PARTIAL RF ECHO-PLANAR IMAGING WITH THE FAISE METHOD .2. CONTRAST EQUIVALENCE WITH SPIN-ECHO SEQUENCES

被引：46

作者：

MELKI, PS ^{[1
]}

JOLESZ, FA ^{[1
]}

MULKERN, RV ^{[1
]}

机构：

[1] HARVARD UNIV,CHILDRENS HOSP,SCH MED,DEPT RADIOL,BOSTON,MA 02115

来源：

MAGNETIC RESONANCE IN MEDICINE | 1992年 / 26卷 / 02期

关键词：

D O I：

10.1002/mrm.1910260213

中图分类号：

R8 [特种医学]; R445 [影像诊断学];

学科分类号：

1002 ; 100207 ; 1009 ;

摘要：

The fast acquisition interleaved spin‐echo (FAISE) sequence and its dual‐echo version (DEFAISE) are partial RF echo‐planar methods which utilize a specific phase‐encode reordering algorithm to manipulate T2 contrast via an operator‐controlled pseudo‐echo time, pTE. The repetition time, TR, between successive applications of the Carr‐Purcell‐ Meiboom‐Gill (CPMG) echo trains used in FAISE may be reduced to introduce T1 weighting. To quantitatively determine the extent to which FAISE T1 and T2 contrast characteristics agree with spin‐echo methods, signal intensities from FAISE acquisitions were compared with signal intensities from equivalent CPMG acquisitions. In phantoms and in human heads, the contrast Characteristics of FAISE are found to be highly correlated with that obtained with equivalent CPMG sequences. However, conventional SE sequences generally utilize longer echo spacings than employed with FAISE/CPMG. Thus, echo spacing‐dependent mechanisms such as spin‐spin coupling and magnetic susceptibility lead to some differences in contrast between conventional SE and FAISE. Finally, FAISE appears to be more sensitive to magnetization transfer effects than conventional SE sequences since more off‐resonance irradiation is applied to individual slices during multislice acquisitions. Copyright © 1992 Wiley‐Liss, Inc., A Wiley Company

引用

页码：342 / 354

页数：13

共 9 条

[1] ANALYSIS OF CARR-PURCELL SPIN-ECHO NMR EXPERIMENTS ON MULTIPLE-SPIN SYSTEMS .I. EFFECT OF HOMONUCLEAR COUPLING [J].

ALLERHAN.A .

JOURNAL OF CHEMICAL PHYSICS, 1966, 44 (01) :1-&

[2] INCIDENTAL MAGNETIZATION TRANSFER CONTRAST IN STANDARD MULTISLICE IMAGING [J].

DIXON, WT ;

ENGELS, H ;

CASTILLO, M ;

SARDASHTI, M .

MAGNETIC RESONANCE IMAGING, 1990, 8 (04) :417-422

[3] RARE IMAGING - A FAST IMAGING METHOD FOR CLINICAL MR [J].

HENNIG, J ;

NAUERTH, A ;

FRIEDBURG, H .

MAGNETIC RESONANCE IN MEDICINE, 1986, 3 (06) :823-833

[4] COMPARING THE FAISE METHOD WITH CONVENTIONAL DUAL-ECHO SEQUENCES [J].

MELKI, PS ;

MULKERN, RV ;

PANYCH, LP ;

JOLESZ, FA .

JMRI-JOURNAL OF MAGNETIC RESONANCE IMAGING, 1991, 1 (03) :319-326

[5]

NELSON T R, 1984, Magnetic Resonance Imaging, V2, P285, DOI 10.1016/0730-725X(84)90194-2

[6] IMPROVED PRECISION IN CALCULATED T1 MR IMAGES USING MULTIPLE SPIN-ECHO ACQUISITION [J].

RIEDERER, SJ ;

BOBMAN, SA ;

LEE, JN ;

FARZANEH, F ;

WANG, HZ .

JOURNAL OF COMPUTER ASSISTED TOMOGRAPHY, 1986, 10 (01) :103-110

[7] OXYGENATION DEPENDENCE OF THE TRANSVERSE RELAXATION-TIME OF WATER PROTONS IN WHOLE-BLOOD AT HIGH-FIELD [J].

THULBORN, KR ;

WATERTON, JC ;

MATTHEWS, PM ;

RADDA, GK .

BIOCHIMICA ET BIOPHYSICA ACTA, 1982, 714 (02) :265-270

[8]

WEINGARTEN K, 1991, AM J NEURORADIOL, V12, P475

[9] MAGNETIZATION TRANSFER CONTRAST (MTC) AND TISSUE WATER PROTON RELAXATION INVIVO [J].

WOLFF, SD ;

BALABAN, RS .

MAGNETIC RESONANCE IN MEDICINE, 1989, 10 (01) :135-144

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