DE2936465A1 - Imaging control for nuclear magnetic resonance scanner - has phase shifted signals and spin echo processing to eliminate residual magnetic effects - Google Patents

Abstract

An imaging control for a nuclear magnetic resonance scanner has the subject scanned layer by layer, and each layer split into lines. The signal is applied 180 degrees out of phase in two sets of patterns. The spin echos are processed in saturated field conditions and generate an imaging signal. The 180 degree offset signals eliminate residual magnetism which could cause smearing of the detected signals. The process provides clearer NMR images without complex magnetic field control.

Description

Process for creating nuclear magnetic resonance images

The invention relates to a method for creating nuclear magnetic resonance images according to the preamble of claim 1. Such a method is described for example in "Journal of Physics E: Scientific Instruments" 1976, Vol. 9, pages 271-278.

According to the above procedure, a level is defined resonantly excited nuclei in an object to be examined (specimen) a two-dimensional Creation of a sectional view. Similar procedures are under the term "nuclear magnetic resonance-zeugmatography" or "spin imaging" is known. The definition of the level of interest is after the reference so achieved that by means of a selective saturation high frequency pulse in a field gradient z perpendicular to this plane, all nuclear spins outside the Level to be saturated.

A field gradient Gx then becomes parallel to the plane of interest applied and with the help of a selective 90 ° high frequency pulse a strip of Nuclear spins excited0 The resulting nuclear magnetic resonance signal is finally read out in a gradient Gy (perpendicular to Gz and Gx). This procedure has the disadvantage that very high radio frequency power is required to achieve selective saturation to reach. Furthermore, it appears to be very difficult experimentally to identify the undesired To completely saturate nuclear spins outside the plane of interest. One remaining However, magnetization significantly reduces the image quality that can be achieved.

The invention is based on the object with the aid of a method according to the preamble of claim 1 one or several lines at the same time to scan an object to be examined completely without undesired spins having to satiate. This object is achieved according to the invention by the in the characterizing Part of this claim resolved specified measures. Appropriate configurations of the invention are the subject of the subclaims.

In contrast to the known line scanning method, in the present Invention, the area to be imaged is defined by selective 1800 pulses and instead of the free induction decay analyzes the spin echoes following the 1800 pulse. As a special embodiment of the invention, it is possible not to have the excitation on a Line, but to stimulate several lines of the object at the same time and read out.

Further details and advantages of the invention are provided below explained on the basis of the exemplary embodiments shown in the figures.

In Fig. 1 is an apparatus for excitation, recording and further processing represented by nuclear magnetic resonance signals, in Fig. 2 in a diagram a plot of the switching sequence to be used, in FIG. 3 that of the switching sequence according to FIG. 2 selected line in the body to be examined, in FIG. 4 a full line Switching sequence for the rapid scanning of several lines and in FIGS. 5a to 5d shows an example of the excitation scheme for the simultaneous measurement of four lines.

In Fig. 1, 1 and 1 'are the field coils of a magnet in a Helmholtz arrangement which generates the required homogeneous basic field in which the sample is to be examined is introduced. Gradient coils are designated with 2 and 3 for generating independent, mutually perpendicular magnetic field gradients. Another set of gradient coils is generated a field gradient perpendicular to that caused by 2 and 3 and is in not shown for the sake of clarity.

Electronics known per se are located in a housing 4 for the periodic switching of the field gradients according to the one described below Switching sequence.

With 5 electronics is referred to for generating selective high-frequency pulses. These have adjustable frequency, bandwidth and amplitude within certain limits, which, together with the magnetic field gradients, allow certain areas to selectively stimulate the object to be examined. The high frequency impulses are fed to the transmitting and receiving coil 6, both of which are used to excite the Nuclear spins generated high-frequency field, as well as for recording the nuclear magnetic resonance signal serves. The housing 7 contains a nuclear magnetic resonance receiver and a phase sensitive one Demodulator, so that at the output 8 the phase-correct rectified nuclear magnetic resonance signal is present.

