RU2469640C1 - Method for making and inserting dental structures - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: procedure is preceded by infrared diagnosis of dentition thermal stability. If observing a uniform temperature drop in the dentitions and symmetrical cooling zones, the dental health is considered to be good and a possibility to implant a dental structure is predicted. A non-uniform dental temperature drop in the dentitions and the non-symmetrical zones therein makes stating the unhealthy thermal-contrast teeth. Infrared-controlled therapy is prescribed. Filling materials are selected with the use of an infrared scanner. A dental structure is made of the material with the thermal stability properties and a surface coated with the material with the adhesive properties. The procedure is combined with the infrared control of temperature drop progression both in the dentition, and in the dental structure.

EFFECT: method enables assessing the dentition health and quality of the prepared and implanted dental structures due to infrared diagnosing and preparation of the dental structure of the materials with the thermal stability and anti-adhesion properties.

1 ex

Description

The invention relates to medicine, in particular to dentistry, and can be used to chew food.

A known method of manufacturing porcelain crowns according to the generally accepted methodology, including examining a patient, preparing the dentoalveolar system for prosthetics, preparing an abutment, receiving impressions from both dentitions, choosing material based on color, manufacturing, fitting and fixing the porcelain crown on cement (Abakarov S.I. Modern Designs of Fixed Dentures. Textbook. - M.: Higher school, 1994. S.30-41).

The disadvantage of this method is the narrow scope, low accuracy and safety, since the method is not applicable in the absence of all teeth, while maintaining the integrity of the dentition, with color blindness, since it does not provide the choice of material with an objective assessment of its quality using hardware methods, does not provide the use materials with anti-adhesive and specified thermostable properties, excluding the adhesion of food products to them and thermal damage to tissues. Therefore, the known method contributes to increased thermolability in the tissues of the dentofacial system, contributing to a significant change in temperature under the influence of cold or hot foods and causing discomfort and pain in the areas of increased thermolability, which disrupts chewing food and the release of the oral cavity from the food lump. In this regard, the method does not provide thermal stability and painlessness of the dentition when talking in cool and frosty conditions, does not ensure the safety of the patient in cold weather, the ingestion of hot and cold water and food, low-melting fats, and also does not provide the formation of a food lump and its removal from the oral cavity.

The known method does not involve the manufacture of dental structures for healthy teeth with thermostable and anti-adhesive properties. On the contrary, the method involves damage to the teeth. In addition, the method provides restoration not so much of isothermal stability, cleanliness and preservation of the dentition, as its subjective uniformity and mechanical reconstruction. In addition, the known method is devoid of assessing the quality of manufactured and installed structures.

A known method of manufacturing dental structures, including the implementation of the general rules of odontodiating, casting castings, the choice of metal material for construction, the manufacture and installation of dental construction (V.N. Kopeikin, MZ Mirgazizov. Educational literature for students of dental faculties of medical schools, ORTHOPEDIC DENTISTRY, second edition, supplemented, Moscow - “Medicine”, 2001, pp. 157-165).

The disadvantage of this method is the narrow scope, low accuracy and safety, since the method is not applicable in conditions of complete absence of teeth, with integrity of the dentition, and also does not provide the use of materials with anti-adhesive and thermostable properties, excluding adhesion to the dental structure of food products, mastication food, the release of the oral cavity from the food lump and thermal damage to hard and soft tissues of the oral cavity. The method allows the material to have high thermolability, therefore, it does not provide thermostability of dental structures when inhaling cold air through the mouth, introducing cold water and food into the mouth. Therefore, the method does not ensure the safety of the patient in cold weather, the safety of ingestion of hot and cold water and food, low-melting fats, and also does not ensure the formation of a food lump and its removal from the oral cavity.

The known method does not involve the manufacture of dental structures for healthy teeth with thermostable and anti-adhesive properties. The method involves mechanical damage to the teeth, increasing their thermal stability (due to the high thermal conductivity of the metal), which contributes to the adhesion of low-melting food products to metal structures (in particular, sheep’s fat, chewing gum, chocolate). Food sticks to metal dental structures due to their higher thermal conductivity, and to the surface of the finished and installed structure - higher adhesion than natural teeth. Therefore, when cold or hot coolant is introduced into the mouth, metal structures cool or heat faster (respectively), which contributes to the melting and then solidification of low-melting food products, i.e. food sticking. Therefore, the method makes it difficult to form a food lump and remove it from the oral cavity.

