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Transceive surface coil array for magnetic resonance imaging and spectroscopy

a magnetic resonance imaging and spectroscopy technology, applied in the field of magnetic resonance imaging (mri), can solve the problems of increasing local and global specific absorption rate, increasing radiation loss, and less effective high field regime, and achieving the effects of reducing image artefacts, reducing radiation loss, and reducing radiation loss

Inactive Publication Date: 2009-03-26
THE JOHN P ROBARTS RES INST
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

The solution enables high signal-to-noise ratio (SNR) imaging across various field strengths, reduces image artifacts, and allows for flexible coil placement, enhancing the efficiency of fast parallel imaging techniques while maintaining the benefits of receive-only surface coils.

Problems solved by technology

Although these volume coils operate well at low magnetic field strengths, they become less effective in the high field regime i.e. at magnetic field strengths greater than 3T.
Several imaging problems arise in this full wavelength regime namely, increased radiation losses, increased local and global specific absorption rate (SAR), and dielectric resonance effects that create both inhomogeneous images and signal loss.
The predominant impediment to surface coil array design is however, the strong magnetic coil-to-coil coupling.
Unfortunately, the resultant overlapping sensitivity profiles are less than ideal for fast parallel imaging techniques, which are more effective when sensitivity profiles of individual surface coils do not overlap.
Unfortunately, low (or high) impedance preamplifiers are not generally available off-the-shelf and are therefore, more complex, expensive and time consuming to implement.
Furthermore, low input impedance RF power amplifiers are not widely commercially available off-the-shelf, thereby practically limiting this coil-to-coil magnetic coupling reduction technique to receive-only applications.
However, considerable electric field loss and strong coupling between lattice networks limits their application at higher field strengths.
Unfortunately, this design requires a common ground resulting in electric field losses and requires a common connection between all of the coils, which is geometrically restrictive.
Unfortunately, this ladder network is complex and appears to be limited to low field MRI applications, as considerable electric field losses, and strong coupling between lattice networks would limit its application at high field strengths.

Method used

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  • Transceive surface coil array for magnetic resonance imaging and spectroscopy
  • Transceive surface coil array for magnetic resonance imaging and spectroscopy
  • Transceive surface coil array for magnetic resonance imaging and spectroscopy

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Embodiment Construction

[0046]Turning now to FIGS. 1 and 2, a transceive surface coil (TSC) array for magnetic resonance imaging and spectroscopy is shown and is generally identified by reference numeral 20. As can be seen, TSC array 20 comprises a cylindrical supporting shell 22 on which are mounted a plurality of generally equally spaced, rectangular surface coils 24. The shell 22 is formed of acrylic and has inside and outside diameters of approximately 24.1 cm and 25.4 cm respectively. In this particular example, the TSC array includes eight (8) surface coils 24. Each of the surface coils 24 is substantially identical and is constructed of conductive strips, in this case copper tape, having a thickness equal to approximately 50 μm. Each surface coil 24 includes two legs 26 having a length of approximately 21 cm and two legs 28 having a length of approximately 8.1 cm. The width of each leg is approximately 63.5 mm and the inter-surface coil spacing is approximately 2 cm.

[0047]A magnetic decoupling circu...

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Abstract

A surface coil array comprises a surface coil support and an arrangement of non-overlapping magnetically decoupled surface coils mounted on the support. The surface coils encompass a volume into which a target to be imaged is placed. Magnetic decoupling circuits act between adjacent surface coils. Impedance matching circuitry couples the surface coils to conventional transmit and receive components.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS[0001]This application claims the benefit of U.S. Provisional Patent Application No. 60 / 554,350 filed on Mar. 19, 2004 for an invention entitled “Transceive Surface Coil Array For Magnetic Resonance Imaging and Spectroscopy”.FIELD OF THE INVENTION[0002]The present invention relates generally to magnetic resonance imaging (MRI) and more specifically, to a transceive surface coil array for magnetic resonance imaging and spectroscopy.BACKGROUND OF THE INVENTION[0003]Nuclear Magnetic Resonance (NMR) Imaging, or Magnetic Resonance Imaging (MRI) as it is commonly known, is a non-invasive imaging modality that can produce high resolution, high contrast images of the interior of the human body. MRI involves the interrogation of the nuclear magnetic moments of a subject placed in a strong magnetic field with radio frequency (RF) magnetic fields. A MRI system typically comprises a fixed magnet to create the main strong magnetic field, a gradient coil ass...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): G01R33/341G01R33/34G01R33/3415G01R33/36G01V3/00
CPCG01R33/34046G01R33/365G01R33/3415
Inventor PINKERTON, ROBERT G.MENON, RAVI S.
Owner THE JOHN P ROBARTS RES INST
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