RU2725131C1 - Method for screening dental cleansers on model of transparent teeth coated with dental deposit - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine and can be used in searching for, developing and evaluating new pharmacological, sanitary-and-hygienic, cosmetic products and medical technologies intended for emergency cleaning in the oral cavity of all open surfaces of teeth and dental structures. Disclosed method of dental cleansers screening is based on comparison of transparency of dental laboratory model before and after exposure of analyzed agent by means of determination by means of amperemeter in conditions of darkness of electric current in photosensor from oxyhemograph sensor when light emitted by the white light mini emitter and passing through the biological material and the plates made of colorless transparent quartz glass in the form of rectangular flat even sheets are placed on the base and are parallel and mirror-parallel to the base. When analyzing the obtained results, it is assumed that a decrease in the photocurrent strength indicates an increase in the content of the light-absorbing biomaterial. Denture model represents 4 plates tightly fixed by narrow ends on a single base in one row across it and perpendicular to the base surface with gaps of 2 mm. Each plate has thickness of 2 mm, width of 4 mm and height of 10 mm. Intensity of light passing through the transparent plates is recorded before, immediately after depositing on their surface a plaque simulator in form of thickened infusion of leaves of black tea and oyster mushrooms and then immediately after completion of the process of irrigating the surface of plates for 2 minutes with the solution of the test agent heated to a temperature of +43 – +65 °C, using an irrigation agent for the oral cavity.

EFFECT: technical result is rapid evaluation of agent purification activity in standard laboratory conditions.

1 cl, 1 ex

Description

The invention relates to medicine, namely to pharmacology, pharmacy, cosmetology and dentistry, and can be used in the search, development and evaluation of new pharmacological, sanitary-hygienic, cosmetic products and medical technologies for emergency cleaning in the oral cavity of all open tooth surfaces and dental designs.

Currently in experimental pharmacology there is no technology for laboratory screening of cleaning agents for surfaces of hard and soft tissues of the human body, including natural and artificial teeth and various dental structures. To this it should be added that in dentistry, pharmacology and pharmacy there is still no group of pharmacological agents combined with a cleaning mechanism of action, that is, combined with a specific activity that manifests itself in a local interaction by physicochemical removal of food debris, traces of blood, pus and plaque with surfaces of natural and artificial teeth, crowns, implants, dentures and braces. In addition, in dentistry and cosmetology there are no technologies for emergency cleaning of surfaces of hard tissues in the oral cavity and, when used once for 1-2 minutes, they completely clean the open surfaces of all teeth, dental fillings, dental crowns, implants, dentures, braces and other dental structures.

At the same time, in some areas of medicine and in other areas of human activity, cleaning agents and surface cleaning technologies are already known. In particular, in the field of purulent surgery, cosmetic pharmacology and forensic medicine, special agents developed for emergency cleaning of the skin surface, mucous membranes, hair, medical dressings and human clothes from biological tissues due to express softening and removal of thick and sticky pus, sulfur plugs and dried blood. In the field of car services, tools and technologies have been known for a long time and have been successfully used to provide emergency washing of painted surfaces of bodies, glass surfaces and automobile engines due to special tools and devices that provide express removal of stains of fuel, oil, paint, road dust and dirt.

The lack of a method for screening dental cleaners delays the search for effective hygienic and cosmetic products that provide rapid removal of plaque and food contaminants from tooth surfaces and dental devices in the oral cavity. This problem is exacerbated by the fact that in the last decades the life expectancy of people has increased, and with it the period of their use of teeth for chewing food has lengthened, which leads to aging and tooth decay in old age. This occurs both from an increase in chewing load, and from plaque, which is formed from food debris with the participation of microflora. Plaque becomes a hotbed of infection in the mouth and is one of the causes of halitosis, caries, periodontal disease and other microbial lesions.

At a young age, the body's defenses usually successfully cope with this danger. But in adulthood and in old age, the protective forces can dry out, and the effectiveness of protecting your teeth from microbial damage can decrease. Currently, to combat microbial contamination in the oral cavity, mainly drugs containing antiseptics are used: lozenges, sucking tablets, elixirs and mouth rinses. The following devices and tools are used to remove plaque and other dental contaminants: toothbrushes, toothpicks, tooth powders, toothpastes and oral irrigators. To eliminate the foul odor, various fresheners containing menthol and other flavors are used. However, the use of these devices and means does not provide a solution to this problem, and plaque remains on the teeth and on the dental structures, which worsens the bad breath, microflora in the oral cavity, aesthetic result and undermines people's health. The creation of special dental cleaners can improve the situation. For this, a laboratory screening method for cleaning products is needed.

