JP6061598B2 - Magnetic resonance equipment - Google Patents

Description

  The present invention relates to a magnetic resonance apparatus that acquires data of a predetermined region of a subject.

  Conventionally, a technique for creating a map of an apparent diffusion coefficient (hereinafter referred to as “ADC”; ADC: apparent diffusion coefficient) is known (see Patent Document 1).

JP 2010-099455 A

One method of creating an ADC map is to execute a T2 scan for collecting T2 weighted image data and a diffusion weighted scan using a motion probing gradient (MPG) for detecting spin motion. is there. In this method, an ADC map is created based on echo signals collected by the T2 scan and echo signals collected by the diffusion weighted scan. However, in this method, when the echo signal of the T2 scan is a high signal, an artifact due to the high signal may appear in the T2-weighted image. In this case, there is a problem that artifacts also appear in the ADC map.
Therefore, it is desirable to reduce the artifacts that appear in the ADC map.

According to a first aspect of the present invention, a scanning unit that executes a plurality of sequences for acquiring data of a predetermined region of a subject, and the predetermined region based on the data obtained by the plurality of sequences. A magnetic resonance apparatus having a map creation means for creating a map of an apparent diffusion coefficient,
A first sequence of the plurality of sequences is
A first pair of gradient magnetic fields for reducing the signal intensity of spins moving within the predetermined region;
A second sequence of the plurality of sequences is
The magnetic resonance apparatus includes a second pair of gradient magnetic fields for detecting a spin motion in the predetermined region.

According to a second aspect of the present invention, the scanning unit is configured to apply a gradient magnetic field in the first direction, the second direction, and the third direction,
The magnetic resonance apparatus according to the first aspect, wherein the first pair of gradient magnetic fields are applied in the first direction, and the second pair of gradient magnetic fields are applied in the second direction.

  A third aspect of the present invention is the magnetic resonance apparatus according to the second aspect, wherein the second sequence includes a third pair of gradient magnetic fields applied in the first direction.

  A fourth aspect of the present invention is the magnetic resonance apparatus according to the third aspect, wherein the third pair of gradient magnetic fields has the same b value as the first pair of gradient magnetic fields.

  According to a fifth aspect of the present invention, there is provided a second sequence in which a third sequence of the plurality of sequences includes a fourth pair of gradient magnetic fields for detecting a spin motion in the predetermined region. A magnetic resonance apparatus according to any one of the fourth aspects.

  A sixth aspect of the present invention is the magnetic resonance apparatus according to the fifth aspect, wherein the fourth pair of gradient magnetic fields are applied in the first direction.

  A seventh aspect of the present invention is the magnetic resonance apparatus according to the sixth aspect, wherein the fourth pair of gradient magnetic fields has a b value larger than the b value of the first pair of gradient magnetic fields. .

  According to an eighth aspect of the present invention, a fourth sequence of the plurality of sequences includes a fifth pair of gradient magnetic fields for detecting a spin motion in the predetermined region. The magnetic resonance apparatus according to any one of the seventh aspects.

  A ninth aspect of the present invention is the magnetic resonance apparatus according to the eighth aspect, wherein the fifth pair of gradient magnetic fields are applied in the third direction.

  A tenth aspect of the present invention is the magnetic resonance apparatus according to the ninth aspect, wherein the fourth sequence includes a sixth pair of gradient magnetic fields applied in the first direction.

  An eleventh aspect of the present invention is the magnetic resonance apparatus according to the tenth aspect, wherein the sixth pair of gradient magnetic fields has the same b value as the first pair of gradient magnetic fields.

A twelfth aspect of the present invention is configured such that the scanning unit can apply a gradient magnetic field in the first direction, the second direction, and the third direction,
The first pair of gradient magnetic fields are applied in the first direction, the second pair of gradient magnetic fields are also applied in the first direction,
The magnetic resonance apparatus according to the first aspect, wherein the second pair of gradient magnetic fields has a b value larger than a b value of the first pair of gradient magnetic fields.

  Since the first sequence includes a first pair of gradient magnetic fields for reducing the signal intensity of the spin moving in the predetermined region, artifacts generated in the apparent diffusion coefficient map can be reduced.

