DE10360677B4 - Arrangement and method for reducing motion artifacts in nuclear magnetic resonance measurements - Google Patents

Abstract

Arrangement for reducing and / or correcting motion artifacts in spatially resolved nuclear magnetic resonance measurements, comprising
- A nuclear magnetic resonance apparatus (110) for spatially resolved nuclear magnetic resonance measurement with a portion (112) for receiving a measurement object (114);
- A marker system (138) which can emit at least one divergent electromagnetic beam and / or by reflection of electromagnetic radiation and which can be firmly connected to the measuring object (114);
- At least two spatially separated detector fields (128, 130), wherein the same diverging beam reaches a plurality of detector fields;
- at least one imaging system (124, 126) for imaging the electromagnetic radiation beam emanating from the marker system (138) onto the detector fields (128, 130);
- a position determining device (144) for calculating a position and / or orientation of the marker system (138) from signals of the detector fields (128, 130);
- A motion detecting device (146) for detecting a movement of the measurement object (114) from the position and / or orientation of the marker system (138); and
A correction device (146) for generating a ...

Description

The The invention relates to a method and an arrangement for correction of motion artifacts in spatially resolved nuclear magnetic resonance measurements. such spatially resolved Nuclear magnetic resonance measurements are used in particular for non-invasive measurements structure elucidation in the field of materials testing and medical technology. An important example is magnetic resonance imaging (MRT).

A Movement of the object to be measured can be done with spatially resolved nuclear magnetic resonance measurements lead to significant image quality issues. This is due to that usually individual pixels or image areas of the to be measured Objects are measured successively, so for example by a sequential scan of individual lines or planes of the object. After taking the picture then usually the picture information the lines or layers in the computer to a three-dimensional image composed. But are the lines or planes due to a Movement of the object to be measured strongly shifted against each other or tilted, the so-called motion artefacts arise in the reconstructed image, so blurring or in reality nonexistent structures ("ghosts"). In the spatial frequency space corresponds to the one unwanted change of amount and phase.

The spatially resolved Nuclear magnetic resonance measurement thus basically requires that that too measuring object during the implementation of the Scans in the volume area to be measured not significantly moved. In many cases However, this requirement is not met, as inevitably measurements be performed on moving objects have to.

in the In the field of pharmacology, for example, it is in many cases of Interest, the spread of certain well-visible on MRI drugs in the body of a test animal time-resolved to determine. So far, the experimental animals often become so for this purpose stunned, that their movements are severely limited.

In of human diagnostics, where MRI scans sometimes take up to several hours can take however, this approach is impractical. Especially in uncooperative patients, such as children or the elderly, therefore, recordings often disturbed by spontaneous movements and must be repeated. Furthermore, such measurements can only be hard to interrupt and then continue, but what for longer Measurements in practice would be desirable.

in the Area of material testing It may be interesting to move through nuclear magnetic resonance measurements on For example, examine objects for material fatigue. This is so far only for slow movements with small amplitude of movement possible.

Various methods have hitherto been used to prevent or correct motion artifacts. One method, which is used in several variations, is the so-called navigator method, which is known from the publications US 4,937,526 . US 5,539,312 and US 2003/0153826 A1 is known. In these procedures, a navigator measurement is inserted at regular intervals between the scans. In this navigator measurement, the position of the object to be measured and the displacement or rotation of the object in comparison to the previous navigator measurement is determined by means of various reference measurements. These reference measurements can be made in different directions in the space of the wave vectors (k-space). Following the measurement, the data collected during the measurement is computationally corrected using the information from the navigator measurements. In this case, the data of each scan (for example, the data of an image plane) by means of a coordinate transformation according to the movements that the object has performed during the measurement, moved in space and tilted.

The Navigator methods have various disadvantages. A major disadvantage is that the reference measurements time consuming and therefore significantly increase the duration of the entire measurement. You can also use Help this method only relatively small movements of the object later Getting corrected.

One known method, by means of which movements of the object already while The measurement can be detected and corrected in US 2002/0118373 A1 described. In this method, which is used in particular for functional MR tomography becomes, becomes the principle of laser triangulation applied. Three laser diodes emit light beams on each a retro-reflector from which the rays parallel to each incident beam back reflected and detected at or near the laser diodes become. The reflected laser beams are detected using a Line scan detected. Movements of the object can be through detect and correct this method in real time.

