RU2308025C1 - Method of spatial visualization of nonmetallic objects - Google Patents

Abstract

FIELD: investigating or analyzing materials.

SUBSTANCE: method comprises exciting signals of nuclear magnetic resonance, plotting 3D-image of the object to be studied with the use of a hydrogen-containing agent provided with resonance magnetic nucleuses, and visualizing the surface of the object be means of recording the signals from the nucleuses by nuclear magnetic resonance method.

EFFECT: expanded functional capabilities.

3 cl, 4 dwg

Description

The invention relates to the field of research of various properties of materials using magnetic resonance imaging (MRI) by volumetric visualization of the surface structure (both external and internal) of various non-metallic objects and products, including household products, art objects, archaeological and paleontological materials, and for non-destructive testing and volume modeling of various products.

Visualization of the external surface structure of many objects is usually not a problem - just make the right number of photos of the subject with different angles. To visualize the structure of the inner surface by optical methods, the not always overcome problem of placement of the emitter and receiver is able to capture the signal reflected from the inner surface. In some cases, the structure of this surface can be determined by measuring the degree of absorption of x-rays by the object at different angles of the object.

If the material that the object under study consists of contains hydrogen and, therefore, protons that have a magnetic moment, then nuclear magnetic resonance (NMR) methods can be used to study it, where the resonant interaction of magnetic momentous atomic nuclei recorded in a constant magnetic field with a radio frequency (RF) field. Using inhomogeneous magnetic fields, you can set the spatial coding of resonance NMR frequencies and obtain magnetic (3D) image of the object using magnetic resonance imaging methods. This non-invasive, safe and highly informative method has been successfully used in medicine and biology for anatomical and functional studies [see Anisimov N.V., Pirogov Yu.A., Gubsky L.V., Gladun V.V. Contrast control and information technology in magnetic resonance imaging / Ed. Pirogova Yu.A. - M .: Faculty of Physics, Moscow State University M.V. Lomonosova, 2005]

The closest technical solution adopted by us for the prototype is the method of volumetric visualization of non-metallic objects by MRI, used in the study of lungs (see MSAlbert, GDCates, B. Driehuys, W. Happer, B. Saam, CSSpringer Jr., A.Wishnia " Biological magnetic resonance imaging using laser-polarized ¹²⁹ Xe. "Nature 370: 199-201 (1994), or modern reviews: http://www.mmrrcc.upenn.edu/research/hyper.html, same, materials in Russian language - http://uc.jinr.ru/libraryplis.htm), according to which a 3D image of the object under study is constructed using a substance containing resonating magnetic nuclei, according to which the visa they lyse the surface of the test object by recording signals from these nuclei by MRI, while a highly polarized inert gas (helium or xenon, specially prepared in advance), introduced in a low concentration (safe for the patient), is used as the substance mentioned.

Modern MRI scanners are mainly focused on the registration of signals from protons. But there are objects for which 3D reconstruction with the help of proton MRI is impossible in their initial state due to the absence of hydrogen in their chemical structure. These are various objects and products from glass and ceramics, bone and stone. Of great interest is the volumetric visualization of the internal structure of these objects, especially for objects of art, archaeological and paleontological materials.

The basis of the invention is the task of such an improvement in the method of volumetric visualization of nonmetallic objects by MRI, in which the technological capabilities of the method are expanded by providing the possibility of volumetric visualization of nonmetallic objects in the absence of hydrogen in their chemical structure, as well as if the NMR signal from protons present in the studied object too small due to their low content or the object under study has a rigid structure for which the registration of the NMR signal, including prot nny, it is difficult because of too fast attenuation of the signal due to the very short time the nuclear magnetic relaxation, it being possible to obtain high quality three-dimensional images that show the structure of both external and internal surfaces of the article.

To solve this problem, in the method of volumetric visualization of non-metallic objects by magnetic resonance imaging (MRI), according to which a 3D image of the object under study is constructed using a substance containing resonant magnetic nuclei in contact with the object under study and the surface of the object under study is visualized by recording signals from of these nuclei by MRI, according to the invention, as a substance containing resonating magnetic nuclei, a substance containing hydrogen is used, pr and the substance containing hydrogen is used in liquid form, and as the substance containing hydrogen, according to the first embodiment of the method, an oily liquid or an oily emulsion is used, while it is applied uniformly with a thin layer on the surface of the test object, according to the second embodiment, as the substance containing hydrogen, use water, or alcohol, or liquid oil, while the test object is immersed in this substance.

A causal relationship between the features of the proposed combination and the achieved technical results from its use is as follows.

Due to the fact that a substance containing hydrogen in contact with the object under study is used as a substance containing resonating magnetic nuclei, the 3D image of this substance will be a kind of cast of the object under study. As a result, objects of 3D-visualization with the MRI image of the structure of both the external and internal surfaces of the product can be not only objects containing water or hydrogen, which means protons, but also objects that do not contain protons at all - glass, ceramic, stones bones or, due to the solid state structure of the object under study, having proton relaxation time too short - polymers, plastics. The essence of the invention boils down to the fact that instead of registering an MR signal from the object being studied, inaccessible for direct registration by MRI due to the lack of hydrogen, to register an MR signal from a contrast medium in contact with this object. Due to the uniform distribution on the surface of the object of a contrast medium with a high content of hydrogen (protons) and having a liquid structure, and therefore giving a powerful MR signal, it is possible to obtain high-quality volume MR images that reflect the structure of both the external and internal surfaces of the object under study, the structure which may be the most diverse.

