𝔖 Bobbio Scriptorium
✦   LIBER   ✦

High-speed STEAM MRI of the human heart

✍ Scribed by J. Frahm; W. Hänicke; H. Bruhn; M. L. Gyngell; K. D. Merboldt

Publisher
John Wiley and Sons
Year
1991
Tongue
English
Weight
730 KB
Volume
22
Category
Article
ISSN
0740-3194

No coin nor oath required. For personal study only.

✦ Synopsis

Abstract

High‐speed STEAM MR images of the normal human heart were obtained from single cardiac cycles using a 2.0‐T whole‐body system equipped with conventional 10 mT m^−1^ gradients. The single‐shot 90°‐TE/2–90°‐TM‐(α‐TE/2‐Acq)~n~ pulse sequence acquires n differently phase‐encoded stimulated echoes. Measuring times of 127–254 ms were achieved using a “repetition time” of 3.96 ms in conjunction with data matrices of 32–64 × 128 pixels covering a field‐of‐view of 250–350 mm. The sequence provides easy access to anatomical short‐axis and long‐axis views of the heart by single and double oblique rotation of the image orientation. STEAM images resemble the features of spinecho images with respect to chemical shifts, susceptibilities, and flow. Thus, no additional techniques are required for the suppression of blood signals. EKG‐triggered acquisitions demonstrate that slice‐selective STEAM sequences using short TM intervals allow an unambiguous delineation of those parts of the myocardium that remain stationary within the selected plane throughout the entire imaging process. Neither spins leaving nor entering the slice defined by the initial 90° RF pulses give rise to a stimulated echo and therefore do not contribute to the resulting image. © 1991 Academic Press, Inc.

📜 SIMILAR VOLUMES

Diffusion imaging of the human brain in
Diffusion imaging of the human brain in vivo using high-speed STEAM MRI
✍ Klaus-Dietmar Merboldt; Wolfgang Hänicke; Harald Bruhn; Michael L. Gyngell; Jens 📂 Article 📅 1992 🏛 John Wiley and Sons 🌐 English ⚖ 935 KB

## Abstract This paper describes a new method for diffusion imaging of the human brain __in vivo__ that is based on a combination of diffusion‐encoding gradients with high‐speed STEAM MR imaging. The single‐shot sequence 90°‐TE/2‐90°‐TM‐(α‐TE/2‐STE)~__n__~ generates __n__ = 32–64 differently phase‐

Black-blood imaging of the human heart u
Black-blood imaging of the human heart using rapid stimulated echo acquisition mode (STEAM) MRI
✍ Alexander Karaus; Klaus-Dietmar Merboldt; Joachim Graessner; Jens Frahm 📂 Article 📅 2007 🏛 John Wiley and Sons 🌐 English ⚖ 638 KB

## Abstract ## Purpose To develop a rapid stimulated echo acquisition mode (STEAM) MRI technique for “black‐blood” imaging of the human heart that overcomes the single‐slice limitation and partially compromised blood suppression associated with double inversion‐recovery techniques. ## Materials a

0.3-second flash mri of the human heart
0.3-second flash mri of the human heart
✍ J. Frahm; K. D. Merboldt; H. Bruhn; M. L. Gyngell; W. Hänicke; D. Chien 📂 Article 📅 1990 🏛 John Wiley and Sons 🌐 English ⚖ 536 KB

## Abstract Flow‐suppressed FLASH MR images of the human heart have been recorded within a measuring time of 0.3 s using a 2.0‐T whole‐body research system (Siemens Magnetom) equipped with a conventional 10 mT m^−1^ gradient system. Subsecond imaging times have been achieved by reducing the repetit

MRI detects myocardial iron in the human
MRI detects myocardial iron in the human heart
✍ Nilesh R. Ghugre; Cathleen M. Enriquez; Ignacio Gonzalez; Marvin D. Nelson Jr.; 📂 Article 📅 2006 🏛 John Wiley and Sons 🌐 English ⚖ 423 KB

## Abstract Iron‐induced cardiac dysfunction is a leading cause of death in transfusion‐dependent anemia. MRI relaxation rates __R__~2~(1/__T__~2~) and __R__(1/__T__) accurately predict liver iron concentration, but their ability to predict cardiac iron has been challenged by some investigators. St

High-resolution longitudinal MRI of the
High-resolution longitudinal MRI of the transition to heart failure
✍ Peter N. Costandi; Andrew D. McCulloch; Jeffrey H. Omens; Lawrence R. Frank 📂 Article 📅 2007 🏛 John Wiley and Sons 🌐 English ⚖ 336 KB

## Abstract The development of heart failure (HF) is an evolving process that entails both structural and functional changes through time. While the physiological state of cardiac pathologies has been well characterized, less is known about the transition from a normal to a maladaptive state. Magne