However, this method also has various disadvantages. So is example se the conversion of the calculated from the detector signals of the triangulation system movement of the object in the absolute coordinate system of the MR tomograph consuming since the exact position of the triangulation system is insufficiently known. Furthermore, the tolerance range for movements of the object is limited by the size of the retro-reflectors. There is also the risk that the retro-reflectors fastened to the object, for example the head of a patient, slip or change their positions relative to the body volume, for example due to movements of the scalp.

task the invention is to provide a method and an arrangement, which is a reliable one Reduction or correction of motion artifacts in spatially resolved nuclear magnetic resonance measurements allows. The procedure is intended to keep track of the absolute position of the object in the coordinate system of the nuclear magnetic resonance apparatus in real time. In particular, the invention is intended to enable high-resolution MR image data of motion-critical Objects (eg a head of a living vertebrate or human) to obtain.

These The object is achieved by an arrangement having the features of the claim 1 and by a method according to claim 10 solved.

It is an arrangement and method for reduction or correction of motion artifacts in spatially resolved nuclear magnetic resonance measurements proposed. The arrangement has a nuclear magnetic resonance apparatus for spatially resolved nuclear magnetic resonance measurement with an area for receiving a measured object (sample space). at This nuclear magnetic resonance apparatus may, for example, order to act an MR tomograph, as used in medical technology becomes. However, it may also be nuclear magnetic resonance apparatus, which especially for Material investigations are designed.

By the nuclear magnetic resonance apparatus, the measurement can be spatially resolved. There are various possibilities for this. In commercially available MR tomographs for example simultaneously receive signals from different locations of the measurement object which are frequency-coded due to a gradient of the magnetic field are. That way For example, the measurement object is "scan" line by line or plane by plane.

But Other types of spatial resolution are possible. Thus, for example, the measurement volume itself by suitable shaping of the magnetic field coils to a few cubic microns or cubic millimeters be limited. To get information from different places within of the object to be measured, the measurement object is determined by means of a Positioning device suitably moved or rotated. such Devices can especially for material investigations be used.

With The measuring object is connected to a marker system, which at least emit a divergent electromagnetic beam or through Can generate reflection of incident electromagnetic radiation. Marker system is understood to mean at least one marker and fastening means, z. As a mechanical holder, via the marker system can be attached to the measurement object. Also, the marker, for example, by Gluing be fixed. Typically, it is the electromagnetic Rays around light of one or more wavelengths from infrared to the ultraviolet spectral range. It is an advantage if one high percentage of the emitted or reflected radiation flux density of the beam in a narrow wavelength range is (eg 90% within a wavelength range between 810 nm and 830 nm). Preferably, therefore, in the case of reflection, light a defined wavelength irradiated in the direction of the marker system. The reflected or emitted beams is divergent, d. H. the beam reaches at the same time a plurality of detector arrays spaced from each other are.

at The marker system can be a system that has its own Light sources (for example, battery-powered light-emitting diodes or phosphorescent or chemiluminescent substances). On the other hand can it is also a marker system, which radiated from the outside can reflect electromagnetic radiation.

Farther the arrangement has at least two spatially separated detector fields and one or more imaging systems. By means of these detector fields should it be possible in combination with the imaging systems an information about to generate the position and / or orientation of the marker system. For example, these detector fields and the imaging Systems act around cameras, which pictures at regular or irregular intervals from the sample room. The emitted by the marker system or reflected light should be detectable on these images, so that, for example with the aid of image processing software, the position of the marker system can be determined. This can be, for example be done by the marker systems as bright spots on the Images appear whose focus is determined automatically can be.

Farther The detector fields may also be other types of detectors act, for example, line scan cameras.

To the method described In each detector field, position information about the Create marker system. The spatial Separation of the detector fields causes at least two different Position information to be generated. From the positions of the detector systems and the position information about leaves the marker system themselves by means of a triangulation method known per se close the position of the marker system. This calculation is done in the proposed arrangement by means of a position-determining device, for example, an image processing system running on a personal computer.

