J Hoenninger scite author profile

Although cross-sectional magnetic resonance examination of the head and body is useful for screening large regions of tissue, subsectional regions of the head and body often need to be examined. Orthogonally directed, selectively irradiated planes with different flip angles produce a spatially limited signal region from which two- or three-dimensional volume images can be reconstructed. Images with limited fields-of-view can be acquired in reduced imaging time. We present a general description of this technique. These subsectional or "inner volume" images eliminate respiratory motion artifacts by excluding moving tissues from the imaged volume. A result of this technique is a high signal from rapid pulsatile blood flow, produced without cardiac gating the pulse sequence.

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Magnetic Resonance Imaging the Velocity Vector Components of Fluid Flow

Feinberg

Crooks

Sheldon

et al. 1985

Magnetic Resonance in Med

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Encoding the precession phase angle of proton nuclei for Fourier analysis has produced accurate measurement of fluid velocity vector components by MRI. A pair of identical gradient pulses separated in time by exactly 1/2 TE, are used to linearly encode the phase of flow velocity vector components without changing the phase of stationary nuclei. Two-dimensional Fourier transformation of signals gave velocity density images of laminar flow in angled tubes which were in agreement with the laws of vector addition. These velocity profile images provide a quantitative method for the investigation of fluid dynamics and hemodynamics.

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Nuclear magnetic resonance whole-body imager operating at 3.5 KGauss.

Crooks¹,

Arakawa²,

Hoenninger³

et al. 1982

Radiology

226

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Nuclear magnetic resonance imaging of the abnormal live rat and correlations with tissue characteristics.

Herfkens¹,

Davis²,

Crooks³

et al. 1981

Radiology

127

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Nuclear magnetic resonance (NMR) images of live rats with sterile and pyogenic abscesses, hematomas, and various implanted and spontaneous neoplasms demonstrated good contrast differentiation between pathologic and surrounding normal tissues. This differentiation was maximal when both the T1 and T2 tissue relaxation times were used as criteria. Neoplasms have a broad range of T1 and T2 values and may be confused with abscesses or hematomas. Tissue rate constants (1/T1 and 1/T2) are mainly dependent on total water content, the exception being fat, which has a 1/T2 value much shorter than that expected on the basis of water content alone.

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Magnetic resonance imaging: effects of magnetic field strength.

Crooks¹,

Arakawa²,

Hoenninger³

et al. 1984

Radiology

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Magnetic resonance images of the head, abdomen, and pelvis of normal adult men were obtained using varying magnetic field strength, and measurements of T1 and T2 relaxations and of signal-to-noise (SN) ratios were determined. The T1 relaxation of gray matter, white matter, and muscle increases and T2 decreases with field strength, while T1 of fat remains relatively constant and T2 increases. As a consequence, for any one spin echo sequence, gray/white matter contrast decreases and muscle/fat contrast increases with field. SN levels rise rapidly up to 3.0 kgauss and then change more slowly, actually dropping for muscle. The optimum field for magnetic resonance imaging depends on tissue type, body part, and imaging sequence, so that it does not have a unique value. Magnetic resonance systems that operate in the 3.0-5.0 kgauss range achieve most or all of the gains that can be achieved by higher magnetic fields.

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J Hoenninger

Inner volume MR imaging: technical concepts and their application.

Magnetic Resonance Imaging the Velocity Vector Components of Fluid Flow

Nuclear magnetic resonance whole-body imager operating at 3.5 KGauss.

Nuclear magnetic resonance imaging of the abnormal live rat and correlations with tissue characteristics.

Magnetic resonance imaging: effects of magnetic field strength.

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