In addition, the known method is devoid of assessing the quality of the installed structure.

The objective of the invention is the expansion of the scope, increasing the accuracy, safety and efficiency due to the manufacture of a dental structure from materials with anti-adhesive and thermostable properties, eliminating food sticking and reducing thermal damage.

This goal is achieved due to the proposed method of manufacturing and installing a dental structure, ensuring their purity and physiological thermal conductivity, the formation of a food lump and its removal from the oral cavity.

The essence of the proposed method of manufacturing a dental structure, taking into account the assessment of the condition of the dentofacial system and the choice of material, is that they preliminarily carry out infrared diagnostics of the thermal stability of the dentition to intraoral cooling during a conversation by the uniformity and symmetry of the spread of the temperature reduction zone in the teeth as they are removed from the midline , while identifying the uniformity of lowering the temperature in the dentition and the symmetry of the cooling zones s teeth evaluated as healthy and predict possibility of installing the dental structure; when an uneven decrease in the temperature of the teeth in the dentition and asymmetry of the cooling zones is established during the conversation, the condition of the thermocontrast teeth is assessed as unhealthy and they are treated under infrared control to prevent premature dismantling of the future design until the symmetry and uniformity of the decrease in the temperature of the teeth in the dentition are restored talk time due to the choice of filling materials using a thermal imager to copy the degree of cooling in blowing the respective workpieces with room temperature air after preheating them to the temperature of a healthy symmetrical tooth in the corresponding dentition, which was installed before the patient started the conversation, after which they predict the possibility of installing a dental structure made of a material with thermostable properties and with a surface coated with material with anti-adhesive properties, and the installation is carried out under infrared control of the dynamics of lowering the temperature in the tooth x series and the dental structure during a call, while maintaining physiological uniformity of cooling and the symmetry of the cooling zones.

In the claimed method, a preliminary infrared diagnosis of the stability of the dentition to intraoral cooling during a conversation by uniformity and symmetry of lowering the temperature of the teeth as they are removed from the midline provides high accuracy in assessing the state of the dentofacial system, since intraoral cooling increases the accuracy of assessing its condition and identifying poorly restored and diseased teeth. The fact is that during a conversation, the inhaled air cools the oral cavity and, above all, the teeth. In this case, cooling normally starts from the upper incisors, then the cooling zone spreads uniformly and symmetrically along the dentition to the right and left of the midline. In parallel with this, the temperature of the lower incisors begins to decrease, after which the cooling zone also begins to spread symmetrically and evenly to the right and left of the midline along the lower dentition. On the other hand, in the presence of a damaged tooth or tooth restored using thermolabile material, intraoral cooling, which occurs due to inhalation of air during a conversation, causes the patient to feel pain and an asymmetric and uneven decrease in tooth temperature detected with a thermal imager. The fact is that in the infrared range of the tissue radiation spectrum, diseased teeth are “manifested” by local hyperthermia, and teeth restored using thermolabile material are “manifested” by local hypothermia, which in both cases can be characterized as thermal contrast of unhealthy teeth.

Therefore, the assessment of the state of the dentofacial system, carried out with the help of a thermal imager in the infrared range of the tissue radiation spectrum during oral cooling during a conversation, improves the accuracy of diagnosis and prediction of its condition, and also increases the efficiency of the design, since due to its thermal stability, thermal damage to dentition tissue is eliminated into cold or hot foods and premature dismantling of the structure for treatment.

The identification of the uniformity and symmetry of a decrease in temperature in the dentition on both sides of the midline during a conversation indicates a healthy condition of the teeth and the possibility of a favorable prognosis after the installation of the dental structure.

