RU187202U1 - Phantom device for controlling the parameters of diffusion-weighted images of magnetic resonance imaging - Google Patents

Abstract

The device relates to the field of medical technology, namely to means for monitoring the quality parameters of images in magnetic resonance imaging and calibration tests. A phantom is known from the prior art (patent US 9603546 B2, Phantom for Diffusion MRI imaging) for calibrating diffusion modes of magnetic resonance imaging (MRI) by measuring the diffusion coefficient of control substances — a homogeneous solution in an arbitrary shape container. The disadvantages of this technical solution is that this homogeneous solution simulates the hindered diffusion of water molecules that can move unlimitedly over the volume of the tank. Closest to the claimed technical solution is a phantom (Boss MA, et al. QIBA PDF MRI Technical Committee: Activities in Diffusion MRI. Poster 2014) for monitoring the measured diffusion coefficient (ICD). This device is a spherical body with containers for control substances placed in the frame. The phantom design allows you to set the range of ICD by filling the containers with solutions with different polymer concentrations - polyvinylpyrrolidone. However, the use of a solution, as for the aforementioned analogue, makes it possible to simulate difficult self-diffusion of water molecules by increasing the viscosity of the solution, which does not accurately simulate diffusion in a human cell. Thus, the main disadvantage of the presented technical solutions is the use of a solution as a control substance. The inventive device allows to solve the technical problem of creating a phantom device devoid of the above disadvantages, namely, providing control of the parameters of diffusion-weighted images (DWI) of magnetic resonance imaging when using containers filled with substances with predetermined ICD, allowing to conduct, control and evaluate the accuracy measuring this parameter. The technical result consists in the creation of a device for controlling the parameters of DWI in magnetic resonance imaging, containing control substances with given ICD values in a wider range than that provided by known analogues.

Description

The device relates to the field of medical technology, namely to means for monitoring the quality parameters of images in magnetic resonance imaging and calibration tests.

A phantom is known from the prior art (patent US 9603546 B2, Phantom for Diffusion MRI imaging) for calibrating diffusion modes of magnetic resonance imaging (MRI) by measuring the diffusion coefficient of control substances — a homogeneous solution in an arbitrary shape container. This solution is a mixture of low molecular weight and high molecular weight polymers of various concentrations and has the diffusion of water molecules characteristic of living tissues. The disadvantages of this technical solution is that the polymer solution simulates the hindered diffusion of water molecules that can move unlimitedly over the volume of the tank. A decrease in the diffusion coefficient is determined by an increase in the viscosity of the solution. This effect does not sufficiently accurately model diffusion in normal or pathological tissues of the human body, where the self-diffusion of water molecules is difficult (due to the presence of organic micro- and nanoblocks) and limited (using lipid membranes). In addition, the implementation of this device does not present the possibility of using the on / off function of fat suppression, as well as measuring the chemical shift due to the presence of adipose tissue.

Also known is a phantom device according to patent US 20160363644, Phantom for quantitative diffusion magnetic resonance imaging, which is a housing filled with a solution, where the solvent has a diffusion coefficient greater than the diffusion coefficient of water, and the dissolved substance due to interaction with the solvent reduces diffusion. The authors state that the substances are selected in such a way that there is one peak in the spectrum of the nuclear magnetic resonance (NMR) of the solvent, and no peak is observed in the NMR spectrum of the dissolved substance. Thus, one peak will be observed in the NMR spectrum of the solution, which will not allow the study of the chemical shift due to the presence of adipose tissue and fat suppression technology. In addition, the disadvantage of this device is that to simulate diffusion corresponding to the physiological range, it is necessary to immerse the phantom in water with ice, which complicates the process of its use.

Closest to the claimed technical solution is a phantom (Boss MA, et al. QIBA PDF MRI Technical Committee: Activities in Diffusion MRI. Poster 2014) for monitoring the measured diffusion coefficient (ICD). This device is a spherical body with containers for control substances placed in the frame. The phantom design allows you to set the range of ICD by filling the containers with solutions with different polymer concentrations - polyvinylpyrrolidone. However, the use of a solution, as for the aforementioned analogue, makes it possible to simulate difficult self-diffusion of water molecules by increasing the viscosity of the solution, which does not accurately simulate diffusion in a human cell. In addition, the phantom device uses ice water to further reduce diffusion.