To examine one or more lines of the sample, first a plane containing the line is selectively excited. With simultaneous examination multiple lines become multiple parallel planes of the sample containing these lines selectively stimulated. The resulting signal is then acted upon by a selective 180 ° pulse reduced to a plane perpendicular to the planes described. For this purpose, a suitable one, i.e. in comparison to the inhomogeneity of the basic field, will be sufficient large field gradient applied. As a rule, it should be caused by the gradient Line broadening at least 1 order of magnitude greater than that caused by the basic field inhomogeneity caused lying. This causes refocusing after a defined delay time the magnetization only within the desired plane.

The basic pulse sequence is shown in Figure 2; in the first Line the selective excitation pulses 10, 11, in the second the nuclear magnetic resonance signals 15, 16 and in the third the field gradients 12, 13, 14. With 10 the first is selective 900 excitation pulse and 11 the following selective 1800 pulse. By 12, 13 and 14 is the order in which the gradients Gx, Gz u.id are switched Gy indicated. The delay times t1 from the end of the 90 ° pulse to the beginning of the 1800 pulse and t2 from the end of the 180 ° pulse to at the beginning of the reading out of the nuclear magnetic resonance signal are of the same size, provided that the 18O0 pulse has a temporally symmetrical amplitude curve. A useful value for the time t1 or t2 should be with regard to the relaxation times in the specimen be sufficiently short, e.g. 1 msec for biological bodies.

In Fig. 3 is the scanning of a line 19 in a sample body 17 drawn. This is done by successively limiting the excitation to two mutually perpendicular planes 18 and 18 '. So effectively a line 19 of the to be examined body 17 are evaluated.

In detail, the sample is first in the field gradient designated by 12 Gx subjected to a selective 90 ° excitation pulse 10. This high frequency pulse causes a rotation of the spins within an area of width d x at the point x0 by an angle 0, generally 900 Impulse it is also possible to use several planes perpendicular at this point instead of one to stimulate to the x-direction at the same time. As is possible in this case, the signals To separate the different excited levels again will be shown in the following will.

Immediately after the end of the first high-frequency pulse 10 is the gradient is switched in the z-direction and the magnetization can during the time t1 decay freely in this gradient. The then created selective Pulse 11 rotates the spins within a slice of thickness iX z by 1800. This causes a selective refocusing of the spins within this slice and an echo signal at time t2 after the end of the RF pulse. At time t2 the echo maximum becomes the gradient in the y-direction switched and the resulting Read out nuclear magnetic resonance signal. The Fourier transform of this signal then gives the spin density along the line a x, z in the body 17.

Immediately after the pulse sequence described, the spins are within of the plane A z are inverted, but show the full range outside the area A x longitudinal magnetization. Therefore a second pulse train of the same type can be started immediately can be applied to lower the spins along a line elsewhere x 'below -0 Looking for. The observed signal is in this case as a result of the first pulse sequence however, be inverted.

In this way, a series of lines can be read out successively without the return of the spin system into thermal equilibrium must be waited for.

If the refocusing pulse 11 does not cause a rotation of the relevant Spins around exactly 1800, so after a few excitation sequences a cumulative one Build up errors in longitudinal magnetization. However, this effect can easily be prevented by inverting the sign of each pulse 11 with respect to the previous one will. In the same way, you also invert the 90 ° pulse that initiates the sequence 10, the sign reversal described above also disappears in the nuclear magnetic resonance signal for every other sequence. Such a complete excitation sequence is shown in FIG shown. The sign reversal of every second excitation pulse is here as a phase shift described around 1800.

Instead of the successive excitation of parallel lines, the to be examined Object also has several lines at the same promptly stimulated and observed will. The pulse sequence to be switched for this differs from the previous one described only by the shape of the selective 90 ° excitation pulse 10. Instead a single selective pulse becomes a multispFk tral high frequency pulse is used whose Fourier transform contains just as many components as parallel lines in the object are to be excited. In the following the example shown by four simultaneously excited lines how it is possible to superimpose them Assign signals of all excited spins back to individual lines in the object.

