M. O’Donnell scite author profile

In principle, multiple-echo magnetic resonance imaging (MRI) can be used to estimate the spin-spin relaxation time, T2, which can then be used for quantitative tissue characterization. Although multiple echoes can be used to enhance the signal-to-noise ratio in an image, by echo addition, rf pulse imperfections modify the echo amplitudes resulting in significant errors in the estimate of T2. Imperfect 180 degree pulses do not completely invert the transverse magnetization so that the magnitude of the transverse component is reduced and a longitudinal component is generated. Successive application of such imperfect pulses generates many components that interact in a complex manner. The amplitudes of successive echoes are affected whenever the transverse components refocus, whereas the longitudinal components may be rotated into the transverse plane by subsequent pulses and may often add to the image signal or give rise to an image artifact. These effects have been analyzed theoretically and have been demonstrated for a wide range of rf pulse imperfections using both simple and composite pulses, through computer simulations based on the numerical solution of the Bloch equations. The theoretical and simulation results have been substantiated through experiments performed on a mineral oil phantom using a resistive prototype MR scanner operating at 6.35 MHz. In this paper we report the effects of improper pulse amplitude or duration for nonselective rf pulses on resonance. We separately describe the other types of imperfections caused by off-resonance effects and the use of selective pulses.

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Coded excitation system for improving the penetration of real-time phased-array imaging systems

O’Donnell

1992

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

336

104

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Based on an analysis of the inherent signal-to-noise ratio (SNR) in medical ultrasound imaging, SNR improvements of 15-20 dB are theoretically possible for real-time phased-array imagers using coded excitation. A very simple coded excitation for phased arrays based on the principles of ;pseudochirp' excitation and equalization filtering is described. This system is capable of SNR improvements of about 15 dB with range sidelobe levels acceptable for many medical imaging applications. Such improvements permit increased operating frequencies, and hence enhanced spatial resolution, for real-time array imagers. Both simulations and measurements are used to demonstrate the efficacy of the method.

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Optimizing the radiation pattern of sparse periodic linear arrays

Lockwood

Li²,

O’Donnell³

et al. 1996

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

199

104

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M. O’Donnell

Coherence factor of speckle from a multi-row probe

Errors in the measurements of T₂ using multiple‐echo MRI techniques. I. Effects of radiofrequency pulse imperfections

Coded excitation system for improving the penetration of real-time phased-array imaging systems

Optimizing the radiation pattern of sparse periodic linear arrays

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Resources

About

M. O’Donnell

Coherence factor of speckle from a multi-row probe

Errors in the measurements of T2 using multiple‐echo MRI techniques. I. Effects of radiofrequency pulse imperfections

Coded excitation system for improving the penetration of real-time phased-array imaging systems

Optimizing the radiation pattern of sparse periodic linear arrays

Contact Info

Product

Resources

About

Errors in the measurements of T₂ using multiple‐echo MRI techniques. I. Effects of radiofrequency pulse imperfections