Should in addition to the position of the object to be measured also an information about a spatial Orientation can be obtained, for example, the marker system several spatially have separate regions (markers), which are electromagnetic radiation reflect or emit. These spatially separated areas should also be perceived spatially separated from the detector fields be, for example in the form of spatially separated light spots in the picture of a camera. By means of the position-determining device then the positions of the separate areas of the marker system determined separately. Depending on the number of these areas can not now only the position of the marker system, but also its spatial Alignment can be determined. As a rule, marker systems are used three spatially separated Areas used to determine the position and orientation of the measurement object to be determined in all spatial directions.

These Determination of position and / or orientation may be during and / or between sequences of nuclear magnetic resonance measurement to different Times occur, which is determined by means of a motion detection device (For example, a personal computer) a movement of the measurement object can detect. Is determined in this way that the measurement object since the last position or orientation determination has moved (Translation and / or rotation), so by means of a correction device a Correction signal are generated, which is a mode of operation of the nuclear magnetic resonance apparatus changes accordingly. This correction device, for example one or the staff Computer, may be configured, suitable motion correction signals to generate the magnetic field in the nuclear magnetic resonance apparatus (eg by adjusting one or more magnetic field gradients) to change. The next Scan is then z. B. at a new location, for example in a plane or along a line, which corresponds to the movement the measured object is adjusted. Al ternativ can in nuclear magnetic resonance apparatus with positioning device (see above) also the position of Sample can be adjusted accordingly, for example by translation or Rotation.

The arrangement described has the advantage that movements of the measurement object in real time or approximately in real time, d. H. already during the measurement, can be detected so that immediately appropriate measures (correction of the measuring method or correction of the position of the measurement object) can be taken. Also can the corrective actions between two or more measurements.

For example can the for a complete Investigation required information in multiple sequences the nuclear magnetic resonance measurement are recorded. During one Sequence, between two sequences and / or after a few sequences a motion correction can be performed. The real one Measurement does not have to be interrupted for this purpose. A subsequent correction the data obtained is i. d. R. no longer required. she can However, in turn, which in turn obtained during the measurement information about the movement of the object to be measured can be used.

When it has proven particularly advantageous if the marker system has reflective properties. The marker system can do this at least have a marker, which is designed, electromagnetic Reflect rays. Reflecting is analogously also a Scattering of the incident electromagnetic radiation to understand.

Farther the arrangement can additionally one Having a source capable of emitting an electromagnetic beam, such that the marker system detects this beam becomes. In particular, the source is designed so that the entire Area in which the marker system can move, is illuminated.

These Further education offers the advantage that the marker system itself does not Source of electromagnetic radiation (eg a light source), whereby the marker system can be designed technically simple. A battery or similar energy source not necessary.

It Arrangements can be electromagnetic with one or more sources Use rays. This can be, for example, a or act on several infrared lamps.

The or the electromagnetic radiation beams emitted by the source of the (preferred non-planar) surfaces of the marker system is reflected such that the reflected electromagnetic ray beam in turn are divergent, eliminating these from multiple detector fields can be recorded at the same time. A precise alignment of the detector fields and the imaging Systems on the DUT is not required.

When very cheap it has been proven, if the marker system in addition to the nuclear magnetic resonance apparatus can be detected, d. H. if the position and / or orientation of the marker system the coordinate system of the nuclear magnetic resonance apparatus by one or several nuclear magnetic resonance measurements can be determined. To this Way lets by one or more reference measurements (for example Beginning of or before a nuclear magnetic resonance measurement) a correlation between the positional information of the detector fields and the coordinate system the nuclear magnetic resonance apparatus produce. The position information the detector fields can so at any time by a simple coordinate transformation be converted into coordinates of the nuclear magnetic resonance apparatus. This facilitates the correction of motion artifacts (both online and later) significantly.

Especially is proposed in addition - by a spatially resolving Nuclear magnetic resonance measurement - the absolute position and / or orientation of the marker system in the coordinate system to determine the nuclear magnetic resonance apparatus. For example, you can this way the origins and / or Alignments of the coordinate systems of the marker system and the nuclear magnetic resonance apparatus before starting a measurement of an object or subject in accordance to be brought. For example, the coordinate system of the marker system becomes adapted to the coordinate system of the nuclear magnetic resonance apparatus. By producing a fixed, known relationship of the coordinate systems of the marker system and the nuclear magnetic resonance apparatus is in each Case possible (and this is suggested) for a following measurement with the nuclear magnetic resonance apparatus a transformation rule (eg a transformation matrix), with which one in the Coordinate system of the marker system (i.e. a movement of the object or subject) into a movement correction to be performed is transformed in the coordinate system of the nuclear magnetic resonance apparatus.