1 is a schematic view of a magnetic resonance apparatus according to a first embodiment of the present invention. It is a figure which shows an example of the normal scan generally performed in order to produce an ADC map. It is a figure which shows an example of the sequence B0 performed by scan SC0 of this form. It is a figure which shows an example of sequence B1-B3 performed by scan SC1-SC3 of this form. It is explanatory drawing when an ADC map is acquired by performing sequence B0-B3. It is a figure which shows an example of a sequence when reducing the signal strength of the spin from which the position of a y-axis direction changes. It is a figure which shows an example of the sequence which applies a pair of gradient magnetic field for reducing the signal strength of a spin to 2 axes | shafts. It is a figure which shows the ADC map of a phantom solution.

  Hereinafter, although the form for inventing is demonstrated, this invention is not limited to the following forms.

(1) First Embodiment FIG. 1 is a schematic view of a magnetic resonance apparatus according to a first embodiment of the present invention.
A magnetic resonance apparatus (hereinafter referred to as “MR apparatus”, MR: Magnetic Resonance) 100 includes a magnet 2, a table 3, a receiving coil 4, and the like.

  The magnet 2 includes a bore 21 in which the subject 11 is accommodated, a superconducting coil 22, a gradient coil 23, and an RF coil 24. The superconducting coil 22 applies a static magnetic field, the gradient coil 23 applies a gradient magnetic field, and the RF coil 24 transmits an RF pulse. In place of the superconducting coil 22, a permanent magnet may be used.

  The table 3 has a cradle 3 a that supports the subject 11. The cradle 3a is configured to be able to move into the bore 21. The subject 11 is transported to the bore 21 by the cradle 3a.

  The receiving coil 4 is attached to the head of the subject 11. The receiving coil 4 receives a magnetic resonance signal from the subject 11.

  The MR apparatus 100 further includes a transmitter 5, a gradient magnetic field power source 6, a receiver 7, a control unit 8, an operation unit 9, a display unit 10, and the like.

  The transmitter 5 supplies current to the RF coil 24, and the gradient magnetic field power supply 6 supplies current to the gradient coil 23.

  The receiver 7 performs signal processing such as detection on the signal received from the receiving coil 4.

  A combination of the magnet 2, the receiving coil 4, the transmitter 5, the gradient magnetic field power source 6, and the receiver 7 corresponds to the scanning means.

  The control unit 8 includes an ADC map creating unit 81 and the like. The ADC map creating means 81 creates an ADC map based on data acquired by scans SC0 to SC3 (see FIG. 4) described later. In addition, the control unit 8 transmits necessary information to the display unit 10 and reconstructs an image based on data received from the receiver 7 so as to realize various operations of the MR apparatus 100. The operation of each part of the apparatus 100 is controlled.

The operation unit 9 is operated by an operator and inputs various information to the control unit 8. The display unit 10 displays various information.
The MR apparatus 100 is configured as described above.

  In this embodiment, the subject is scanned, and an ADC map is created based on data collected by the scan. Hereinafter, a scan executed in this embodiment for creating an ADC map will be described. In the description of the scan executed in this embodiment, for convenience of explanation, the normal scan generally executed for creating the ADC map is described first, and after the normal scan is described, A scan executed in the form will be described.

FIG. 2 is a diagram illustrating an example of a normal scan that is generally performed to create an ADC map.
FIG. 2 shows scans SC0 to SC3. In the scan SC0, an EPI (Echo Planar Imaging) sequence A0 for acquiring T2-weighted image data is executed. In the scans SC1 to SC3, EPI-DWI (Diffusion Weight Imaging) sequences A1 to A3 for acquiring diffusion weighted image data are executed.

  In the sequence A0, a pair of gradient magnetic fields for detecting the spin motion is not applied, but in the sequences A1, A2, and A3, a pair of gradient magnetic fields MPGx for detecting the spin motion, respectively. MPGy and MPGz are applied.

