Systems and methods for achieving a recovery of spins of nuclei

Details Systems and methods for achieving a recovery of spins of nuclei Systems and methods for achieving a recovery of spins of nuclei

2002-07-09

2004-08-03

Fulton, Christopher W. (Department: 2859)

Electricity: measuring and testing

Particle precession resonance

Using a nuclear resonance spectrometer system

Reexamination Certificate

active

06771069

ABSTRACT:

BACKGROUND OF THE INVENTION
The present invention relates to a spin exciting method, a magnetic resonance imaging method, and a magnetic resonance imaging system. More particularly, the present invention relates to a spin exciting method, a magnetic resonance imaging method, and a magnetic resonance imaging system for performing magnetic resonance imaging according to a fast spin echo (FSE) technique combined with an inversion recovery (IR) technique.
In a magnetic resonance imaging (MRI) system, a subject of imaging is carried into a bore of a magnet system, that is, an imaging space in which a static magnetic field is created. Magnetic field gradients and a radio-frequency magnetic field are applied to the subject in order to excite spins in the subject. Consequently, a magnetic resonance signal is induced, and an image is reconstructed based on the signal received.
A sequence of exciting spins so as to induce a magnetic resonance signal and receiving the signal is repeated at predetermined intervals of a repetition time TR. The TR is often set to a time long enough for the excited spins to recover to exhibit an original longitudinal magnetization. When an imaging time must be shortened, the TR is set to a short time and spins are forcibly recovered. The forcible recovery of spins is achieved with additional excitation. This technique is referred to as fast recovery.
Japanese Examined Patent Publication No. 4-21488 describes that the fast recovery is combined with the IR. In short, as shown in
FIG. 7
, spins are turned 180° with application of a 180° pulse and thus brought to an inversion. Thereafter, when a predetermined inversion time TI has elapsed, a 90° pulse is applied in order to turn the spins 90°. A free induction decay (FID) signal that is induced accordingly is then acquired.
Thereafter, when a half of an echo time TE has elapsed, a −180° pulse is applied in order to reverse the spins. Thereafter, when a half of the TE has elapsed, a −90° pulse is applied in order to turn the spins −90° and a 180° pulse is then applied in order to reverse the spins. Thus, the fast recovery of the spins is achieved.
U.S. Pat. No. 6,054,853 describes that the fast recovery is combined with the FSE. In short, as shown in
FIG. 8
, a 90° x pulse is applied in order to excite spins and turn them 90° with respect to an x axis. Thereafter, when a half of an echo space esp has elapsed, a 180° y pulse is applied in order to reverse the spins with respect to a y axis. Thereafter, when the esp has elapsed, the 180° y pulse is applied in order to reverse the spins again with respect to the y axis. When the echo space esp has elapsed, the 180° y pulse is applied in order to reverse the spins again with respect to the y axis. Consequently, a spin echo is acquired during the echo space esp between applications of the 180° y pulse.
When a half of the echo space esp has elapsed since the last application of the 180° y pulse, a −90° x pulse is applied in order to turn the spins −90°, and a 180° x pulse is applied in order to reverse the spins. Thus, the fast recovery of the spins is achieved.
According to the technology described in the Japanese Examined Patent Publication No. 4-21488, the fast recovery employing the −90° pulse and 180° pulse is achieved through unselective excitation that is not intended to select a slice. This disables multiple slice imaging that interleaves pulse sequences like the foregoing one and involves a plurality of slices.
According to the related art described in the U.S. Pat. No. 6054853, the fast recovery employing the −90° x pulse and 180° is performed through selective excitation. However, a selected slice is not perfectly square. It is not easy to properly achieve the fast recovery using the two selective excitation pulses.
Moreover, the number of reversals of spins stemming from application of the 180° y pulse is an odd value. If the degree of the reversal of spins stemming from application of the 180° y pulse has an error, the spins are not restored to exactly face along the x-y plane. Therefore, the succeeding fast recovery is achieved imperfectly.
SUMMARY OF THE INVENTION
Therefore, an object of the present invention is to realize a spin exciting method, a magnetic resonance imaging method, and a magnetic resonance imaging system for properly performing fast recovery during magnetic resonance imaging in which the fast spin echo technique combined with the inversion recovery technique is implemented.
(1) In one aspect of the present invention intended to solve the aforesaid problems, there is provided a spin exciting method for producing an image using a magnetic resonance signal induced by spins in a subject being imaged according to the fast spin echo technique combined with the inversion recovery. Specifically, a 180° pulse is applied in order to excite spins. Thereafter, when a first time has elapsed, a first 90° x pulse is applied in order to excite the spins. Thereafter, when a second time has elapsed, a 180° y pulse is applied in order to excite the spins. Thereafter, when a third time that is double the second time has elapsed, the 180° y pulse is applied an odd number of times in order to sequentially excite the spins. Thereafter, when the second time has elapsed, a second 90° x pulse is applied in order to excite the spins.
(2) In another aspect of the present invention intended to solve the aforesaid problems, there is provided a magnetic resonance imaging method for producing an image using a magnetic resonance signal induced by spins in a subject being imaged according to the fast spin echo technique combined with the inversion recovery technique. Specifically, a 180° pulse is applied in order to excite spins. Thereafter, when a first time has elapsed, a first 90° x pulse is applied in order to excite the spins. Thereafter, when a second time has elapsed, a 180° y pulse is applied in order to excite the spins. Thereafter, when a third time that is double the second time has elapsed, the 180° y pulse is applied an odd number of times in order to sequentially excite the spins. Thereafter, when the second time has elapsed, a second 90° x pulse is applied in order to excite the spins. A spin echo is read during the third time, and an image is produced based on the spin echo.
(3) In another aspect of the present invention intended to solve the aforesaid problems, there is provided a magnetic resonance imaging system for producing an image using a magnetic resonance signal induced by spins in a subject being imaged according to the fast spin echo technique combined with the inversion recovery technique. The magnetic resonance imaging system includes a spin exciting means, an echo reading means, and an image producing means. The spin exciting means excites spins with application of a 180° pulse. Thereafter, when a first time has elapsed, the spin exciting means applies a first 90° x pulse to excite the spins. Thereafter, when a second time has elapsed, the spin exciting means applies a 80° y pulse to excite the spins. Thereafter, when a third time that is double the second time has elapsed, the spin exciting means applies the 180° y pulse an odd number of times to excite the spins sequenlially. Thereafter, when the second time has elapsed, the spin exciting means applies a second 90° x pulse to excite the spins. The echo reading means reads a spin echo during the third time. The image producing means produces an image according to the spin echo.
In the aspects of the present invention set forth in paragraphs (1) to (3), a 180° pulse is applied in order to excite spins. Thereafter, when the first time has elapsed, a first 90° x pulse is applied in order to excite the spins. Thereafter, when the second time has elapsed, a 180° y pulse is applied in order to excite the spins. Thereafter, when the third time that is double the second time has elapsed, the 180° y pulse is applied an odd number of times in order to excite the spins. Thereafter, when the second time has elapsed, a second 90° x pulse is applied in order

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