Especially in the case of this transformation, it is preferable to use one for determination the measurement information provided in the nuclear magnetic resonance apparatus Measuring device (eg a system of readout coils for reading the measurement information generate a magnetic gradient field) to drive in such a way that a measuring field generated by the measuring device (in particular the magnetic gradient field) before and after the movement to be corrected the same position and / or orientation relative to the coordinate system of the marker system (and thus relative to the object or subject) Has.

Around the coordinate systems of the marker system and the nuclear magnetic resonance apparatus in a defined relationship to each other is preferably the marker system "visible" for the nuclear magnetic resonance apparatus made. Again, it makes sense to have separate areas (Marker) of the marker system in the nuclear magnetic resonance apparatus can be made visible. That way not only a position of the marker system, but also a spatial Alignment of the marker system in the coordinate system of the nuclear magnetic resonance apparatus determine.

The Markersystem can for example be designed so that certain Areas of the marker system are made of a material, which in the nuclear magnetic resonance apparatus with a high contrast can be made visible. In particular, this may be a proton-rich material (for example, a hydrocarbon with a high density of hydrogen atoms or water).

By the arrangement described allows movement artifacts to be largely but i. d. R. not complete, eliminate. Remaining blurs in the image information obtained by nuclear magnetic resonance tomography are common due to the fact that the detector fields (for example cameras) have image noise, or that vibration is the quality of the position information influence negatively.

These remaining blurs or movement artefacts can be additionally reduced by further training, wherein a reference marker system is fixed to the nuclear magnetic resonance apparatus is connected. The reference marker system is designed in this way be that in turn emit at least one electromagnetic beam or reflect, wherein the reference marker system is more advantageous Way similar or structurally identical as the marker system. The reference marker system should be arranged such that the position of the reference marker system can be determined by means of the detector fields.

Furthermore, the arrangement may include a noise correction device (for example, an image processing system used by a personal computer executed), which should correct or reduce apparent variations in the detected position and / or orientation of the marker system connected to the measurement object, which are not caused by the movement of the measurement object itself. This correction can be effected by determining the position and / or orientation of the reference marker system at the same time or in a timely manner for determining the position and / or orientation of the marker system. Since the reference marker system does not change its position and orientation in the coordinate system of the nuclear magnetic resonance apparatus as a rule, detected fluctuations in the position and / or orientation of the reference marker system can nevertheless be classified as unwanted noise or vibrations which simultaneously also affect the determined positions and / or orientations of the marker system are superimposed. By simply differentiating between the positions of the reference marker system and the positions of the marker system, such artifacts can be eliminated almost completely, thereby significantly increasing the image quality.

A Another advantageous embodiment of the invention relates to the design a marker, in particular a marker for the marker system described above. This marker system can in particular one or more hollow body with a cavity for use as a marker. The hollow body is configured such that it at least one surrounding the cavity, having electromagnetic radiation reflective material. In which Markers may be, for example, a hollow sphere (eg with centered cavity) act.

The reflecting the cavity surrounding electromagnetic radiation Material does not have to form the wall of the cavity. Rather, it can between the reflective material and the cavity also be arranged further material. In particular, it is possible that only the surface of the hollow body the radiation reflects.

The reflective material is intended to reflect reflective properties for the irradiated have electromagnetic radiation. Is particularly advantageous it, when it comes to infrared radiation and for example the surface of the hollow body in this wavelength range (for example at 820 nm) has a high reflectivity.

Farther the cavity of the hollow body is preferably filled with a material, which is detectable by a nuclear magnetic resonance measurement. As described above, it may be, for example, a hydrocarbon act with high proton density and / or water, which is to increase the proton density was doped. Alternatively or additionally, however also other liquids can be used, which are detectable in the MR tomograph.