Next, the amplitude of a pair of gradient magnetic fields in sequences A0 to A3 will be described. When the amplitude of the pair of gradient magnetic fields in the sequence A0 is “G0” and the amplitude of the pair of gradient magnetic fields in the sequences A1, A2, and A3 is “G1”, “G2”, and “G3”, respectively, G0, G1, G2 and G3 can be defined by the following equations.
Gn = (Gx, Gy, Gz) (1)
Where n = 0, 1, 2, 3
Gx: amplitude of a pair of gradient magnetic fields applied in the x-axis direction
Gy: amplitude of a pair of gradient magnetic fields applied in the y-axis direction
Gz: amplitude of a pair of gradient magnetic fields applied in the z-axis direction

  Hereinafter, the amplitude of a pair of gradient magnetic fields of the sequences A0, A1, A2, and A3 will be described using Equation (1).

(1) Amplitude G0 of a pair of gradient magnetic fields in sequence A0 In sequence A0, a pair of gradient magnetic fields are not applied in any of the x-axis direction, the y-axis direction, and the z-axis direction. The amplitude G0 of the pair of gradient magnetic fields can be expressed by the following equation.
G0 = (Gx, Gy, Gz)
= (0,0,0) (2)

(2) About a pair of gradient magnetic fields G1 in sequence A1 In sequence A1, a pair of gradient magnetic fields MPGx is applied in the x-axis direction, although a pair of gradient magnetic fields are not applied in the y-axis direction and the z-axis direction. . Therefore, the amplitude G1 of the pair of gradient magnetic fields MPGx in the sequence A1 can be expressed by the following equation.
G1 = (Gx, Gy, Gz)
= (Gx, 0, 0) (3)

Here, assuming that the b value of the pair of gradient magnetic fields MPGx is b = b0 and the amplitude of the gradient when b = b0 is “1”, Equation (3) can be expressed by the following equation.
G1 = (Gx, 0, 0)
= (1, 0, 0) (4)

(3) About a pair of gradient magnetic fields G2 of sequence A2 In sequence A2, a pair of gradient magnetic fields MPGy is applied in the y-axis direction, although a pair of gradient magnetic fields are not applied in the x-axis direction and z-axis direction. . Therefore, the amplitude G2 of the pair of gradient magnetic fields MPGy in the sequence A2 can be expressed by the following equation.
G2 = (Gx, Gy, Gz)
= (0, Gy, 0) (5)

Here, if the b value of the pair of gradient magnetic fields MPGy is the same b value (b = b0) as the pair of gradient magnetic fields MPGx of the sequence A1, and the amplitude of the gradient when b = b0 is “1”, Formula (5) can be represented by the following formula.
G2 = (0, Gy, 0)
= (0,1,0) (6)

(4) About a pair of gradient magnetic fields G3 in sequence A3 In sequence A3, a pair of gradient magnetic fields MPGz is applied in the z-axis direction, although a pair of gradient magnetic fields are not applied in the x-axis direction and the y-axis direction. . Therefore, the amplitude G3 of the pair of gradient magnetic fields MPGz in the sequence A3 can be expressed by the following equation.
G3 = (Gx, Gy, Gz)
= (0,0, Gz) (7)

Here, the b value of the pair of gradient magnetic fields MPGz is the same b value (b = b0) as the pair of gradient magnetic fields MPGx of the sequence A1, and the amplitude of the gradient when b = b0 is “1”. Formula (7) can be represented by the following formula.
G3 = (0,0, Gz)
= (0,0,1) (8)

In equations (2) to (8), it is assumed that diffusion is isotropic.
By executing the sequence A0, T2 weighted image data D0 is obtained, and by executing the sequences A1 to A3, diffusion weighted image data D1 to D3 are obtained.

  The ADC map MA is created using the T2-weighted image data D0 and the diffusion-weighted image data D1 to D3 obtained in this way.

  However, in FIG. 2, when the echo signal collected by the sequence A0 is a high signal, the artifact p of the T2-weighted image data D0 may be emphasized. Thus, if the artifact p of the T2-weighted image data D0 is emphasized, a conspicuous artifact q appears in the ADC map MA. Therefore, it is desirable to reduce the artifact p of the T2-weighted image data D0 as much as possible. Therefore, in this embodiment, the following scan is executed.