It should be noted that the first tools and methods for emergency cleaning of medical bandages, clothes, skin surfaces and hematomas from spots and blood clots were invented in the Russian Federation. Today, these medicines are known as “Bleeding Bleaches” [1]. Moreover, it was in Russia that the first “Method for screening bleach bleach screening” was invented [2]. This allows us to hope that the first dental cleaners will also be developed in the Russian Federation. There is no doubt that the development of a laboratory screening method for cleaning agents will accelerate the creation of such agents.

A known method for the rapid evaluation of the effect of toothpastes is based on determining the luminosity of the luminol-dependent chemoluminescence of the oral fluid before and after brushing the teeth with toothpaste, in which if the luminescence is decreased or increased by 20% or more, it is believed that the toothpaste inhibits or stimulates ( respectively) free-radical oxidation and vital activity of microbes in the oral fluid (RU 2328740).

The disadvantage of this method is the low efficiency, speed, accuracy, safety and a narrow scope. The fact is that the study of the oral fluid and the determination in the saliva of a volunteer and / or patient of the level of biochemical markers of peroxidation and traces of the activity of microbes does not provide information about the ability of toothpaste to remove plaque from the surface of teeth and dental structures, as well as the degree of purity of these surfaces after applying toothpaste. This is because the study of peroxidation processes in the oral fluid does not accurately reflect the results of cleaning the surface of the teeth with the evaluated preparation. At the same time, evaluating the effect of toothpaste on the volunteer's teeth does not provide high safety and speed, since it does not exclude the development of side and negative effects, such as local irritant effect, local inflammation and allergic reaction. In addition, the use of one living volunteer to evaluate the effect of the drug does not provide reliable information; since the method does not exclude the presence of an individual structural feature and function of the soft and hard tissues of the oral cavity in the selected volunteer, and also does not ensure compliance with standard and repetitive conditions for local interaction of the studied drug with the selected dental surface. In addition, it is unrealistic and unsafe for the health of a volunteer to screen dental cleaner products multiple times on the same person in a short period of time in practice.

In addition, the known method does not provide for several series of studies in a short period of time. All this reduces the accuracy of the results and slows down the speed of obtaining reliable data.

In addition, the method requires the participation of personnel specially trained in immunochemical research methods.

In addition, the use of the immunochemical research method in experiments with the oral fluid of a particular patient does not provide standardization of the data obtained, repeatability of the results when using saliva of other patients, or even saliva of the same patient, but obtained with an interval of several days. In addition, the immunochemical method does not provide information on the mechanism of action of drugs, in particular, on their local physico-chemical interaction with plaque. In this regard, the immunochemical method is not suitable for screening funds - dental cleaners at the stage of preclinical studies.

In addition, the use of volunteer saliva reduces the safety of screening, since human saliva can be a source of infection for research participants with infection.

A known method of screening pharmacological compounds for neuroprotective activity, based on the cultivation of primary: cultures of neurons or primary glial cells, adding a test compound to them, assessing the survival of cultured neurons or proliferation of cultured glial cells (RU 2383615).

The disadvantage of this method is the low speed, efficiency, accuracy and a narrow scope, since the method is not intended for emergency assessment of pharmacological activity.

In addition, the method is not intended for screening means-: dental cleaners.

A known method for determining plaque deposits in patients with bridges based on staining the surface of the prosthesis with 0.1% rhodamine 6G solution and determining the amount of plaque by color intensity using ultraviolet light of 300-400 nm using a 5-point scale (RU 2286719 )

The disadvantage of this method is the low speed, efficiency, accuracy and a narrow scope, because the method does not provide an estimate of the total contamination of the selected surface and does not provide an assessment of the cleaning activity of drugs that claim to be dental cleaners. The fact is that in the known method, the determination of the amount of plaque is carried out by an indirect method, namely, by changing the color of the tooth surface in the ultraviolet range of rays after irrigation with dye. In other words, in the known method, the tooth surface is additionally painted (stained) by applying a dye to the surface to be examined. Moreover, in the known method, the color intensity of the colored plaque is determined not by means of a sensitive and accurate optical device, but by eye.