In Figs. 5a to 5d is an excitation sequence for four with I to IV marked lines drawn (cf.

also the matrix (2)). The position of the vertical bars above or below the abscissa symbolizes the sign of the excitation of the corresponding Line. A reversal of the sign of the excitation pulse for a spectral component just causes an inversion of the corresponding magnetization and thus a Inversion of the resulting nuclear magnetic resonance signal.

Now, SI to SIv denotes the values obtained when each individual line was excited Nuclear magnetic resonance signals and 5a to 5d are those obtained for an excitation according to FIGS. 5a to 5d The following applies to sum signals: Sa + Sb + Sc + Sd = 4SI Sa - Sb + Sc + Sd = 4SII (1) S + Sb - 5c + Sd SIII Sa + Sb + Sc - Sd = 4SIV By applying the described excitation sequence (cf.

5) the signals of the four lines are obtained in four measurements with a signal-to-noise ratio corresponding to an averaging over four measurement cycles. Upon suggestion however, one line in each case according to the well-known method is the same to win Information with the same signal-to-noise ratio means that 16 single measurements are carried out necessary with a correspondingly increased expenditure of time.

Leave the corresponding excitation sequences and decoding algorithms specify themselves for any number N simultaneously excited lines. The procedure works most effective when N is a power of 2, so that N measurement cycles are necessary to Obtain N lines with a signal-to-noise ratio corresponding to an N-cache averaging.

To generalize the method to larger numbers N, it is useful to the excitation sequence from FIG. 5 and the described evaluation method (1) in matrix form to represent: I II III IV a -1 1 1 1 b 1 -1 1 1 (2) c 1 1 -1 1 d 1 1 1 -1 The lines the matrix describe the excitation spectra of measurements a to d, while the Columns symbolize the evaluation scheme for maintaining lines I to IV.

A negative sign means inverse excitation of the corresponding Line or, in the evaluation, the subtraction of the respective data record. To e.g. To get the nuclear magnetic resonance signal for line I, the data sentences a, b, c, d can be added up with the signs -1, +1, +1, +1.

To expand the scheme to a larger number of simultaneously excited lines, a larger matrix (3) can be composed of sub-matrices (2), whereby one quadrant is inverted to ensure that two lines with an index difference of four can be distinguished. The following scheme results for eight lines: I II III IV V VI VII VIII a -1 1 1 1 -1 1 1 1 b 1 -1 1 1 1 -1 1 1 c 1 1 -1 1 1 1 -1 1 d 1 1 1 -1 1 1 1 -1 e -1 1 1 1 1 -1 -1 -1 f 1 -1 1 1 -1 1 -1 -1 g 1 1 -1 1 -1 -1 1 -1 h 1 1 1 -1 -1 -1 -1 1 The present invention enables the investigation of the spin density within a plane of an extended specimen. Furthermore, several lines can be scanned at the same time within the selected plane. A combination of these techniques using the rapid measurement sequence described is an effective method for imaging spin density using the principle of selective excitation.

Claims (4)

Method for creating nuclear magnetic resonance images of a two-dimensional section (layer (18)) through extensive specimens under Use of linear scanning of the body with measured values after excitation by high-frequency pulses during the course of a field gradient switching sequence can be obtained, that is, the spatial selection of the scanned line (19) in at least one dimension by the application of a selective, i.e. based on its frequency spectrum and the applied field gradient (13) takes place in the spatial area of the cut (18) effective, 180 ° pulse. 2. The method according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the selection of the desired line (19) of the body (17) in one dimension by applying a selective 900 pulse and through in the second dimension the selective 180 ° pulse is applied. 3. The method according to claim 1 or 2, since dur c h g e k e n n z e i c h n e t that the measured values used to create the image at the time one by simultaneously applying a field gradient (13) and one selective 1800 impulses caused spin echoes are read out. 4. The method of claim 1, 2 or 3, d a d u r c h g e k e n n notices that in the body to be examined (17) several volume areas (layers 18 ') are excited at the same time and the superimposed signals are read out, whereby guaranteed by an excitation sequence (a-d, FIG. 5) in a sequence of several measuring cycles is, that the measured values obtained are again assigned to individual volume areas.