The Attachment of the marker system to the measurement object is often a problem Considerable technical problem. Especially with spatially resolved nuclear magnetic resonance measurements to vertebrates or humans, this attachment must be done that also involves a shift of the skin relative to the muscle tissue or Skeleton does not affect the position determination negatively.

there it has been especially in investigations of the head as special Advantageously, when the marker system for placement mouthpiece decorated inside the mouth and one outside of the mouth to be placed fastening device, wherein the fastening device and the mouthpiece firmly connected are. At the attachment device of the marker system can at least a marker (for example, a marker in one of those described above Embodiments), the at least one electromagnetic Emit radiation bundles or can reflect. It may be, for example, a Arrangement of three of the above-described hollow bodies act. These hollow bodies are intended be arranged on the fastening device that they spaced apart from each other. That way they can get off the detector fields spatial are sufficiently separated and their positions are therefore easily determinable. In particular, the hollow bodies should not be in be arranged in a line, so that the orientation of the marker system can be determined in all three spatial directions.

The Attachment in the mouth of the vertebrate or patient ensured a good fixation of the marker system relative to the skull bone and brain, which is particularly beneficial when shooting in the head area is. In vertebrates and non-cooperative patients (eg elderly patients or children) In addition, the mouthpiece to be placed inside the mouth can still be added be attached by means of a negative pressure on the palate or jaw. With this painless fixation can be the durability further improve the positioning of the marker system.

One Computer program may expire on a computer or computer network those parts of the process according to the invention in one of its Execute embodiments wholly or partially, the one control involved devices and / or processing of the obtained Concern information.

Furthermore, a computer program may include program code means to those parts the method according to the invention, which relate to a control of the devices involved and / or a processing of the information obtained to perform in whole or in part, when the program is executed on a computer or computer network. In particular, the program code means may be stored on a computer-readable medium.

On a disk may be stored a data structure after loading in a working and / or main memory of a computer or computer network those parts of the method according to the invention, the one driving involved devices and / or processing of the obtained Information can affect, in whole or in part.

One Computer program product may be particularly on a machine-readable carrier stored program code means to those parts of the method according to the invention, the a control of the devices involved and / or processing The information received shall be in whole or in part if: the program runs on a computer or computer network.

there Under a computer program product, the program is considered tradable Product understood. It can basically be in any form so for example on paper or a computer-readable disk and can in particular over a data transmission network be distributed.

in the The invention will be explained in more detail below with reference to exemplary embodiments which are shown schematically in the figures. However, the invention is not limited to the examples. The same reference numerals in the individual figures indicate same or functionally identical or with regard to their functions corresponding elements. In detail shows:

1 a plan view of an arrangement for correcting motion artifacts of nuclear magnetic resonance measurements by means of a camera system, a lighting system and an image processing and a marker system;

2 a top view to one 1 alternative arrangement with a single diffuse light source;

3 a hollow body having a curved, reflective surface and a filling of a visible material in the nuclear magnetic resonance measurement as a marker;

4 a fixable by means of a vacuum device marker system with a mouthpiece; and

5 a flowchart of an embodiment of the method according to the invention.

1 shows a preferred embodiment of an arrangement for reducing motion artifacts. A nuclear magnetic resonance apparatus 110 for spatially resolved nuclear magnetic resonance measurements has a sample space 112 for taking a measurement object 114 (schematically shown as head in this case). As a nuclear magnetic resonance apparatus in this case, a Siemens Magnetom 3T Whole Body System of the manufacturer Siemens Medical Systems GmbH is used.

The nuclear magnetic resonance apparatus is connected to a control electronics 116 which is a central control unit 118 , a measurement data acquisition system 120 and a measurement positioning device 122 having.

Two with suitable infrared lenses 124 . 126 equipped digital camera systems 128 . 130 and two diffuse infrared light sources 132 . 134 are on a positioning rail 136 fixed. The positioning rail is installed at a distance of 4 meters from the center of the magnetic field coils, where only a magnetic field of 10 mT can be observed. This measure is necessary so that the magnetic forces on components of the camera systems do not lead to damage or misalignment of the arrangement. Shielded cables are used to reduce negative effects of the magnetic fields on the data signals of the camera systems.

