7T Human Spine Imaging Arrays With Adjustable Inductive Decoupling

Bing Wu; Chunsheng Wang; Roland Krug; Duan Xu; Yong Pang; Suchandrima Banerjee; Douglas A. Kelley; Daniel B. Vigneron; Sarah J. Nelson; Sharmila Majumdar; Xiaoliang Zhang; Daniel B. Vigneron; Sarah J. Nelson; Sharmila Majumdar

doi:10.1109/TBME.2009.2030170

7T Human Spine Imaging Arrays With Adjustable Inductive Decoupling

Bing Wu
, Chunsheng Wang
, Roland Krug
, Duan Xu
, Yong Pang
, Suchandrima Banerjee
, Douglas A. Kelley
, Daniel B. Vigneron
, Sarah J. Nelson
, Sharmila Majumdar
, Xiaoliang Zhang
, Daniel B. Vigneron
, Sarah J. Nelson
, Sharmila Majumdar

Department of Biomedical Engineering

University at Buffalo

Research output: Contribution to journal › Article › peer-review

59 Scopus citations

Abstract

Ultrahigh-field human spine RF transceiver coil arrays face daunting technical challenges in achieving large imaging coverage with sufficient B₁ penetration and sensitivity, and in attaining robust decoupling among coil elements. In this paper, human spine coil arrays for ultrahigh field were built and studied. Transceiver arrays with loop-shaped microstrip transmission line were designed, fabricated, and tested for 7-tesla (7T) MRI. With the proposed adjustable inductive decoupling technique, the isolation between adjacent coil elements is easily addressed. Preliminary results of human spine images acquired using the transceiver arrays demonstrate the feasibility of the design for ultrahigh-field MR applications and its robust performance for parallel imaging.

Original language	English
Pages (from-to)	397-403
Number of pages	7
Journal	IEEE Transactions on Biomedical Engineering
Volume	57
Issue number	2
DOIs	https://doi.org/10.1109/TBME.2009.2030170
State	Published - Feb 2010

Keywords

Array
RF coil
decoupling
high-field MRI
human spine
microstrip
parallel imaging

Access to Document

10.1109/TBME.2009.2030170

Cite this

@article{81f95f8c44704bbe9e4464a7fc9bec49,

title = "7T Human Spine Imaging Arrays With Adjustable Inductive Decoupling",

abstract = "Ultrahigh-field human spine RF transceiver coil arrays face daunting technical challenges in achieving large imaging coverage with sufficient B1 penetration and sensitivity, and in attaining robust decoupling among coil elements. In this paper, human spine coil arrays for ultrahigh field were built and studied. Transceiver arrays with loop-shaped microstrip transmission line were designed, fabricated, and tested for 7-tesla (7T) MRI. With the proposed adjustable inductive decoupling technique, the isolation between adjacent coil elements is easily addressed. Preliminary results of human spine images acquired using the transceiver arrays demonstrate the feasibility of the design for ultrahigh-field MR applications and its robust performance for parallel imaging.",

keywords = "Array, RF coil, decoupling, high-field MRI, human spine, microstrip, parallel imaging",

author = "Bing Wu and Chunsheng Wang and Roland Krug and Duan Xu and Yong Pang and Suchandrima Banerjee and Kelley, \{Douglas A.\} and Vigneron, \{Daniel B.\} and Nelson, \{Sarah J.\} and Sharmila Majumdar and Xiaoliang Zhang and Vigneron, \{Daniel B.\} and Nelson, \{Sarah J.\} and Sharmila Majumdar",

year = "2010",

month = feb,

doi = "10.1109/TBME.2009.2030170",

language = "English",

volume = "57",

pages = "397--403",

journal = "IEEE Transactions on Biomedical Engineering",

issn = "0018-9294",

publisher = "IEEE Computer Society",

number = "2",

}

TY - JOUR

T1 - 7T Human Spine Imaging Arrays With Adjustable Inductive Decoupling

AU - Wu, Bing

AU - Wang, Chunsheng

AU - Krug, Roland

AU - Xu, Duan

AU - Pang, Yong

AU - Banerjee, Suchandrima

AU - Kelley, Douglas A.

AU - Vigneron, Daniel B.

AU - Nelson, Sarah J.

AU - Majumdar, Sharmila

AU - Zhang, Xiaoliang

AU - Vigneron, Daniel B.

AU - Nelson, Sarah J.

AU - Majumdar, Sharmila

PY - 2010/2

Y1 - 2010/2

N2 - Ultrahigh-field human spine RF transceiver coil arrays face daunting technical challenges in achieving large imaging coverage with sufficient B1 penetration and sensitivity, and in attaining robust decoupling among coil elements. In this paper, human spine coil arrays for ultrahigh field were built and studied. Transceiver arrays with loop-shaped microstrip transmission line were designed, fabricated, and tested for 7-tesla (7T) MRI. With the proposed adjustable inductive decoupling technique, the isolation between adjacent coil elements is easily addressed. Preliminary results of human spine images acquired using the transceiver arrays demonstrate the feasibility of the design for ultrahigh-field MR applications and its robust performance for parallel imaging.

AB - Ultrahigh-field human spine RF transceiver coil arrays face daunting technical challenges in achieving large imaging coverage with sufficient B1 penetration and sensitivity, and in attaining robust decoupling among coil elements. In this paper, human spine coil arrays for ultrahigh field were built and studied. Transceiver arrays with loop-shaped microstrip transmission line were designed, fabricated, and tested for 7-tesla (7T) MRI. With the proposed adjustable inductive decoupling technique, the isolation between adjacent coil elements is easily addressed. Preliminary results of human spine images acquired using the transceiver arrays demonstrate the feasibility of the design for ultrahigh-field MR applications and its robust performance for parallel imaging.

KW - Array

KW - RF coil

KW - decoupling

KW - high-field MRI

KW - human spine

KW - microstrip

KW - parallel imaging

UR - https://www.scopus.com/pages/publications/77950357155

U2 - 10.1109/TBME.2009.2030170

DO - 10.1109/TBME.2009.2030170

M3 - Article

C2 - 19709956

SN - 0018-9294

VL - 57

SP - 397

EP - 403

JO - IEEE Transactions on Biomedical Engineering

JF - IEEE Transactions on Biomedical Engineering

IS - 2

ER -

7T Human Spine Imaging Arrays With Adjustable Inductive Decoupling

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this