RU205367U1 - Dento model to simulate tooth mobility and dentition deformities - Google Patents

Abstract

The utility model relates to orthopedic dentistry and can be used to simulate the pathological mobility of teeth and deformities of the dentition. The technical result of the utility model is to simulate the movement of teeth in different directions with pathological mobility of the teeth, deformities of the dentition, which can be used for teaching dental students. The dento model is represented by a plastic base covered with an artificial gum made of silicone with cutouts for artificial teeth and containing sockets in which artificial teeth made of plastic are placed, while the inner surface of the wells is covered with a thin-walled copper plate, and the wells themselves are filled with a tin-containing fusible alloy, The model contains heating elements for melting a low-melting alloy, located under the sockets for artificial teeth and connected to a power supply and a thermostat.

Description

The useful model relates to orthopedic dentistry and can be used to simulate pathological tooth mobility and dentition deformities. These pathologies develop in chronic periodontal diseases of a person, thereby, the dento-model imitates the state of the position of the teeth in periodontal diseases.

At the moment, there are various practical and theoretical methods that allow assessing changes in tooth mobility in patients with chronic periodontal diseases and partial absence of teeth, however, many of the clinical diagnostic techniques do not provide a full-fledged visual representation of the movement of teeth in these pathologies. Visual mock-ups that imitate the mobility of teeth and deformations of the dentition can be used in the development of dental orthopedic disciplines by dental students.

The closest analogue to the proposed utility model is a method of making dento-models of the jaws for use in dental simulators [RU 2661713 C1, Publ. 07/19/2018], this method allows you to make a denture model of the jaw for various dental simulators, a feature of this method is the manufacture of a mold according to the existing model of the jaw, the resulting form is filled with liquid polyurethane plastic, as a result, it is possible to obtain a new non-separable denture model made of plastic, which is not has the ability to retrofit with any additional elements. The difference between the proposed utility model and the models obtained by this method is that the developed dento-model contains a base (base) of the model with holes for artificial teeth, the inner surface of the holes is covered with a thin-walled copper plate and filled with a tin-containing fusible alloy, for example, Melot alloy, when This denture model contains heating elements that melt the fusible alloy inside the sockets to create controlled mobility of the teeth to be placed in the sockets. The proposed model differs from its analogue in that it is collapsible, equipped with various functional elements and allows you to simulate the mobility of teeth.

The prototype of the utility model is the orthodontic typodont [RU 135253 U1, publ. 12/10/2013], which is an anatomical model for teaching manipulations in orthodontics and can be used to study the biomechanics of teeth movement in three directions under the influence of imposed orthodontic equipment in the process of teaching practical orthodontic skills. Orthodontic typodont is represented by a denture model with a plastic base (base) and artificial teeth, on which orthodontic appliances can be installed, while the sockets of the artificial teeth are filled with wax. The difference between the proposed utility model and the described utility model is that the developed model contains a tin-containing low-melting alloy, for example, the Melot alloy in the sockets of artificial teeth, which makes the model reusable. Another difference is that hot water or hot air is used to melt the wax in the wells of the orthodontic typodont device to create tooth mobility; the proposed utility model contains heating elements for melting a low-melting alloy to create controlled tooth mobility.

The problem to be solved by the claimed utility model is the imitation of various degrees of tooth mobility in the jaw and the demonstration of deformations of the dentition.

The technical result of the useful model is the imitation of the movement of teeth in different directions with pathological mobility of teeth, deformities of the dentition, which can be used for teaching dental students.

The technical result of the utility model is achieved by the fact that the sockets for artificial teeth of the dento-model are filled with a tin-containing fusible alloy, for example, the Melot alloy, which is melted using heating elements, thereby creating a controlled mobility of the teeth and it becomes possible to imitate the movement of teeth in different directions.

Description of drawings

FIG. 1 shows the outer side of the dento model to simulate tooth mobility and deformities of the dentition, where

1 - hole for an artificial tooth;

2 - low-melting alloy;

3 - base of the model;

4 - artificial tooth;

5 - artificial silicone gum; 6 - thin-walled copper plate.

FIG. 2 shows the inner side of the dento-model to simulate the mobility of the teeth and deformities of the dentition, where

1 - artificial tooth socket;

3 - base of the model; 7 - heating element; 8 - power supply unit; 9 - thermostat.

Description of the utility model

The dento model is a plastic base (base) (Fig. 1-3), covered with a removable artificial gum made of silicone with cutouts for artificial teeth (Fig. 1-5), the base contains holes for artificial teeth (Fig. 1- 1), in which artificial teeth made of plastic are placed (Figs. 1-4) with the possibility of their extraction from the holes, the inner surface of the holes is covered with a thin-walled copper plate (Figs. 1-6), and the holes themselves are filled with a tin-containing fusible alloy (Fig. 1 -2), the base of the dento-model (Figs. 2-3) also contains heating elements (Figs. 2-7), which are located under the holes for artificial teeth (Fig. 2-1) and connected to the power supply unit (Fig. 2 -8) and a thermostat (FIGS. 2-9) and can be heated in a controlled manner in the range from 10 to 50 ° C.

The essence of using the model lies in the fact that a tin-containing low-melting alloy, for example, the Melot alloy, which fills the holes for artificial teeth, is heated with the help of heating elements located under these holes, which controllably develop a temperature in the range from 10 to 50 ° C, so the alloy itself is melted, the mobility of artificial teeth is created and it becomes possible to imitate the movement and mobility of teeth in different directions.

Usage example

When the low-melting alloy contained in the wells of the base of the dento-model is melted, the mobility of artificial teeth is formed in different directions (to the sides, up, down), thereby it becomes possible to imitate the pathological mobility of teeth or deformities of the dentition that occur in diseases of the human periodontal. This state of tooth mobility is due to the fact that chronic periodontal diseases lead to the destruction of collagen and elastin ligaments of the tooth in the tooth socket, thereby forming its pathological mobility, deforming the dentition. Thus, the dentist model can fully simulate the pathology described above, which can be used to train dental students.

Claims (1)

A dento model for imitating the mobility of teeth and deformations of the dentition in periodontal diseases, represented by a plastic base covered with an artificial gum made of silicone with cutouts for artificial teeth and containing holes in which artificial teeth made of plastic are placed, characterized in that the inner surface of the holes is covered with a thin-walled a copper plate, and the wells themselves are filled with a tin-containing low-melting alloy, while the base of the dento-model contains heating elements for melting the low-melting alloy, located under the holes for artificial teeth and connected to a power supply and a thermostat.

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