RU2533840C2 - Artificial food bolus and method for instant assessment of dento-facial health with using artificial food bolus - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, particularly to dentistry, and aims at the instant assessment of a patient's adaption to dental structures. There are used two identical artificial food boluses unbreakable by chewing and presented as a cylinder of the diameter of 1 cm ending with hemispheres 4 cm long; a plaiting thread is attached to one of the boluses; the thread has a pin on the other side to be fixed on the patient's clothes when chewing. An elastic base of the bolus is porous neoprene having a porosity of no more than 30% and air-filled. Before use, the artificial food boluses are heated to a temperature of +37°C. Heat emission of the patient's oral cavity tissues is controlled by means of a thermal camera. The bolus thread pin is fixed to the patient's clothes, and the patient is asked to place the bolus into the mouth and chew it for 30 sec, with the bolus advanced sequentially along the whole dentition. That is followed by analysing the heat emission dynamics of the oral cavity tissues. If observing no hyperthermia or short-term uniform or symmetrical temperature increase in the oral cavity tissues, the patient's adaption to chewing is considered to be high and his/her dental structure is stated to be highly stable. The non-uniform, asymmetrical and long-term tissue temperature increase shows the patient's low adaptation to chewing, low stability of his/her dental structure is predicted. The dental structure is mounted with controlling the tissue heat emission dynamics after 30-second chewing of the artificial food bolus heated to +37°C and identical to the first one; the heat emission dynamics is compared to the initial one; and an increase of the hyperthermia and its length shows the low patient's adaptation to the dental structure, and the tissue injuries are predicted.

EFFECT: by the instant assessment of the patient's adaptation to the dental structures, the method enables preventing food chewing complications following mounting the dental structure with the patient's low stability to chewing.

2 cl, 1 ex

Description

The invention relates to medicine, namely to dentistry. Known chewing gum spherical shape or shape of a food product with a taste of an elastic base of chewing gum, corresponding to the taste of this food product. The gum mass contains at least one inclusion of a filler, the filler being a liquid or viscous food product, in particular an alcoholic beverage, with a moisture content of more than 15%, enclosed in a shell with a thickness of more than 0.1 mm, which prevents the filler from contacting the mass elastic basis of chewing gum, from another food material selected from the group: caramelized sugar, chocolate, honey, gelatin, and the filler is insoluble in the shell. In this case, the taste imparted to an elastic base does not coincide with the taste of a liquid or viscous food product (RU 2197094).

A disadvantage of the known invention is that it is not intended for medical use. Known chewing gum refers to confectionery and is not intended for use in dentistry with an expert purpose when installing a dental structure. In particular, the disadvantage of the known chewing gum is its high complexity, low urgency, responsiveness, information and reliability of assessing the patient's adaptation to the manufactured dental structure, since the gum melts during chewing, sticks to the teeth and to the dental structure, and loses its shape and elasticity. The fact is that the well-known chewing gum does not have the volume and shape of a natural food lump (a bolus with a volume of 5-15 cm ³ ), and also does not ensure the preservation of the original shape, therefore, when chewing, a person is forced to give the elastic to the shape of a food lump in his mouth. As a result, the gum acquires the shape of a food lump only at the end of chewing, when it loses its original shape and elasticity, as it melts and collapses due to heating, which increases its deformation.

All this eliminates the use of the well-known chewing gum as a reference medical product suitable for functional testing for the resistance of the dentition to the dental structure during chewing.

