RU2777255C1 - Method for manufacturing a phantom with vessels for ultrasonic examination - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: invention relates to the field of biomedical simulation, in particular, to manufacture of models for ultrasonic examination of tissues and vessels. Method for manufacturing a phantom for transcranial ultrasonic examination includes manufacture of a vascular bed using 3D printing from water-soluble plastic, part of the vascular bed is coated with a sealing substance, liquid plastisol is poured into the body with the vascular bed secured therein, the hardened plastisol together with the vascular bed is removed from the body and put in water, when the plastic forming the vascular bed is dissolved and a lumen is formed between the vascular walls, a tube for supply and removal of the blood-imitating fluid is connected to the vascular bed, water is supplied through the tubes to wash off and dissolve the remaining water-soluble plastic.

EFFECT: invention can be used in ultrasound imaging laboratories.

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Description

The invention relates to the field of biomedical modeling, in particular to the manufacture of models for ultrasound examination of tissues and blood vessels, and can be used in ultrasound imaging laboratories. Phantoms have well-known characteristics, therefore they can be used to train specialists in the conduct of ultrasound diagnostics of cerebral vessels, echocontrast, equipment testing and the creation of new diagnostic methods and devices.

The prior art method [1], according to which the phantom is created on the basis of angiographic data obtained using medical imaging. According to these data, inner and outer molds are made, the space between which is filled with a substance, for example, liquid polyvinyl alcohol (PVA), which solidifies upon cooling. After the PVA solidifies, the molds are dissolved with the help of xylenes. The disadvantage of this method is the known health hazard to which a person is exposed when working with xylenes [2].

Also known from the prior art is a method for manufacturing a phantom [3], according to which polyvinyl alcohol or gelatin is dissolved in water until a transparent solution is obtained, then a model of the vascular bed is prepared from PLA plastic using the FDM 3D printing method and the model of the vascular bed is filled with a solution of polyvinyl alcohol or gelatin, the solution hardens, after which the model of the vascular bed made of PLA plastic is dissolved in dichloromethane, as a result, a phantom is created containing gaps that simulate the vessels.

The disadvantages of this method include:

- the fragility of the resulting phantom, since the jelly formed from polyvinyl alcohol or gelatin is not stored for a long time;

- a health hazard during the manufacturing process, since a toxic substance is used to dissolve the PLA plastic.

This method is accepted as the closest analogue of the claimed method.

The technical result of the claimed invention is:

- increasing the durability of the resulting phantom;

- reducing the risk to health in the process of manufacturing a phantom;

- taking into account the peculiarities of changes in tissue structures caused by the deposition of microcalcifications.

The basis of the manufacturing process of the phantom is described in the prototype [3] and consists in the fact that the material is taken to obtain an imitation of soft tissues, a model of the vascular bed is made using 3D printing, the model is fixed in the form used to fill the phantom, filled with liquid material, after solidification this material simulates soft tissues.

The essential distinguishing features of the proposed technical solution from the closest analogue are:

- the use of plastisol as a material to simulate soft tissues to ensure the durability of the phantom;

- the use of water-soluble PVA plastic for the manufacture of a model of the vascular bed to reduce health risks during the manufacture of the phantom.

Also, an essential feature is the placement of a tissue model with microcalcifications in the phantom to take into account the peculiarities of changes in tissue structures caused by their deposition.

On FIG. 1 (a-c) shows the drawings of the molds used to make the kidney phantom: a - the upper part of the mold containing the protrusion for pouring and holes for inserting the model of the vascular bed; b - the lower part of the form; c - model of the vascular bed.

On FIG. 2 shows the shapes of vessels with aneurysms printed on a 3D printer from soluble plastic.

On FIG. Figure 3 shows an example of placement of vascular bed models containing aneurysm models in the form used to fill the phantom.

On FIG. 4 shows the appearance of the phantom containing the gaps formed after the dissolution of the models of the vascular bed.

On FIG. 5 is a photograph of a kidney phantom made from plastisol.

On FIG. 6 gives examples of sonograms of areas with models of phantom aneurysms from FIG. 4 in color Doppler blood flow mapping mode.

On FIG. 7 shows a sonogram of a kidney phantom.

On FIG. 8 shows a sonogram with an overlay of a color flow map.

On FIG. 9, the sonogram shows a phantom area containing microcalcifications, macrocalcifications are displayed as white dots.