3 and 4 are explanatory diagrams of the scan executed in this embodiment.
First, FIG. 3 will be described.
FIG. 3 is a diagram illustrating an example of the sequence B0 executed in the scan SC0 of the present embodiment.
The sequence B0 is configured by adding a pair of gradient magnetic fields MPG _z0 in the z-axis direction of the sequence A0. The b value of the pair of gradient magnetic fields MPG _z0 is b = Δb. When a pair of gradient magnetic fields MPG _z0 is applied, it is possible to reduce the signal intensity of the spin whose position in the z-axis direction changes among the spins moving in the imaging region. Therefore, comparing the sequence A0 and the sequence B0, the signal intensity of the echo signal can be reduced in the sequence B0 than in the sequence A0. For this reason, the artifact p (refer FIG. 2) which may arise in an image when an echo signal is a high signal can be reduced.

In the present embodiment, by applying a pair of gradient magnetic fields MPG _z0 in the scan SC0, the signal intensity of the spin whose position in the z-axis direction changes among the spins moving in the imaging region is reduced. Therefore, even in the scans SC1 to SC3, the reliability of the ADC map may be lowered unless the signal intensity of the spin whose position in the z-axis direction changes is not reduced. Therefore, in this embodiment, a sequence as shown in FIG. 4 is executed in the scans SC1 to SC3.

FIG. 4 is a diagram illustrating an example of the sequences B1 to B3 executed in the scans SC1 to SC3 of the present embodiment.
The sequence B1 is configured by adding a pair of gradient magnetic fields MPG _z1 in the z-axis direction of the sequence A1. The pair of gradient magnetic fields MPG _z1 of the sequence B1 has the same b value (b = Δb) as the pair of gradient magnetic fields MPG _z0 of the sequence B0.

The sequence B2 is configured by adding a pair of gradient magnetic fields MPG _z2 in the z-axis direction of the sequence A2. The pair of gradient magnetic fields MPG _z2 of the sequence B2 has the same b value (b = Δb) as the pair of gradient magnetic fields MPG _z0 of the sequence B0.

The sequence B3 is configured by applying a pair of gradient magnetic fields MPG _z3 instead of the pair of gradient magnetic fields MPG _z applied in the z-axis direction of the sequence A3. The b value of the pair of gradient magnetic fields MPG _z3 of the sequence B3 is set so as to satisfy the following formula (x).
b = b0 + Δb (x)
Here, b0: b value of a pair of gradient magnetic fields MPG _z of sequence A3
Δb: b value of a pair of gradient magnetic fields MPG _z0 of sequence B0

  Next, the amplitude of a pair of gradient magnetic fields in sequences B0 to B3 will be described. If the amplitude of the pair of gradient magnetic fields of the sequence B0 is “G0” and the amplitude of the pair of gradient magnetic fields of the sequences B1, B2, and B3 is “G1”, “G2”, and “G3”, respectively, G0, G1, G2 and G3 can be defined by the equation (1) shown above. Hereinafter, the amplitude of a pair of gradient magnetic fields of the sequences B0, B1, B2, and B3 will be described using Equation (1). It is assumed that the diffusion is isotropic.

(1) Amplitude G0 of a pair of gradient magnetic fields in sequence B0 In sequence B0, a pair of gradient magnetic fields MPG _z0 is applied in the z-axis direction, although a pair of gradient magnetic fields is not applied in the x-axis direction and the y-axis direction. Has been. Therefore, the amplitude G0 of the pair of gradient magnetic fields in the sequence B0 can be expressed by the following equation.
G0 = (Gx, Gy, Gz)
= (0,0, Gz) (9)

Here, when the amplitude of the gradient when b = b0 is “1”, equation (9) can be expressed by the following equation using b values (b = Δb) of a pair of gradient magnetic fields MPG _z0. it can.
G1 = (0,0, Gz)
= (0,0, (Δb / b0) ^0.5 ) (10)

(2) Amplitude G1 of a pair of gradient magnetic fields in sequence B1 In sequence B1, a pair of gradient magnetic fields MPG _x is applied in the x-axis direction, although a pair of gradient magnetic fields are not applied in the y-axis direction. A pair of gradient magnetic fields MPG _z1 is applied in the z-axis direction. Therefore, the amplitude G1 of the pair of gradient magnetic fields in the sequence B1 can be expressed by the following equation.
G1 = (Gx, Gy, Gz)
= (Gx, 0, Gz) (11)