A known method for diagnosing the pathological effect of the material of the dentures on the state of the oral cavity, which consists in measuring the controlled parameter without removing the dentures, at the test points that are selected on the surface of the tissue that limits the oral cavity, the pair of symmetry points on the outer surface of the patient’s lips, for which the lips are divided into two symmetrical parts by a visually vertical line, and the bioelectromagnetic re index is used as a controlled parameter ktivnosti (BEMR), the primary measurements are fixed, after which the calculated coefficient of asymmetry primary measurements by the formula: z ₁ = (1-V ₁ / V ₂₎ V ₁ <V ₂ or z ₁ = (1-V ₂ / V ₁ ) for V ₁ > V ₂ , where z ₁ is the asymmetry coefficient of the primary measurements, V ₁ , V ₂ are the arithmetic mean values of the BEMR indices measured primarily at the studied points on each of the symmetrical parts of the lips, respectively, then structural materials are examined for pathological effects dentures, for which between the lips of the patient along the line of symmetry a sample of the construction material of the dentures is drawn so that its inner part fits snugly on the mucous membrane of the lips, while the patient is first offered to moisten the sample with saliva, after which the BEMR index is re-measured at the same test points, the calculation results are recorded, and then the asymmetry coefficient of the secondary measurements according to the formula: z ₂ = (1-V ₁ '/ V ₂ ') for V ₁ '<V ₂ ' or z ₂ = (1-V ₂ '/ V ₁ ') for V ₁ '> V ₂ ' where z ₂ is the asymmetry coefficient of the secondary measurements, V ₁ 'and V ₂ ' are the arithmetic mean values of the BEMR indices, from measured for the second time at the test points on each of the symmetrical parts of the lips, after which the values of the asymmetry coefficients are compared and, for z ₂ > z ₁ or z ₂ = z _{1, the} presence of the pathological influence of the studied structural material of dentures is diagnosed, and for z ₂ <z _{1, the} absence is diagnosed pathological effects (RU 2146506. A method for diagnosing the pathological effect of the material of dentures on the condition of the oral cavity).

The disadvantage of this method is the high complexity, low responsiveness, urgency, informativeness and reliability of assessing the patient’s adaptation to the manufactured dental structure, since the method requires multiple “manual” measurements of the bioelectromagnetic reactivity index (BEMR), record the obtained results of primary measurements, and then calculate the asymmetry coefficient primary measurements by the formula. Therefore, the method does not provide high ease, urgency and reliability of the result. At the same time, the low reliability and information content of the known method is explained by the lack of results on the state of tissues in the place of their direct interaction with the finished dental structure. In addition, the method does not provide an assessment of adaptation to the dental structure during chewing of coarse food for the period necessary for the formation of a food lump from it, which reduces the information content of the known method and narrows its functionality.

A known method for examining the safety of medicines, including analyzing the conformity of their quality to the requirements of pharmacopoeial articles, local administration of a piglet with an indication of the time of administration, determining the dynamics of local tissue damage and issuing an opinion on the low safety of the drug when acquiring damage of an excessive nature, characterized in that it is additionally opened mouth, insert a conservator, move the upper lip, remove plaque from the vestibular surface of the upper res cts, on the necks of the central upper incisors and the adjacent gum, place the studied preparation in double single dose, lower the lip for more than 6 minutes, remove the preparation, rinse the front-upper vestibule with warm distilled water, dry it with a stream of dry warm air, irrigate it with a warm solution of 1% methylene blue, immediately wipe with a single erasing movement of a dry cotton swab and determine if the surface of the incisors, gums and lips is blue, and the low safety of the drug and the possibility of damage to the tissue It gastrointestinal judged by the localization and the degree of staining, and then removed gag (RU 2362163. Examining Method drug safety).

The disadvantage of this method is the high complexity, low efficiency, information content and reliability, since it requires the presence of a piglet, the implementation of "manual" manipulations in the oral cavity, which are an additional factor in tissue irritation. In addition, the method is intended to assess the local irritating and damaging effects of drugs, rather than dental structures. Moreover, the known method does not provide an assessment of the adaptation of each individual patient to the dental structure made for him. Therefore, the method does not provide high ease, urgency, information content and reliability of the result.

In addition, the method does not provide an assessment of adaptation to the dental structure during the chewing of food for 30 s, that is, the length of time for which a person forms a food lump when chewing hard to chew food, which reduces the information content of the known method and narrows its functionality.

Thus, the methods for assessing the patient’s adaptation to a new (just made) dental structure, identified as a result of a patent search, do not ensure the achievement of a technical result consisting in the prevention of complications by increasing the urgency, information content and reliability of the adaptation assessment.

The objective of the invention is the expansion of the scope, increasing the urgency, information content, reliability of the assessment and the prevention of complications when chewing food after installing a dental structure with reduced patient resistance to chewing due to the timeliness of chewing an artificial food lump with stable and safe elastic properties and determining the dynamics of temperature in the tissues of the mouth cavities.

This goal is achieved due to the proposed artificial food lump and the method of its use for rapid assessment of patient adaptation to the dental structure, providing an emergency and safe assessment of its resistance to the dental structure when chewing food.

The present invention solves the problem of creating a medical device with reference and safe elastic properties and a method of its use for rapid assessment of the patient’s adaptation (stability) to the manufactured dental structure, the implementation of which ensures the achievement of a technical result in the form of an assessment of the patient’s adaptation to the dental structure during dosed chewing, excluding damage to the structure and soft tissues of the oral cavity.