Figures 1-6 contain the following structural elements: 1 - drawing of an auxiliary element that serves to prevent the pouring of liquid plastisol during pouring; 2 - drawing of the upper part of the mold used to fill the phantom; 3 is a drawing of the lower part of the mold used to fill the phantom; 4 - drawing of the model of the vascular bed; 5 - printed model of the vascular bed; 6 - printed model of the aneurysm; 7 - the form used to fill the phantom; 8 - clearance in place of the model of the vascular bed; 9 - tissue-imitating material; 10 - lumen of the aneurysm model.

The following is an example of the invention. This example only illustrates and does not limit the invention.

Prepare the form for pouring the phantom. On FIG. 1 shows an example drawing of such a mold for pouring a phantom, consisting of an upper 2 and a lower 3 parts, it also contains an element 1 that serves to prevent the pouring of liquid plastisol. If necessary, a model of such a shape can be prepared in a 3D modeling program, then the prepared shape model is printed using a 3D printer using layer-by-layer fusing technology from PLA plastic, since this type of plastic is easy to use for most 3D printers and does not interact with plastisol. Then, a drawing of the vessel model is prepared in the 3D modeling program, an example is represented by element 4 in FIG. 1. The vessel model is first prepared in the form of a drawing or in an idealized form, then for drawing, for example, Autodesk Inventor is used, or in a form close to reality, then, for example, angiographic computed tomography is used as a data source, it is opened in the RadiAnt DICOM Viewer program , the display is adjusted so that only the vessels are visible, then the 3D image of the vessels is exported in STL format. The STL file is opened for further processing, for example, in Meshmixer, where unnecessary parts of the drawing of the vascular bed model are cut off, if necessary, interface elements, such as fittings, are added to connect the vascular wort model to the hoses through which the fluid simulating blood will be supplied. The resulting virtual vessel model is prepared for 3D printing in a special program called a slicer. We used Polygon X as such a program. It generates a G code that controls the operation of a 3D printer when printing by layer-by-layer deposition. Examples of models of the vascular bed, made in the described manner from water-soluble PVA plastic using the Picaso X Pro printer, are shown in Fig. 2 in FIG. Figure 3 shows an example of placement of printed models of vessels 5 in mold 7 used to fill a phantom, where element 6 simulates an aneurysm. The model of the vascular bed 5 is fixed in the mold 7 so that its part, which will serve to connect the tubes for supplying and draining the fluid simulating blood, goes outside, the area of contact of this part of the model of the vascular bed 5 with the mold 7 is covered with a substance that seals this area. As such a substance, we used silicone sealant. Then the form with the models of vessels placed in it is covered with a sealing agent to exclude the possibility of leakage of liquid plastisol. Next, plastisol is taken, poured into a thick-walled ceramic container and heated to the recommended temperature (~150 degrees Celsius) in a microwave oven, stopping every 30 seconds for thorough mixing. They wait for the state when the plastisol becomes transparent and goes from a thick state back to a liquid state. After that, it is poured into the form of a phantom with pre-installed models of vessels. After a few minutes, the plastisol hardens. Then the form with plastisol and the models of vessels placed in it is placed in water, the plastic dissolves there, from which the models of vessels are printed. Next, they wait for the appearance of a lumen 8 in place of the models of the vascular bed and connect the tubes to the model of the vascular bed for supplying and draining the fluid simulating blood. Water is supplied through these tubes to wash out and dissolve the remaining water-soluble plastic. Examples of the resulting demoulded phantoms are shown in FIG. 4 and 5, where element 9 is a material simulating soft tissues, and element 8 are gaps simulating vessels.

When using a phantom, a liquid simulating blood is supplied through the tubes and an ultrasonic sensor is applied in the right place. Examples of sonograms obtained by ultrasonic examination of the fabricated samples are presented in Fig. 6, 7 and 8. FIG. 6 and 8 are obtained in the duplex mode of operation of the ultrasonic device, the colors and shades encode the direction of the flow rate of the fluid simulating blood. It can be seen that in area 10, modeling the aneurysm, the movement of the flow is recorded, and in area 8 the movement is not recorded, since the ultrasound system used measures the velocity projection, in this case the projection is close to zero.