At the measuring object 114 is a marker system 138 fixed, wherein the marker system three provided with an infrared-reflective surface markers 140 having. The camera systems 128 . 130 and the light sources 132 . 134 are aligned so that the markers 140 in the field of view of the camera systems 128 . 130 and in the light cone of the light sources 132 . 134 are located.

The camera systems 128 . 130 are connected to a personal computer 142 which is an image processing system 144 and a central processing unit 146 having. The personal computer 142 is with the control electronics 116 connected.

During Nuclear Magnetic Resonance (for example, after each image plane is taken in MRI or at certain intervals during image plane acquisition), the position of the markers becomes 140 with the help of image processing processing system 144 certainly. This is done with the help of the lenses 124 . 126 that of the diffuse infrared light sources 132 . 134 emitted and from the markers 140 reflected light on the CCD chips of digital camera systems 128 . 130 projected. The image processing system 144 thus registers the markers 140 as bright spots in the image area and can change the position of the markers 140 for example, by determining the center of gravity of the bright spots in the respective coordinate system of the camera systems 128 . 130 determine. Thus, the spatial direction is known under which each marker 140 from every camera system 128 . 130 looks from.

For the determination of the absolute position of the markers 140 In the room now a conventional triangulation method is used. Starting from every camera system 128 . 130 a virtual straight line is drawn in the direction in which the marker appears from the respective camera system. The position of the marker 140 results from the intersection of this line and from the known position of the camera systems 128 . 130 , When the position and the angular position of the cameras 128 . 130 is not exactly known, the position determination can also by means of a reference measurement on a (in 1 not shown) reference marker system are calibrated.

If in this way the positions of all three markers 140 of the marker system 138 have been determined is the position and orientation of the measurement object 114 sufficiently determined for that time. To the accuracy of measuring the position and orientation of the marker system 138 can further increase, one with the nuclear magnetic resonance apparatus 110 firmly connected reference marker system 148 be used. By comparing the measured position and orientation of the marker system 138 with the measured position and orientation of the reference marker system 148 let artifacts that are not caused by movements of the measurement object 114 arise (but by noise, vibration, etc.) Avoid or reduce.

If the positions and orientations of the marker system 140 between two measurements (for example, before and after the MR scan of a plane of the measurement object 114 ), this can easily be determined by means of the arrangement described. Accordingly, appropriate corrective action will be taken. This is done by the central processing unit 146 the change in the position and orientation of the measurement object 114 in suitable correction signals for the control electronics 116 the nuclear magnetic resonance apparatus 110 converts and transfers to them.

The central control unit 118 the control electronics 116 Corrects accordingly the control of the measuring positioning device 122 , For example, by changing the parameters of the control of the coil currents of the magnetic field coils. The next MR scan of a plane of the measurement object 114 is then done with the corrected controls so that the movement of the measurement object 114 has been compensated. The spatial resolution can be improved by this method to up to 0.1 mm.

Analogous The correction may also already be made during an MR scan what the accuracy of the measurements and the reduction of Motion artifacts further improved.

In 2 is a variation of in 1 illustrated construction shown. In this construction, only a diffused infrared light source is used 132 used, which is in the middle between the two camera systems 128 . 130 on the positioning rail 136 is arranged. In this way, the arrangement can be made more compact than the in 1 illustrated arrangement.

In 3 is a marker 140 represented according to a preferred construction. The marker has a spherical hollow body 310 with a cavity 311 which is made of plastic (in this case polyethylene). The surface 312 of the hollow body 310 is formed by an outer layer (in particular a lacquer layer) which has a high reflection in the infrared spectral range.

The hollow body has a filling opening 314 on which in the operation of the marker with a plastic stopper 316 is sealed liquid-tight. The plastic plug can, as in 3 is shown, also for the connection of the hollow body 310 with a fastening device 410 be used. The cavity 311 of the hollow body 310 is with water 318 high proton density filled.

In 4 is shown as the in 3 pictured markers 140 to a marker system 138 can be connected. Three markers 140 are about their plastic plugs 316 with a cruciform fastening device 410 connected. The fastening device 410 is with a mouthpiece 412 connected. The mouthpiece has a series of suction openings 414 on, which via a vacuum line 416 with a vacuum pump 418 are connected.