The essence of the proposed artificial food lump of a spherical shape from an elastic base with the taste of the food product and filler is that it is non-destructible when chewed, it is a cylinder with a diameter of 1 cm with hemispheres on the ends of 4 cm long, a braided thread with a clip is attached to one of them on the other end, which provides attachment to the patient’s clothing during chewing, the elastic base is porous neoprene with a porosity of not more than 30%, the filler is air.

The essence of the proposed method of its use for rapid assessment of the patient’s adaptation to the dental structure, taking into account its quality, assessment of the state of the dentofacial system, local injection into the oral cavity with fixation of the injection time, selection of paired symmetry points, repeated measurement of the controlled parameter in them, processing of the obtained values, determining their dynamics and assessing the state of tissues with the conclusion on the possibility of damage to excessive values, is that they control the heat radiation, measurement is carried out using a thermal imager, pre-heat two artificial food lumps to + 37 ° C, fasten the thread clamp of the first lump to the patient’s clothes, ask him to put the lump in his mouth and chew for 30 s, moving the lump sequentially throughout the dentition, after which the dynamics of heat radiation of the tissues of the oral cavity is examined, while in the absence of hyperthermia or with a short-term uniform and symmetrical increase in temperature in the tissues of the oral cavity, the patient’s adaptation to chewing is evaluated to to predict high and its high resistance to the dental structure; with an uneven, asymmetric and prolonged increase in temperature in the tissues, the patient's adaptation to chewing is assessed as low and its low resistance to dental design is predicted; the installation of the dental structure is carried out under the control of the dynamics of heat radiation of tissues after chewing for 30 s of the second identical artificial food lump heated to + 37 ° C, the dynamics of heat radiation is compared with the initial one, and when the values and duration of hyperthermia are increased, low patient adaptation to the dental structure is judged and predict tissue damage.

In the claimed method, a preliminary (before the installation of the dental structure) study using a thermal imager of the dynamics of heat radiation of the tissues of the oral cavity in a patient after chewing them for 30 s with an artificial lump made of porous neoprene in the form of a cylinder with a diameter of 1 cm with hemispheres at the ends of 4 cm and heated to body temperature, provides information about the initial resistance (adaptation) of the patient to chewing. The use of a thermal imager provides control of the temperature of the tissues of the oral cavity almost without contact with them and almost instantly.

The specified shape, as well as the diameter and length of the artificial food ball, are optimal for solving the problem, since sizes smaller than the specified ones do not provide modeling of the physiological process of chewing semi-rough and rough foods, in particular bread products, and do not provide mechanical impact on the entire chewing area premolars and molars, and sizes larger than indicated are redundant because they exceed the sizes of a safe and comfortable physiological food lump. Neoprene is the most inert synthetic polymer that does not react with water, alcohol and other organic solvents. Neoprene porosity of not more than 30% and filling the pores with air provide a safe physico-chemical regime and a level of elasticity.

Attaching braided thread to one of their ends with a clip on the other end, which ensures attachment to the patient’s clothing while chewing, is necessary to prevent the patient from accidentally swallowing an artificial food lump during diagnosis of adaptation to the dental structure. The braided thread provides durability of retention of the food lump and safety of use.

Chewing for 30 s of an artificial food lump heated to body temperature while moving it along the entire dentition provides modeling of the physiological process of chewing semi-coarse and elastic food, standardizes the study, provides high information content by participating in the chewing of the entire dentition, and also provides high accuracy comparing the results and safety for the dental structure and tissues of the oral cavity of the patient. In addition, the introduction into the patient’s mouth of an artificial food lump at body temperature provides high accuracy in measuring the temperature of the tissues of the oral cavity, the reliability and information content of the method.

Moreover, in the absence of hyperthermia or in the case of short-term uniform and symmetrical appearance in the tissues of the oral cavity, the patient's adaptation to chewing is assessed as high and high patient resistance to the dental structure is predicted. The fact is that hyperthermia is a symptom of inflammation, therefore its absence indicates the absence of irritation and inflammation, and the appearance of symmetrical foci of local hyperthermia for a short period indicates the reversibility of tissue inflammation, which also indicates a high patient resistance to the dental structure.