The establishment during a conversation of an asymmetric and uneven decrease in temperature in the dentition indicates the presence of hidden or obvious damage to the teeth, since their damage is accompanied by inflammation and, as a result, local hyperthermia, which violates the uniformity and symmetry of the dynamics of the distribution of the cooling zone in the dentition to the right and left of the median lines.

The identification of the local hypo- or hyperthermia area in the dentition during intraoral cooling prior to the installation of the dental structure and the treatment of these areas under infrared control until the symmetry and uniformity of the dynamics of lowering the temperature of the teeth in the dentition during a conversation improves not only the accuracy and safety of the method, but and its effectiveness. The fact is that the installation of the dental structure only after the dental manual, carried out up to the restoration of uniformity and symmetry of lowering the temperature of the teeth in the dentition during their oral cooling, ensures the absence of potentially dangerous pathological areas and processes in the dentition that can cause premature dismantling of the structure for treatment .

The manufacture of the surface of the dental structure from a material with anti-adhesive properties eliminates the sticking of food to it, including fats like lamb fat, oils like cocoa butter, and chewing gum. The manufacture of a structure from a material with thermostable properties eliminates the increased thermolability and thermal damage to the tissues of the dentofacial system.

Treatment of the dentofacial system, carried out under infrared control until the restoration of symmetry and uniformity of lowering the temperature of the teeth in the dentition during a conversation due to the choice of filling materials using a thermal imager to copy the degree of cooling under blowing the respective workpieces with room temperature air after preliminary heating them to a healthy temperature symmetrical tooth in the corresponding dentition, which was installed before the conversation of the patient, ensuring Chiva matching thermostable properties of the patient's teeth and the materials used.

The installation of the structure under control with the help of a thermal imager of the dynamics of lowering the temperature in the dentition during a conversation only while maintaining the symmetry and uniformity of their cooling provides high quality by maintaining the physiological dynamics of thermoregulation in the mouth.

Therefore, this method of manufacturing and installing a dental structure improves its accuracy and safety by increasing thermostability and cleanliness due to better materials, which eliminates thermal damage to the tissues of the dentoalveolar system by cold or hot heat carriers and food sticking and disruption of the formation of the food lump and its removal from the mouth cavities. In addition, the claimed method expands the scope, because it provides the installation of the design on healthy teeth in the presence of all teeth and on soft tissues in the complete absence of teeth.

Example 1. Patient U., aged 33, was admitted to a dental clinic complaining of pain in her right cheek in the premolar region in the upper right dentition (tooth number 2.6) and with a desire to receive advice on the condition of all teeth. According to the generally accepted methodology, the patient was examined and found that the cause of the pain is tooth decay number 2.6. Additionally specified that the patient suffers from a deep bite. In this regard, the standard dental treatment of caries of a diseased tooth was carried out, including the removal of the affected part of the tooth, filling of the formed tooth hollow with a standard filling, after which it was decided to make and install a porcelain crown on the tooth. To do this, we prepared the dentoalveolar system for prosthetics, prepared the abutment, received impressions from the upper and lower dentition, selected the material taking into account the color of the patient’s adjacent teeth, made it, fit and fix the porcelain crown on cement. Then, to correct a deep bite, a Damon-3 bracket system was installed on both dentitions.

A week later, the patient complained of the difficulty in forming a food lump when chewing chocolate and chewing gum due to their adhesion to the crown. In addition, the patient began to worry about the pain that arises in the area of the right upper canine that was restored and is located under the metal (gold) crown when talking on the street and when cold water is introduced into the mouth.

To clarify the causes of complaints, it was decided to apply the claimed method. For this purpose, an infrared diagnosis of the thermal stability of the dentition to intraoral cooling during a patient conversation was carried out using a NEC TH91XX (Japan) thermal imager. At the same time, after 2 minutes of conversation, the uniformity of the temperature decrease zone was established across the teeth of both dentitions as they were removed from the midline to the right and left, with the exception of the right half of the upper dentition, since the local upper canine (tooth number 2.3) revealed a local hyperthermia (temperature increase by 0.2 ° C compared to neighboring teeth), and local hypothermia was detected in the upper right premolar (tooth number 2.5) (temperature decrease by 0.7 ° C compared to neighboring teeth). In addition, the symmetry of the location of the cooling zones in the lower dentition to the right and left of the midline and the asymmetry of the right and left cooling zones in the upper dentition were ascertained.