Here, when the amplitude of the gradient when b = b0 is “1”, equation (11) can be expressed by the following equation using the b value (b = Δb) of the pair of gradient magnetic fields MPG _z1. it can.
G1 = (Gx, 0, Gz)
= (1, 0, (Δb / b0) ^0.5 ) (12)

(3) Amplitude G2 of a pair of gradient magnetic fields in sequence B2 In sequence B2, a pair of gradient magnetic fields MPG _y is applied in the y-axis direction, although a pair of gradient magnetic fields are not applied in the x-axis direction. A pair of gradient magnetic fields MPG _z2 is applied in the z-axis direction. Therefore, the amplitude G2 of the pair of gradient magnetic fields in the sequence B2 can be expressed by the following equation.
G2 = (Gx, Gy, Gz)
= (0, Gy, Gz) (13)

Here, when the amplitude of the gradient when b = b0 is “1”, the equation (13) can be expressed by the following equation using the b value (b = Δb) of the pair of gradient magnetic fields MPG _z2. it can.
G2 = (0, Gy, Gz)
= (0,1, (Δb / b0) ^0.5 ) (14)

(4) Amplitude G3 of a pair of gradient magnetic fields in sequence B3 In sequence B3, a pair of gradient magnetic fields MPG _z3 is applied in the z-axis direction, although a pair of gradient magnetic fields are not applied in the x-axis direction and the y-axis direction. Has been. Therefore, the amplitude G3 of the pair of gradient magnetic fields in the sequence B3 can be expressed by the following equation.
G3 = (Gx, Gy, Gz)
= (0,0, Gz) (15)

Here, when the amplitude of the gradient when b = b0 is “1”, equation (15) can be expressed by the following equation using the b value (b = b0 + Δb) of the pair of gradient magnetic fields MPG _z3. it can.
G3 = (0,0, Gz)
= (0,0, {(b0 + Δb) / b0} ^0.5 ) (16)

  The amplitude of the pair of gradient magnetic fields in the sequences B0, B1, B2, and B3 can be described as described above.

FIG. 5 is an explanatory diagram when the ADC map is acquired by executing the sequences B0 to B3.
Image data D10 is obtained by executing the sequence B0, and image data D11 to D13 are obtained by executing the sequences B1 to B3. The ADC map creating means 81 (see FIG. 1) creates an ADC map MA based on the image data D10 and the image data D11 to D13.

The sequence B0 can reduce the signal intensity of the spin whose position in the z-axis direction changes among the spins moving in the imaging region by the pair of gradient magnetic fields MPG _z0 . Therefore, artifacts that can occur in the image data D10 due to the high echo signal can be reduced.

In addition, since the sequences B1 and B2 each have a pair of gradient magnetic fields MPG _z1 and MPG _z2 , the signal intensity of the spin whose position in the z-axis direction changes can be reduced similarly to the sequence B0. In the sequence B3, the b value of the pair of gradient magnetic fields MPG _z3 is set to b = b0 + Δb in consideration of the b value (b = Δb) of the pair of gradient magnetic fields MPG _z0 of the sequence B0. Therefore, in the sequence B3 as well as the sequence B0, the signal intensity of the spin whose position in the z-axis direction changes can be reduced. As described above, the sequences B1 to B3 can reduce the signal intensity of the spin whose position in the z-axis direction changes among the spins moving in the imaging region, as in the sequence B0. Can be increased.

  In the present embodiment, an ADC map can be created by four scans as in a normal scan. Therefore, a high-quality ADC map can be created without increasing the number of scans.

  Next, the isotropic evaluation of the ADC map obtained by the normal sequences A0 to A3 and the isotropic evaluation of the ADC map obtained by the sequences B0 to B3 of this embodiment were performed. Below, the evaluation results of these isotropic properties will be described.

(1) About Isotropic Evaluation Result of ADC Map Obtained by Normal Sequences A0 to A3 First, the diffusion tensor D is defined by the following 3 × 3 matrix.

