacts varied. These results indicate that MR procedures may be performed safely

Ceramic surgical instruments: Ex vivo ev
Ceramic surgical instruments: Ex vivo evaluation of compatibility with MR imaging at 1.5 T
✍ Frank G. Shellock; Vincent J. Shellock πŸ“‚ Article πŸ“… 1996 πŸ› John Wiley and Sons 🌐 English βš– 362 KB

## Abstract The purpose of this study was to evaluate the MR compatibility of ceramic instruments. Nine different ceramic instruments were tested with respect to ferromagnetism, heating, and artifacts using previously described techniques. There was no magnetic field attraction, temperature increas

Metallic clips used for scleral buckling
Metallic clips used for scleral buckling: Ex vivo evaluation of ferromagnetism at 1.5 T
✍ Haleh Bakshandeh; Frank G. Shellock; Charles J. Schatz; Stacy M. Morisoli πŸ“‚ Article πŸ“… 1993 πŸ› John Wiley and Sons 🌐 English βš– 82 KB

MAGNETIC RESONANCE (MR) IMAGING is contraindicated in patients with certain ferromagnetic implants, devices, and materials, primarily because of the hazards associated with movement or dislodgment (1). This is particularly true for metallic implants located in sensitive areas of the body, such as in