The marker system 138 is fixed by the fact that the patient the mouthpiece 412 takes in the mouth, where it is using the suction holes 414 sucked by vacuum on the palate and so fixed.

In 5 a preferred embodiment of the method for the correction or reduction of motion artifacts is shown as a flow chart. In the first step 510 a positioning of the measurement object takes place 114 Thus, for example, a positioning of a patient on a spatially adjustable couch or the positioning of a test setup with moving parts to be examined within the sample space 112 the nuclear magnetic resonance apparatus 110 ,

In step 512 becomes a marker system 138 firmly with the measurement object 114 connected. It should be a marker system 138 act which marker 140 which can be visualized by means of nuclear magnetic resonance measurements. In the next step 514 therefore, the position and orientation of the marker system 138 in the coordinate system of the nuclear magnetic resonance apparatus 110 be determined by a spatially resolved nuclear magnetic resonance measurement.

Subsequently, in step 516 the position and orientation of the marker system 138 by means of the in 1 described optical system in the coordinate system of the cameras 128 . 130 certainly. In step 517 is determined by the position and orientation of the marker system 138 in the coordinate system of the MR tomograph and in the coordinate system of the optical system 128 . 130 calculates the transformation matrix, which transforms the two coordinate systems into each other.

In step 518 then the spatially resolved nuclear magnetic resonance measurement is started, in this case by starting the first MR scan in step 520 ,

After completion of the MR scan of the first image plane is then in step 522 the position and orientation of the marker system again 138 performed in the optical system. At the same time (step 524 ) a measurement of the position and orientation of the reference marker system 148 carried out. As described above, this information is used to suppress artefacts due to noise or vibration.

Out of the ones in step 522 and 524 gained information about the position and orientation of the measurement object 114 will be in step 526 determines a possible movement of the measurement object and accordingly calculates a correction signal for the positioning of the next scan. This correction signal is then, as described above, in the control electronics 116 the nuclear magnetic resonance apparatus 110 converted into a correction of the location resolution.

This procedure, including the correction of the spatial resolution, is repeated a total of N times, where N represents the number of image planes. After measuring the N. image plane is in step 530 the tomography is finished and the data processing started.

110

Magnetic resonance apparatus

112

sample space

114

measurement object

116

control electronics

118

central control unit

120

Measurement data acquisition system

122

Measurement positioning device

124

lens

126

lens

128

digital camera system

130

digital camera system

132

diffuse infrared light source

134

diffuse infrared light source

136

positioning rail

138

marker system

140

marker

142

staff computer

144

Image processing system

146

central computer unit

148

Reference marker system

310

hollow body

311

cavity

312

Surface of the hollow body 310

314

filling

316

Plastic plugs

318

water filling

410

fastening device

412

mouthpiece

414

suction

416

vacuum line

418

vacuum pump

510

positioning of the measured object

512

fixation of the marker system

514

determination the position and orientation of the marker system in the MR tomograph

516

determination the position and orientation of the marker system in the optical system

517

calculation the transformation matrix

518

begin the MR measurement

520

MR scan the i. image plane

522

determination the position and orientation of the marker system in the optical system

524

determination the position and orientation of the reference marker system in the optical system and noise reduction

526

detection the measurement object movement and generation of a correction signal

528

correction the location resolution

530

termination the measurements and the beginning of the data processing

Claims (13)