Thus, the main disadvantage of the presented technical solutions is the use of a solution as a control substance. In this case, the model of self-diffusion of water molecules is difficult, because the movement of water molecules is unlimited in volume, but the diffusion coefficient decreases due to an increase in viscosity. This is not an accurate model of self-diffusion of water molecules in human cells, because in living tissue, the self-diffusion of water molecules is difficult (due to the presence of organic micro and nanoblocks) and limited (with the help of lipid membranes). Thus, to simulate living tissue from the point of view of indicators of diffusion of water molecules, it is possible to simulate both limited and difficult self-diffusion of water molecules.

To obtain the lower boundary of the ICD, ice is used in the analogues, with the help of which the temperature of the samples is reduced, and, consequently, the ICD is reduced. In our technological solution, the minimum ICD is achieved under normal conditions, namely, at standard temperature in the treatment room (scan room) of the MRI room.

The inventive device allows to solve the technical problem of creating a phantom device devoid of the above disadvantages, namely, providing control of the parameters of diffusion-weighted images (DWI) of magnetic resonance imaging when using containers filled with substances with specified ICD, allowing monitoring and accuracy assessment measuring this parameter, including in the case of applying fat reduction technologies, as well as measuring the amount of chemical shift due to the presence of Irova tissues and act as a reference signal during extracorporeal patient scanning.

The technical result consists in the creation of a device for monitoring the parameters of DWI in magnetic resonance imaging, containing control substances with given ICD values in a wider range than that provided by known analogues, namely: ICD covers the range from values corresponding to normal tissue to values characterizing benign or malignant pathologies. In addition, the presence of reverse emulsions based on organosilicon compounds makes it possible to simulate the lower limit of the ICD range by simulating the limited diffusion of water molecules, as well as to measure the chemical shift and control the effectiveness of the fat suppression function, due to the presence of control substances on the spectrum of nuclear magnetic resonance (NMR) peaks from adipose tissue (-CH ₃ / -CH ₂ ) and from water (-OH).

The inventive phantom device consists of a housing of arbitrary shape and one or more containers filled with control substances imitating the diffusion of water molecules in living tissues. Control substances have ICD in the range of values from the corresponding normal tissue to benign and malignant pathologies.

Inverse emulsions based on organosilicon compounds are used to simulate diffusion processes corresponding to the lower boundary of the range of ICD values. Aqueous solutions of polymers with different concentrations - diffusion processes corresponding to the average values of the ICD range. The self-diffusion coefficient corresponding to the upper limit of the range of ICD values is set using water (or water with paramagnetic salts of copper (II) sulfate or manganese (II) chloride dissolved in it). Inverse emulsions in the NMR spectrum have peaks corresponding to adipose tissue (-CH ₃ / -CH ₂ ) and water (-OH), which allows you to control the parameters of DWI with the fat suppression function on / off, as well as measure the chemical shift from adipose tissue. In addition, in comparison with water, the signal intensity from reverse emulsions is higher on DWI in a wide range of b-factor values and significantly lower on ICD cards.

Thus, the claimed device is characterized by the following essential features:

 the presence of a case of arbitrary shape filled with water (or water with paramagnetic salts of copper (II) sulfate or manganese (II) chloride dissolved in it), and one or more containers for control substances

 the presence of control substances with stability properties for the period

tests, with ICD in the range of values from the corresponding normal tissue to the corresponding benign and malignant pathology

the presence of inverse emulsions based on organosilicon compounds simulating diffusion processes that correspond to the lower boundary of the ICD range and having peaks in the NMR spectrum corresponding to adipose tissue (-CH ₃ / -CH ₂ ) and water (-OH), as well as generating higher in comparison with water, the signal on DWI in a wide range of b-factor values and lower on the ICD cards

 the presence of aqueous solutions of polymers with different concentrations for modeling diffusion processes corresponding to the average values of the ICD range

 the presence of water (or water with paramagnetic salts of copper (II) sulfate or manganese (II) chloride dissolved in it) to represent diffusion processes corresponding to the upper limit of the range of ICD values

In FIG. 1 is a diagram of a phantom device for monitoring parameters of a diffusion-weighted MRI, where 1 is a body that is filled with MP - contrast fluid 5; 2 - containers filled with control substances 4; 3 - housing cover or hole for installing containers.