In turn, with an uneven, asymmetric and prolonged increase in temperature in the tissues, the patient's adaptation to chewing is assessed as low and low resistance to dental construction is predicted, since prolonged local hyperthermia indicates prolonged inflammation of the tissues.

The implementation of the installation of the dental structure under the control of the dynamics of heat radiation of the tissues after chewing for 30 s of the artificial food lump heated to body temperature ensures the modeling of physiological chewing of food and the safe conduct of a standardized test for patient resistance to chewing, the inflammatory response of tissues of his oral cavity in the presence of a dental structure, and also makes it possible to compare the final dynamics of the heat radiation of tissues with its initial dynamics, and the patient’s place before the installation of the dental structure.

Comparison of the dynamics of heat radiation of the tissues of the oral cavity obtained with a standardized test for chewing using a special artificial food lump before and after the installation of the dental structure provides an express assessment of the patient's resistance to the dental structure as follows. With an increase in the total temperature and duration of hyperthermia, a patient is judged of low adaptation to the dental structure and tissue damage is predicted, since an excess of the final thermogram over the initial thermogram indicates the exhaustion of the patient's adaptation reserves to the established dental structure.

The study of the heat radiation of the tissues of the oral cavity after chewing an artificial food lump for 30 s models the process of physiological chewing of semi-rough food, provides high speed, safety, standardization, physiology and information content of the method.

Therefore, the created artificial food lump and this method of its use for the rapid assessment of patient adaptation to the dental structure increases urgency, informativeness, reliability of the assessment and expands the scope of application due to chewing of the lump at body temperature with stable elastic properties and increasing the accuracy of determining the dynamics of local hyperthermia in tissues of the oral cavity. At the same time, the use of a warm artificial lump of porous neoprene in the form of a cylinder with a diameter of 1 cm and hemispheres at the ends of 4 cm for chewing standardizes the study, improves accuracy and safety by increasing the thermal stability and cleanliness in the patient's mouth due to the absence of materials in the food lump capable of exerting a local irritant and allergic effect, which eliminates thermal damage to the tissues of the dentition by cold or hot heat carriers, the adhesion of the food lump and it is removed from the oral cavity. In addition, the claimed method extends the scope, as it provides an assessment of the patient's resistance to chewing, regardless of the installation of the dental structure.

The device operates as follows. Before installing the dental structure, a patient is tested for its resistance to chewing of a “reference” artificial food lump. Before this, an artificial food lump is heated to body temperature (for example, by means of a water bath), a clamp is attached to the threads of the lump to the patient’s clothes so that the patient can chew the lump, they ask the patient to start chewing the lump, moving it sequentially throughout the entire dentition, time is noted. , after 30 seconds, ask the patient to stop chewing and spit out a lump. After that, the clamp is disconnected. They ask the patient to open his mouth wide, expand his mouth to the maximum possible size with the help of dental retractors, measure the heat radiation of the tissues of the oral cavity with a thermal imager, evaluate the results, then establish the dental design and reuse another identical artificial food lump in the same way, after which measure the heat radiation of the tissues of the oral cavity using a thermal imager, evaluate the results, compare them with the original values niyami and outputting a final conclusion about the adaptation to the patient's dental structure.

Example 1. Patient U. at the age of 57 turned to the dental clinic with a complaint about the absence of molars in the lower right dentition and with a desire for implantation. In this regard, a standard surgical implantation operation was performed at the site of the missing first molar. After 3 months, the patient was invited to continue treatment, while the implant was opened, a gum shaper with surgical sutures was installed on it. After 2 weeks, the patient was invited for examination and further treatment. At the same time, the healthy condition of the gums around the implant was ascertained, suture threads and the healing abutment were removed, then the impression was taken from the level of the implant, after which a new healing abutment was installed. After 10 days, the patient was invited to install a crown.