A model of microcalcified tissue can also be created in the phantom. To imitate microcalcifications, microcrystals of CaSO ₄ (ρ=2.4 g/cm ³ ) with a size of about 0.1 mm, grown chemically in the thickness of agar jelly, were used. To grow microcalcifications, a solution of calcium chloride (100 ml of the reagent per 1 liter of water) and a solution of copper sulfate (50 g of the reagent per 400 ml of water) were used. When preparing the sample, the following sequence of actions was performed: 3 g of agar-agar, 5 g of gelatin and 10 mg of calcium chloride were dissolved in 100 mg of boiling water; pour the resulting solution into a container; mixed; waited for the transformation of the resulting mixture into jelly; prepared a solution of copper sulfate, while 50 g of copper sulfate was dissolved in 400 ml of water, which was heated to 60°C; allowed to cool; put jelly in it; after 3 days, the jelly was removed and found that microcrystals had formed in it. So we got a model of microcalcified tissue. It is placed in a mold for pouring a phantom and filled with a substance that, after solidification, imitates soft tissues. On FIG. 9 shows an example of a sonogram showing a model of microcalcified tissue. The speed of sound and modulus of elasticity in microcalcifications are different from these parameters for soft tissues; therefore, microcalcifications are seen as the brightest objects, highlighted in white.

We use plastisol, because it is more durable than many common materials used to simulate soft tissues, such as gelatin, agar-agar or polyvinyl alcohol, the latter dry out quite quickly when exposed to air, and in the absence of special chemical treatment, bacteria appear in them. .

In the manufacture of models of the vascular bed, 3D printing is used, which allows them to be given the necessary shapes, to introduce pathologies of interest, such as aneurysms, blood clots, plaques, etc. Printing is carried out by layer-by-layer fusing using water-soluble plastic. The blanks printed by this method can be dissolved in water, leaving cavities or gaps in their place. Models of the vascular bed prepared in this way are elastic, that is, their walls, when a pulsating flow of a fluid simulating blood flows, are able to change shape, pulsing in time with the flow.

The phantom contains areas with microcalcifications grown in the thickness of the jelly. Also, the phantom may contain objects for testing spatial, contrast resolution, speed resolution for testing Doppler modes.

The phantom can be used to train ultrasonographers in identifying characteristic anatomical features and pathologies, in particular pathologies of vascular development.

Working with the model will provide skills:

- quick selection of the ultrasound scanning mode for the best visualization of various areas and pathologies;

- recognition of the manifestation of visualization artifacts and their differences from the blood flow image;

- correct setting and coordination of the hand with the sensor according to the landmarks on the screen of the ultrasonic device.

Sources of information

1. US 10092252 Vascular phantoms and method of making the same. 2018.

2. Kandyala R, Raghavendra SP, Rajasekharan ST. Xylene: An overview of its health hazards and preventive measures. J Oral Maxillofac Pathol. 2010; 14(1):1-5. doi: 10.4103/0973-029X.64299

3. CN 109859595 A Vascular network ultrasonic phantom and making method thereof.

Claims (10)

1. A method for manufacturing a phantom for transcranial ultrasound studies, which consists in making a model of the vascular bed using 3D printing, fixing the model in the phantom body, pouring it with a liquid substance, which, after solidification, simulates soft tissues in terms of the attenuation of the acoustic wave and the longitudinal speed of sound, characterized in that - using three-dimensional printing of polyvinyl alcohol (PVA), a vascular bed is made, and the model for printing is preliminarily prepared in a three-dimensional modeling environment so that the areas forming the internal space between the walls of the vessels are printed; - the vascular bed is fixed in the housing so that its part, which will serve to connect the tubes for supplying and draining fluid simulating blood, goes outside, the area of contact of this part of the vascular bed with the housing is covered with silicone sealant; - plastisol is used as a material for simulating soft tissues, and it is preheated to a temperature at which the diffusion of the plasticizer into polyvinyl chloride occurs most quickly, liquid plastisol is poured into a body with a fixed vascular bed; - wait for the plastisol to harden; - frozen plastisol, together with the vascular bed, is removed from the body and placed in water; - wait for the dissolution of polyvinyl alcohol (PVA), which forms the vascular bed, and the formation of a gap between the walls of the vessels; - connect to the vascular bed tubes for supply and removal of fluid simulating blood; - water is supplied through the tubes to wash out and dissolve the residues of polyvinyl alcohol (PVA). 2. The method according to p. 1, characterized in that the body is made by 3D printing in the form of the organ under study according to the medical images of this organ.

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