In FIG. 2 shows a diagram of the installation of containers 2 for control substances in the housing 1 by fixing in the frame 6.

Control substances 4 include inverse emulsions, in which the dispersed phase is water, contained as separate droplets (micelles) in an oil-dispersed medium, as shown schematically in FIG. 3. In the inventive phantom device, the oil is an organosilicon compound. The emulsifiers shown in FIG. 3 in the form of round heads with a zigzag tail. Thus, the thermal motion of water molecules is limited by the size of micelles, which makes it possible to simulate the limited diffusion of water in living cells. In addition, inverse emulsions make it possible to simulate the difficult diffusion of organosilicon molecules in a dispersed medium.

The micelle size is determined by the ratio of the dispersed medium and the phase, as well as the content of the emulsifier (or stabilizer). By changing these concentrations, various ICDs can be obtained. The signal intensity at the DVI is determined by several parameters, including the ICD:

where S _b is the signal intensity at the DWI with the b factor b.

Aqueous polymer solutions may contain both high molecular weight and low molecular weight polymers depending on the desired concentration. So, for example, using high molecular weight polymers, it is possible to simulate average ICD values close to the lower boundary of the ICD range. By adding low molecular weight polymers to the solution, simulate the average ICD values. close to the upper limit of the range of ICD (patent US 9603546 B2, Phantom for Diffusion MRI imaging).

In a preferred embodiment of the inventive device, the following control substances are used: water (or water with paramagnetic salts of copper (II) sulfate or manganese (II) chloride dissolved in it) to simulate the upper limit of the ICD range, an aqueous solution of polyvinylpyrrolidia PVP with concentrations of 10, 20 , 30, 40 and 50% by weight - to cover the average values of the ICD range, as well as inverse emulsions for modeling the lower boundary of the ICD range. In FIG. 4 shows the dependence of the signal for these control substances relative to the b-factor. This graph shows that in a wide range of b-factor values, the signal intensity from inverse emulsions is higher than from water and aqueous PVP solutions. The ICD measurement results for these control substances are shown in FIG. 5. As shown in the graph, the modeling of the lower boundary of the ICD range is carried out using inverse emulsions, the average values using aqueous PVP solutions with different concentrations, and the upper boundary using water.

In FIG. Figure 6 shows the NMR spectrum for water (Fig. 6, a), for an organosilicon compound (Fig. 6, b) and for an inverse emulsion based on an organosilicon compound (Fig. 6, c). FIG. 6 shows the presence of two peaks in the NMR spectrum of the inverse emulsion: the corresponding adipose tissue (—CH ₃ / —CH ₂ ) and water (—OH).

In one of the embodiments of the phantom for controlling the parameters of the DWI, the containers for control substances are fixed in the housing by means of support plates. The list of control substances includes, but is not limited to: reverse emulsions based on organosilicon compounds, water, water with paramagnetic salts, polymer solutions with various concentrations.

To control the parameters of the DVI, it is possible to use the following methodology: before scanning, you should install a radio frequency coil (RF coil) on the deck of the patient table and provide its electrical power. An embodiment of the phantom described in the previous paragraph is placed inside the RF coil and centered relative to it. Next, the scanning procedure is started using pulse sequences for the DWI using at least two b-factors, and axial images of the phantom shown in FIG. 7. In FIG. 7a, an example of a diffusion-weighted image recorded with a b factor of 0 s / mm ² is presented. In FIG. 7, 6 - an example of DWI with a b-factor of 1500 s / mm ² . Using the software, the signal intensity of the control substances, as well as the ICD cards calculated by the MRI apparatus, is estimated by measuring the values inside the areas of interest marked by ellipses in FIG. 7. The accuracy of determining the ICD by the MRI apparatus is assessed by comparing the control substances with the specified ICD values.