Before the final installation of the final part of the dental structure, it was decided to evaluate the patient’s adaptation to it when chewing food using the created artificial food lump and a rapid assessment method for the patient’s adaptation to the made ceramic-metal crown. To do this, with the help of a water bath, two identical artificial food lumps, each of which is non-destructible when chewed, were preliminarily heated to body temperature; it is a cylinder 1 cm in diameter with hemispheres at the ends 4 cm long, a braided thread is attached to one of the ends with a clip on the other at the end, which provides attachment to the patient’s clothing while chewing, the elastic base is porous neoprene with a porosity of 25%, the filler is air. Then examined the heat radiation of the tissues of the oral cavity using a thermal imager. At the same time, the absence of foci of local hyperthermia in the patient's mouth before chewing an artificial food lump was noted. They fastened the clamp with the thread to the patient’s clothes so that the thread ensured that it was chewed freely and kept from swallowing, they suggested that the patient place a lump in his mouth and chew it for 30 s, sequentially moving the lump across the entire dentition, and then asked the patient to remove the lump from mouth out, disconnect the clamp, put the used lump in the tray and examined the dynamics of heat radiation of the tissues of the oral cavity. It was found that there was a uniform and symmetric increase in temperature in the tissues of the oral cavity by 0.2-0.4 ° C, which lasted about 30 seconds, and then the temperature returned to normal. Based on these data, the initial adaptation of the patient to chewing was rated as high and a prediction was made about its high resistance to the manufactured dental structure.

In this regard, it was decided to install a manufactured crown. Before that, the gum former was removed, the abutment was installed on the implant, and the made ceramic-metal crown was installed on the abutment under the control of the dynamics of heat radiation of tissues after the patient chewed for 30 seconds from the second (identical to the first lump) artificial food lump heated to + 37 ° C. It turned out that immediately after chewing an artificial food lump, the temperature of the tissues of the oral cavity uniformly and symmetrically increased by 0.2-0.4 ° C, and then after 30 seconds the temperature returned to its original values. The dynamics of the heat radiation of the tissues of the oral cavity were compared, obtained after a sample with chewing of an artificial food lump before and after the installation of the crown, revealed the absence of an increase in the values and duration of hyperthermia compared with the values of the initial dynamics and on this basis made a conclusion about the patient's high resistance to the manufactured ceramic-metal crown and gave a forecast on the exclusion of excessive inflammation and tissue damage when chewing ordinary food.

A week later, the patient came to the clinic for prophylaxis and a final examination. There were no complaints of impaired chewing function of food and there were no symptoms of inflammation and damage to the tissues of the oral cavity.

In this regard, it was concluded that there were no pathological processes in the tissues of the oral cavity, as well as about the high accuracy, information content and prognostic significance of the proposed artificial food lump and the method of its use for rapid assessment of patient adaptation to the dental structure.

Long-term results showed the absence of complaints of violation of chewing food and the absence of symptoms of inflammation and damage to the soft and hard tissues of the oral cavity.

Thus, the claimed artificial food lump and the method of its use for rapid assessment of patient adaptation to the dental structure expands the scope of application, increases the urgency, information content, reliability of the assessment and prevents complications when chewing food after installing the dental structure with reduced patient resistance to chewing due to timeliness chewing of an artificial food lump with stable and safe elastic properties and determining the dynamics of temperature in the tissues of the mouth howling cavity during dental benefits.

Claims (2)

1. An artificial food ball of a spherical shape made of an elastic base with the taste of a food product and filler, characterized in that it is non-destructible when chewing, is a cylinder with a diameter of 1 cm with hemispheres on the ends of 4 cm long, a braided thread with a clip is attached to one of them on the other end, which provides attachment to the patient’s clothing during chewing, the elastic base is porous neoprene with a porosity of not more than 30%, the filler is air. 2. The method of rapid assessment of the state of the dentofacial system using an artificial food lump according to claim 1, including local introduction of it into the oral cavity with fixation of the injection time, the choice of pair symmetry points, repeated measurements of a controlled parameter in them, processing of the obtained values, determination of their dynamics , assessment of the state of the dentofacial system, while controlling the heat radiation, making measurements using a thermal imager; pre-heat two artificial food lumps to + 37 ° C, fasten the clamp of the thread of the first lump to the patient’s clothes, ask him to put the lump in his mouth and chew for 30 s, moving the lump successively throughout the entire dentition, and then examine the dynamics of heat radiation of the tissues of the oral cavity in this case, in the absence of hyperthermia or with a short-term uniform and symmetrical increase in temperature in the tissues of the oral cavity, the patient's adaptation to chewing is assessed as high; with an uneven, asymmetric and prolonged increase in temperature in the tissues, the patient's adaptation to chewing is assessed as low; the installation of the dental structure is carried out under the control of the dynamics of heat radiation of tissues after chewing for 30 s of the second identical artificial food lump heated to + 37 ° C, the dynamics of heat radiation is compared with the original one, and when the values and duration of hyperthermia are increased, low patient adaptation to the dental structure is judged and predict tissue damage.