The following relationship holds between the signal intensity of the echo signal collected by the normal sequences A0 to A3 and the diffusion tensor D.

Here, S _t2 : Signal strength of the echo signal collected by the sequence A0
S _bx : Signal strength of the echo signal collected by the sequence A1
_Sby : signal strength of echo signal collected _by sequence A2
S _bz : Signal strength of the echo signal collected by the sequence A3
b ₀ : b value of a pair of gradient magnetic fields used in the sequences A1 to A3

The right side of Expression (18) includes only the terms D _xx , D _yy , and D _zz on the diagonal line of the diffusion tensor D. Therefore, it can be seen that the ADC map obtained by the normal sequences A0 to A3 is isotropic.

(2) About the isotropic evaluation result of the ADC map obtained by the sequence B0 to B3 of the present embodiment Between the signal intensity of the echo signal collected by the sequence B0 to B3 of the present embodiment and the diffusion tensor D, The following relationship holds.

Here, S _t2 ′: signal intensity of the echo signal collected by the sequence B0
S _bx : Signal strength of the echo signal collected by the sequence B1
S _by : Signal strength of the echo signal collected _{by the} sequence B2
S _bz : Signal intensity of echo signal collected by sequence B3 b ₀ , Δb: b value of a pair of gradient magnetic fields used in sequences B1 to B3

Since the cross terms D _zx and D _yz are included on the right side of the equation (19), it is not strictly isotropic. However, in the case of Δb << b0, the cross terms D _zx and D _yz can be ignored, so that it can be regarded as approximately isotropic.

In this embodiment, the pair of gradient magnetic fields MPG _z1 and MPG _z2 of the sequences B1 and B2 have the same b value (b = Δb) as the pair of gradient magnetic fields MPG _z0 of the sequence B0. However, as long as artifacts in the ADC map can be reduced, the b values of the pair of gradient magnetic fields MPG _z0 , MPG _z1 , and MPG _z2 may be different.

In this embodiment, the pair of gradient magnetic fields MPG _z3 of the sequence B3 is set to b = b0 + Δb. However, if the artifact of the ADC map can be reduced, the pair of gradient magnetic fields MPG _z3 may be set to a b value different from b = b0 + Δb.

  In this embodiment, scans SC0 to SC3 are executed to create an ADC map. However, only the scan SC0 and the scan SC1 may be executed to create an ADC map, or only the scan SC0 and the scan SC2 may be executed to create an ADC map. Alternatively, only the scan SC0 and the scan SC3 may be executed to create an ADC map.

  In this embodiment, the signal intensity of the spin whose position in the z-axis direction changes among the spins moving in the imaging region is reduced. However, the signal intensity of the spin whose position in the x-axis direction or the y-axis direction among the spins moving in the imaging region may be reduced (see FIG. 6).

  FIG. 6 is a diagram illustrating an example of a sequence for reducing the signal intensity of a spin whose position in the y-axis direction changes.

  In FIG. 6, the following pair of gradient magnetic fields is applied to the sequences B0 to B3.

(1) Sequence B0
x-axis direction: none y-axis direction: a pair of gradient magnetic fields MPG _y0 (b = Δb)
z-axis direction: None

(2) Sequence B1
x-axis direction: a pair of gradient magnetic fields MPG _x (b = b0)
y-axis direction: a pair of gradient magnetic fields MPG _y1 (b = Δb)
z-axis direction: None

(3) Sequence B2
x-axis direction: none y-axis direction: a pair of gradient magnetic fields MPG _y2 (b = b0 + Δb)
z-axis direction: None

(4) Sequence B3
x-axis direction: none y-axis direction: a pair of gradient magnetic fields MPG _y3 (b = Δb)
z-axis direction: a pair of gradient magnetic fields MPG _z (b = b0)

  In the sequence shown in FIG. 6, a pair of gradient magnetic fields are applied in the y-axis direction. Therefore, since the signal intensity of the spin whose position in the y-axis direction changes among the spins moving in the imaging region can be reduced, the artifacts of the ADC map can be reduced. Although not shown, ADC map artifacts may be reduced using a sequence in which a pair of gradient magnetic fields are applied in the x-axis direction.