A good adaptation of MRI for 3D imaging is a consequence of the fact that the magnetic and RF fields freely penetrate the structure of the object under study, if it is not metallic. The method is an addition to radiation research methods based on the reflection of the probe beam (optical and microwave lasers), as well as on the attenuation of the penetrating beam (X-ray method).

The presented graphic materials show images obtained as a result of tomographic studies using the known and proposed methods of volumetric visualization of non-metallic objects by MRI.

Figure 1 shows examples of volumetric imaging in known diagnostic MRI studies of objects containing hydrogen: A - vessels of the brain, B - structures of the inner ear, C - neuroma of the spinal canal, D - external anatomical structures of the head.

Figure 2 presents examples of volumetric visualization - 3D reconstructions obtained from objects made of materials that do not contain hydrogen (these are ordinary household items: glassware and a ceramic teapot). This figure shows the original MR images (upper row) and 3D reconstruction (lower row).

Figure 3 - three-dimensional images reproducing objects (on the left is a glass bottle, on the right is a ceramic teapot) with cut off parts, which allows you to visualize the inner surface of the object.

Figure 4 shows a 3D visualization of the figurine.

To obtain the initial MR images, scanning was used with a digital resolution of 1 × 1 × 1 mm, the scanning time was not more than 20 minutes. Small artifacts near the area of the drawing on the teapot are associated with the presence of metallic components in the paint, causing distortion of the RF field. Image quality - signal-to-noise ratio, spatial resolution - can be improved by increasing the signal accumulation time. If for living objects this time has to be limited, then for non-living objects the duration of the study can be set arbitrarily long.

The method of volumetric visualization of non-metallic objects by MRI was carried out on a Tomikon S50 MRI scanner (Bruker). 3D processing was carried out using ParaVision ^™ (v.1.0 (IRIX 5.3) and ImageJ 1.34s (MS Windows XP) programs. A 3D image of the object under study was constructed using a substance containing resonant magnetic nuclei that was brought into contact with the object under study and on which the surface of the object under study was visualized by registering signals from these nuclei by MRI, a substance containing hydrogen was used as a substance containing resonating magnetic nuclei, in the first example vaseline, which was applied uniformly with a thin layer on p the surface of the studied object. On fragments A and B (see figure 2) you can see the signal of vaseline smeared on the surface of the studied object. For 3D reconstruction, the MIP transformation is applied, in which the glass surface is reproduced better than for 3D rendering. the second example on fragments C and D shows the presence of the investigated object immersed in water, which is detected by the loss of the signal in the MR image.

On separate slices, the MR image of the object according to the first example is represented by thin bright lines displaying the localization of vaseline deposited on the surface of an invisible object for NMR - Fig.2A, B. The information obtained is sufficient to carry out segmentation and, ultimately, volume reconstruction of the object, after which it can be presented at any viewing angle, with different options for shading the surface, animation effects, etc.

When implementing the second option (example 2), information about an object invisible for NMR is presented on an MRI image as sections of a low signal (dark areas) against a strong water signal (light areas) - figs. 2C, D. For 3D reconstruction using the standard algorithm only needs to perform an inverse transformation of the brightness scale on an MRI image.

Due to simple manipulations with MRI data, it is possible to construct arbitrary sections of the reconstructed object, which allows you to examine the object as if from the inside and visualize the internal surface of the object - Fig.3. In order to obtain volumetric images with internal “cutouts” or “cut off” at a certain angle, before starting the volume reconstruction algorithm, it is necessary to pre-process the initial (2D) images obtained from the MR scan of the object under study. Processing is reduced to the corresponding "cropping" of the source image using a conventional graphics editor. The described manipulations (graphic processing and 3D reconstruction) can be implemented not only with the help of software that is supplied by the tomography manufacturers, but also with the help of freely available programs - for example, ImageJ (http: //rsb.info.nih .gov / ij /).

Due to the use of the proposed method, objects of 3D visualization using the proton MRI method can be objects that contain, but cannot be detected by conventional MRI methods due to too short proton relaxation time - for example, polymer, plastic products that do not contain hydrogen at all. It is only necessary that they do not contain metal, because the latter distort the RF field and, accordingly, the MRI image itself, did not deteriorate from applying a hydrogen-containing emulsion to their surface or from immersion in a contrasting hydrogen-containing liquid, and also had dimensions acceptable for the tomograph. It is possible that the most popular objects of 3D visualization will be art objects, archaeological and paleontological materials, copies of designed products, etc.

Claims (1)

The method of volumetric visualization of non-metallic objects by magnetic resonance imaging (MRI), according to which the signals of nuclear magnetic resonance (NMR) are excited and a 3D image of the object under study is constructed using a hydrogen-containing substance containing resonant magnetic nuclei, by which the surface of the object under study is visualized by registration of signals from these nuclei by the MRI method, characterized in that the NMR signals are excited in a hydrogen-containing another product that is placed on the surface of the rendered object.

Images