In addition, the method does not provide a determination of the total contamination of the selected surface, since its irrigation with a 0.1% rhodamine 6G solution allows only Ca, Zn, tungstates and some other elements of the periodic system of chemical elements to be detected in the ultraviolet spectrum (periodic table). In other words, the known method does not provide the use of a universal dye. Therefore, the known method does not provide for the identification of all potential 'dental contaminants of tooth surfaces and dental structures.

A known method of photo-electro-colorimetric determination in the absence of external illumination of the amount of substances in solutions using photoelectrocolorimeters (FEC) of various brands (http://505days.com/fiziko-himicheskie-metody-analiza/fotoelektrokolorimetriya/. Found on the Internet 05/14/2019 ) using rectangular cuvettes made of quartz glass of the KU-1 brand with a wall thickness of 1.25 and 3 mm (https://www.sovlab.ru/kyuvetyi-dlya-fotokolorimetrov-i-spektrofotometrov.html. Found on the Internet 05/14/2019). The method of photocolorimetric determination of the amount of substances is based on the fact that the light flux is passed through a colored liquid placed in a quartz glass cuvette, in which the opposite walls (glass plates) are rectangular, placed parallel and mirror to each other, and the intensity of the light passing through through the two walls of the cuvette and the thickness of the test solution between them and then incident on the photocell in which an electric current is caused, they are estimated using an ammeter according to the current strength that appears in the photocell, and the results are analyzed based on the fact that the smaller the force of the photo current , the greater the optical density of the solution, the degree of absorption of light by the solution and the greater the concentration of the substance in it.

The disadvantage of this method is the low speed, efficiency, accuracy and narrow scope, because the method does not provide an estimate of the total contamination of the selected surface and does not provide an assessment of the cleaning activity of a potential dental cleaner. The fact is that the method does not provide the application of food contaminants to all surfaces of the cuvettes, the treatment of these surfaces with investigated agents that claim to be dental cleaners, and does not provide an assessment of the cleanliness (contamination) of these surfaces from food contaminants before and after surface treatment with the studied agents.

In addition, the known method is not intended for laboratory screening of cleaning products.

It should be added that the known method requires the use of a dye, which further pollutes the surface and introduces an error in the assessment of the cleaning (cleaning) activity of the preparations, since it automatically requires them to remove not only foodborne contaminant, but also the dye introduced into the solution.

The objective of the invention is to increase the efficiency, speed, accuracy, safety and expand the scope by introducing a solution of the studied product heated to a temperature of +43 - + 65 ° C in the tank of the irrigator until the tank is filled and then irrigated for 2 minutes with a solution of this tool using the tip of the irrigator of the surface of the model of the dentition, made in the form of a comb with 4 teeth in the form of flat transparent colorless plates 2 mm thick, 4 mm wide and 10 mm high, placed at intervals of 2 mm in one row parallel and mirror to each other and assessing the cleansing activity of the agent by registering the intensity of light passing through the transparent plates before, immediately after applying plaque simulator on their surface in the form of a condensed infusion of black tea leaves and oat jelly and then immediately after completion of the irrigation of the surface of the plates with a solution of the studied agent.

The technical result is an express assessment of the cleansing activity of the agent in standard laboratory conditions using a dentition model with plaque simulator with the exception of infection of researchers and local irritation and inflammation of the soft tissues of the oral cavity in a volunteer.