  In the above example, the pair of gradient magnetic fields for reducing the signal intensity of the spin is applied only in any one of the three axial directions (x-axis direction, y-axis direction, z-axis direction). ing. However, a pair of gradient magnetic fields for reducing the spin signal intensity may be applied in two-axis directions or three-axis directions (see FIG. 7).

  FIG. 7 is a diagram illustrating an example of a sequence in which a pair of gradient magnetic fields for reducing the spin signal intensity is applied to two axes.

  In FIG. 7, the following pair of gradient magnetic fields are applied to the sequences B0 to B3.

(1) Sequence B0
x-axis direction: none y-axis direction: a pair of gradient magnetic fields MPG _y0 (b = Δb _y )
z-axis direction: a pair of gradient magnetic fields MPG _z0 (b = Δb _z )

(2) Sequence B1
x-axis direction: a pair of gradient magnetic fields MPG _x (b = b0)
y-axis direction: a pair of gradient magnetic fields MPG _y1 (b = Δb _y )
z-axis direction: a pair of gradient magnetic fields MPG _z1 (b = Δb _z )

(3) Sequence B2
x-axis direction: none y-axis direction: a pair of gradient magnetic fields MPG _y2 (b = b0 + Δb _y )
z-axis direction: a pair of gradient magnetic fields MPG _z2 (b = Δb _z )

(4) Sequence B3
x-axis direction: none y-axis direction: a pair of gradient magnetic fields MPG _y3 (b = Δb _y )
z-axis direction: a pair of gradient magnetic fields MPG _z3 (b = b0 + Δb _z )

  In the sequence shown in FIG. 7, not only the signal intensity of the spin whose position in the y-axis direction changes, but also the signal intensity of the spin whose position in the z-axis direction changes can be reduced. It becomes possible to do.

  Further, in order to verify that the artifact of the ADC map can be reduced by executing the sequence of this embodiment, a phantom solution showing isotropic diffusion was scanned to create an ADC map of the phantom solution. FIG. 8 shows an ADC map of the phantom solution.

FIG. 8A is a diagram showing an ADC map obtained by a normal sequence, and FIG. 8B is a diagram showing an ADC map obtained by a sequence of this embodiment.
In the ADC map of FIG. 8A, an artifact is seen at the position of the arrow. On the other hand, it can be seen that the artifact is reduced in the ADC map of FIG.

2 Magnet 3 Table 3a Cradle 4 Receiving coil 5 Transmitter 6 Gradient magnetic field power supply 7 Receiver 8 Control unit 9 Operation unit 10 Display unit 11 Subject 21 Bore 22 Superconducting coil 23 Gradient coil 24 RF coil 81 ADC map creation means 100 MR apparatus

Claims (3)

Based on scanning means for executing a plurality of sequences for acquiring data of a predetermined region of the subject and data obtained by the plurality of sequences, a map of an apparent diffusion coefficient of the predetermined region is created A magnetic resonance apparatus having map creating means,
A first sequence of the plurality of sequences is
A first pair of gradient magnetic fields for reducing the signal intensity of spins applied in a first direction and moving within the predetermined region;
A second sequence of the plurality of sequences is
A second pair of gradient magnetic fields applied in the first direction and having the same b value as the first pair of gradient magnetic fields, and applied in a second direction, and the spin movement in the predetermined region third and a pair of gradient magnetic fields, the magnetic resonance apparatus for detecting.   A third sequence of the plurality of sequences is:
  A fourth pair of gradient magnetic fields applied in the first direction and having the same b value as the first pair of gradient magnetic fields, and applied in the third direction to detect spin movement in the predetermined region The magnetic resonance apparatus according to claim 1, further comprising: a fifth pair of gradient magnetic fields.   A fourth sequence of the plurality of sequences is:
  A sixth pair of gradient magnetic fields applied in the first direction for detecting the spin motion in the predetermined region, wherein the b value is larger than the b value of the first pair of gradient magnetic fields; The magnetic resonance apparatus according to claim 1, comprising a sixth pair of gradient magnetic fields.