Arrangement for reducing and / or correcting motion artifacts in spatially resolved nuclear magnetic resonance measurements, comprising: - a nuclear magnetic resonance apparatus ( 110 ) for spatially resolved nuclear magnetic resonance measurement with a range ( 112 ) for receiving a measured object ( 114 ); A marker system ( 138 ), which can emit at least one divergent electromagnetic beam and / or can generate by reflection of electromagnetic radiation and which firmly with the measured object ( 114 ) can be connected; At least two spatially separated detector fields ( 128 . 130 ), wherein the same divergent beam reaches a plurality of the detector fields; - at least one imaging system ( 124 . 126 ) for mapping the marker system (s) ( 138 ) outgoing electromagnetic radiation beams on the detector fields ( 128 . 130 ); A position determining device ( 144 ) for calculating a position and / or orientation of the marker system ( 138 ) from signals from the detector fields ( 128 . 130 ); A motion detection device ( 146 ) for determining a movement of the measurement object ( 114 ) from the position and / or orientation of the marker system ( 138 ); and a correction device ( 146 ) for generating a motion correction signal for driving the nuclear magnetic resonance apparatus ( 110 ). Arrangement according to the preceding claim, characterized in that - the marker system ( 138 ) at least one marker ( 140 ), which can reflect electromagnetic radiation; and - that the arrangement additionally contains a source ( 132 . 134 ), which is suitable for emitting an electromagnetic radiation beam, such that the marker system ( 138 ) is detected by this beam. Arrangement according to one of the preceding claims, characterized in that the marker system ( 138 ) and the nuclear magnetic resonance apparatus ( 110 ) are designed such that the position and / or orientation of the marker system ( 138 ) additionally from the nuclear magnetic resonance apparatus ( 110 ) can be detected. Arrangement according to one of the preceding claims, characterized in that the arrangement additionally comprises: - a reference marker system ( 148 ) which can emit and / or reflect at least one electromagnetic radiation beam and which is firmly fixed to the nuclear magnetic resonance apparatus ( 110 ) connected is; and - a noise correction device ( 144 ) for the correction and / or reduction of not by the movement of the measurement object ( 114 ) caused apparent fluctuations in the position and / or orientation of the object to be measured ( 114 ) associated marker system ( 138 ). Arrangement according to one of the preceding claims, characterized characterized in that the correction device is designed, To generate motion correction signals that a magnetic field in the nuclear magnetic resonance apparatus change. Arrangement according to one of the preceding claims, - wherein the marker system comprises a hollow body ( 310 ) with a cavity ( 311 ) for use as a marker ( 140 ), wherein the hollow body ( 310 ) at least one cavity ( 311 ) comprises surrounding electromagnetic radiation reflecting material; and - wherein the cavity ( 311 ) of the hollow body ( 310 ) with a material detectable by a nuclear magnetic resonance measurement ( 318 ) is filled. Arrangement according to one of the preceding claims, - wherein the marker system ( 138 ) a mouthpiece designed for placement within the mouth of a vertebrate or human ( 412 ) and an outside of the mouth to be placed fastening device ( 410 ) having; and - wherein at the fastening device ( 410 ) at least one marker ( 140 ), which can emit and / or reflect at least one electromagnetic beam. Arrangement according to the preceding claim, wherein the marker system ( 138 ) as a marker ( 140 ) three hollow bodies ( 310 ) according to claim 6. Arrangement according to one of the two preceding claims, wherein the mouthpiece ( 412 ) can be fixed by means of a negative pressure on the palate or jaw of a vertebrate or human. Method for reducing and / or correcting motion artifacts in spatially resolved nuclear magnetic resonance measurements, characterized in that a. that a marker system ( 138 ), which can emit at least one diverging electromagnetic beam and / or generate electromagnetic radiation by reflection, firmly with a measuring object ( 114 ), so that the same thing diverging from the marker system ( 138 ) emitted or reflected beam reaches a plurality of detector fields, which are arranged spaced from each other; b. that from different perspectives images of the marker system ( 138 ) are recorded; c. that from the images information about a translation and / or rotation of the measurement object ( 114 ) be won; and d. that a motion correction is performed during a nuclear magnetic resonance measurement and / or between nuclear magnetic resonance measurements using the information. Method according to the preceding claim, characterized e. that a divergent electromagnetic beam in the direction of the marker system ( 138 ) is irradiated; and f. that a part of the beam through the marker system ( 138 ) is reflected. Method according to one of the two preceding claims, characterized in that g. that additionally by a spatially resolving nuclear magnetic resonance measurement, the absolute position and / or orientation of the marker system in the coordinate system of the nuclear magnetic resonance apparatus ( 110 ) is determined ( 514 ). Method according to one of the preceding claims, characterized in that h. that in addition information about the position and / or the alignment of a with the nuclear magnetic resonance apparatus ( 110 ) fixed reference marker system ( 148 ) be won; i. that from this information not by the movement of the measurement object ( 114 ) caused apparent fluctuations in the position and / or orientation of the object to be measured ( 114 ) associated marker system ( 138 ) be determined; and J. that the apparent variations in the motion correction are taken into account.