Since during the conversation, an uneven decrease in the temperature of the teeth in the upper dentition to the right of the midline and the asymmetry of the right and left cooling zones in the upper dentition were found, the condition of the thermocontrasted teeth was assessed as unhealthy and they were treated to prevent premature dismantling of the future dental structure. To improve the quality of the assessment of the state of the dentofacial system, the bracket system and crown were removed. Then, the dental treatment of nos. 2.3 and 2.5 was carried out under infrared control of the dynamics and degree of their cooling (using a thermal imager) until the symmetry and uniformity of lowering the temperature of the teeth in both dentitions was restored during a conversation the next day after treatment (reconstruction, which was completed with reflashing), and the choice of filling materials was carried out using a thermal imager to copy the degree of cooling under conditions of blowing the corresponding blanks with room temperature air after preliminary of their heating up to the temperature of a healthy tooth in a corresponding symmetric tooth number which was set prior to patient conversation. After restoring the uniformity of lowering the temperature in the dentition during a conversation and the symmetry of the cooling zones to the right and left of the midline, a prediction was made about the possibility of installing a dental structure, namely, a crown on a sore canine on the right in the upper dentition and bracket system. At the same time, the crown and bracket system were made of a material with thermostable (heat-insulating) properties and with a surface coated with material with release properties, and the bracket system was installed the day after the crown was installed. The installation of the crown and bracket system was carried out under infrared control of the dynamics of lowering the temperature in the dentition and dental structure during a conversation. A check of the dynamics of cooling the dentition carried out with the help of a thermal imager confirmed the high quality of the installed crown and bracket system, since the preservation (restoration) of the physiological uniformity of their cooling and the symmetry of the chilled zones in both dentitions was confirmed.

After 2 weeks at the second appointment, the patient did not complain of toothache during the conversation and the difficulty of forming food lumps when chewing food. An assessment of the dynamics of cooling of her teeth with a thermal imager during a 2-minute conversation in a dental office confirmed the physiological uniformity of their cooling and the symmetry of the chilled areas in both dentitions. In this regard, it was concluded that there were no pathological processes in the teeth and the high quality of the established dental structures. Long-term results showed the absence of sticking of chocolate, chewing gum and lamb fat, as well as the absence of a feeling of toothache when cold and hot food was introduced into the mouth.

Thus, the claimed method expands the scope of application, improves accuracy and safety due to the manufacture of a dental construction of materials with thermostable and anti-adhesive properties, which exclude increased thermal stability, thermal damage to tissues, food sticking and difficulty removing it from the oral cavity.

Claims (1)

A method of manufacturing and installing a dental structure, taking into account the assessment of the state of the dentofacial system and the choice of material, characterized in that they pre-conduct infrared diagnostics of the thermal stability of the dentition to oral cooling during a conversation according to the uniformity and symmetry of the spread of the temperature reduction zone in the teeth as they are removed from the midline while identifying the uniformity of lowering the temperature in the dentition and the symmetry of the cooling zones, the condition of the teeth ivayut as a healthy and predict possibility of installing the dental structure; when an uneven decrease in the temperature of the teeth in the dentition and asymmetry of the cooling zones is established during the conversation, the condition of the thermocontrast teeth is assessed as unhealthy and they are treated under infrared control to prevent premature dismantling of the future design until the symmetry and uniformity of the decrease in the temperature of the teeth in the dentition are restored talk time due to the choice of filling materials using a thermal imager to copy the degree of cooling in blowing the respective workpieces with room temperature air after preheating them to the temperature of a healthy symmetrical tooth in the corresponding dentition, which was installed before the patient started the conversation, after which they predict the possibility of installing a dental structure made of a material with thermostable properties and with a surface coated with material with anti-adhesive properties, and the installation is carried out under infrared control of the dynamics of lowering the temperature in the tooth x series and the dental structure during a call, while maintaining physiological uniformity of cooling and the symmetry of the cooling zones.