The following technique can be used to control the parameters of DWI when scanning a patient: during laying, a phantom should be placed along the patient’s body, the containers of which are long sealed tubes with a diameter of up to 5 cm and a length of more than 1 m filled with inverse emulsions. Next, it is necessary to scan the patient in the DVI mode in a regulated manner. It is possible to evaluate the operation of the DVI mode by comparing the patient's signal intensity in the field of pathological formations with a signal from inverse emulsions. Thus, the inventive phantom device acts as an extracorporeal signal.

Inverse emulsions based on organosilicon compounds have peaks in the NMR spectrum. corresponding adipose tissue (—CH ₃ / —CH ₂ ) and water (—OH) (FIG. 5). The presence of a difference between the peaks of the NMR spectrum of adipose tissue and water leads to the fact that the spins of fat and water located in the same bill process at different speeds, and, therefore, are located on the image with an offset relative to each other. The chemical shift in the NMR spectrum is expressed in relative magnitude - millionth of a fraction (ppm). Due to the presence of this effect, when registering DWI, fat suppression technologies are often used to increase the diagnostic value of images. Since inverse emulsions based on organosilicon compounds have two peaks in the NMR spectrum, the bias of the adipose tissue signal relative to the water signal will be displayed on the DWI. When using reverse emulsion as a control substance, it is possible to measure the chemical shift due to the presence of adipose tissue, as well as evaluate the effectiveness of the function of fat suppression.

умножают на ширину полосы пропускания (BW) и делят на размер матрицы (число строк или столбцов, Matrix) в зависимости от направления сдвига. Величина ƒ имеет размерность частоты, Гц.Thus, the inventive device is used to measure the chemical shift, as well as to evaluate the performance of the fat suppression function, namely, DVI is obtained by scanning the phantom and image processing. To measure the chemical shift due to the presence of adipose tissue in the image, it is necessary to measure in pixels the deviation of the center of the signal of the inverse emulsion from the center of the true position of the capacitance of this inverse emulsion. Given value

multiply by the bandwidth (BW) and divide by the size of the matrix (the number of rows or columns, Matrix) depending on the direction of the shift. The value ƒ has the dimension of frequency, Hz.

To bring the chemical shift ƒ to a relative value (dimension in ppm), it is necessary to divide by the operating frequency of a particular tomograph.

To control the technology of fat suppression, it is necessary to carry out scans with the function of fat suppression turned on and off, subject to the remaining identical conditions.

It is also possible to implement the inventive device in which inserts and test objects are additionally placed in the housing to control other parameters and characteristics of a magnetic resonance imager. At the same time, containers for control substances are located in compartments. This allows you to combine the control procedures for the parameters of the DVI and the main operational parameters and characteristics of the magnetic resonance imager.

Although the real utility model is described by the example of specific options for its implementation, the specialists will be clear on the possibilities of numerous modifications of the invention, not going beyond the scope of its legal protection, as defined by the attached formula.

Claims (5)

1. The phantom device for controlling the parameters of diffusion-weighted images of magnetic resonance imaging, containing a housing, containers for control substances, characterized in that the control substances have a diffusion coefficient in the range of values from the corresponding normal tissue to the corresponding pathology, have stability for the period of testing and include reverse emulsions based on organosilicon compounds with peaks in the nuclear magnetic resonance spectrum corresponding to adipose tissue and water and aqueous solutions of polyvinylpyrrolidone with concentrations of 10, 20, 30, 40 and 50% by weight and water with paramagnetic salts dissolved in it, and inverse emulsions are used to simulate diffusion processes corresponding to the lower boundary of the range of values of the measured diffusion coefficient, and aqueous solutions of polyvinylpyrrolidone are used to simulate diffusion processes corresponding to the average values of this range. 2. The phantom device according to claim 1, characterized in that the body shape is parallelepiped-shaped, and the containers for control substances are fixed with support plates. 3. The phantom device according to claim 1, characterized in that the body shape is in the form of a cylinder, and the containers for control substances are fixed with support plates. 4. The phantom device according to claim 1, characterized in that the containers for control substances are long sealed tubes with a diameter of up to 5 cm and a length of more than 1 m. 5. The phantom device according to claim 1, characterized in that the housing has a cylindrical shape.

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