The essence of the method of screening dental cleaners, based on comparing the transparency of the laboratory model before and after exposure to the studied means by determining with the help of an ammeter in dark conditions the electric current in the photocell when light emitted by a special emitter with a certain wavelength and intensity and transmitted through biological material and plates made of colorless transparent quartz glass in the form of rectangular even flat sheets mounted on the base with wide planes parallel and mirror-like to each other at certain intervals, and on the analysis of the results obtained, based on the fact that the decrease in the photo current indicates an increase in the content of biomaterial that absorbs light, consists in the fact that 4 plates are firmly fixed with narrow ends on a common base in one row across and perpendicular to the surface of the base with 2 mm intervals, each the plate has a thickness of 2 mm, a width of 4 mm and a height of 10 mm, the light intensity is recorded immediately before, immediately after applying the biomaterial to the entire area of the open surface of the plates and immediately after completion of the irrigation process with a solution of the studied medium, the solution of the studied medium at a temperature of +43 - + 65 ° C is poured into the capacity of the irrigator for the oral cavity until the capacity is filled and then the solution is applied using the tip of the irrigator for 2 minutes to the surface of all plates, using fresh infusion of black tea leaves at + 25 ° C and oatmeal as biomaterial jelly at a temperature of +60 - + 65 ° C, the plates are immersed completely alternately for 1-2 seconds, first in the infusion, then in the jelly, after each immersion, the dentition model is placed with the plates down and in this position they are waiting for the completion of the process of draining excess biomaterial from them, then blow off the surface of the plates with a household hairdryer with a stream of dry air at room temperature to a defined thicken liquid biomaterials by eye until they turn into a film that is firmly glued to the surface of the plates, then the model is placed in a sink in which it is placed with the plates up, fixed in this position and irrigated by the solution of the studied agent, the obtained results are analyzed and an opinion is made on the ability of the studied means to quickly clean the tooth surfaces from plaque simulator, if necessary, re-application of the method, the surfaces of the plates are cleaned to full cleanliness, dried and the method is reused with the same or other means, analyze the results and give a final conclusion.

In the claimed method, the use of a laboratory model, including 4 rectangular plates made of quartz glass with a thickness of 2 mm, a width of 4 mm and a height of 10 mm, firmly fixed on a single base with narrow ends with gaps of 2 mm in the shape of teeth combs, located wide planes parallel and specular to each other in one row across it and perpendicular to the surface of the base with 2 mm intervals, increases speed, accuracy, safety and expands the scope of application, as it provides modeling of a transparent and colorless dentition of an adult, suitable for laboratory screening of cleaning products, carried out by changing the degree of transparency of the biomaterial covering the surface of the plates. Moreover, the plates have a shape and size that mimic the shape and size of the largest upper incisors of a person, and the biomaterial has a composition, thickness and color similar to fresh plaque. The fact is that the purity of the alveolar surfaces of the upper incisors is the most important for the aesthetic result in everyday life for most people. The dimensions of the width of the plates with a value of 4 mm and their height with a value of 10 mm are explained by the maximum possible sizes of natural and artificial incisors in adults. The imitation of the incisors in the proposed laboratory model by means of plates, the sizes of which correspond to the maximum dimensions of the alveolar surface of the adult incisors, provides the method with high accuracy and practical significance of the results, suitable for clinical use, and standardizes the research conditions. The thickness of the plates with a size of 2 mm and the presence of intervals between them of 2 mm ensures, on the one hand, the high strength of the laboratory model of the dentition, the durability of its use, the reliability of applying biomaterial to all surfaces of the plates, the possibility of local effects of the studied funds on all surfaces of the plates and the convenience of mechanical cleaning of internal surfaces with brushes and abrasive materials to prepare for the next use in the next study. On the other hand, the indicated parameters of the laboratory model of the dentition, as well as the fact that the plates are installed perpendicular to the surface of the base and with their planes across the center line of their row, provide high accuracy in assessing the degree of transparency of all 4 plates simultaneously with plaque-like biomaterial applied to their surface . The fact is that in the claimed method, the degree of transparency is estimated using an ammeter. An analogue of such studies is a pulse oximeter, the factory external sensor of which is intended for application to the fingers based on the maximum maximum thickness of the largest finger in men, which reaches 15 mm, which is encountered in practice. The fact is that excessive increase or decrease in the gap between the light source and the photocell in the pulse oximeter sensor reduces the accuracy of the results. The proposed model of the dentition consists of 4 plates with a thickness of 2 mm and 3 spaces between them with a width of 2 mm, so the total size of the model (the distance between the extreme surfaces of the plates of the dentition model) is 14 mm. This total value of the transparent transparent object made of colorless transparent quartz glass with a food product on its surface is optimal for assessing its total transparency.

The use of the laboratory model of the dentition increases the speed, safety and expands the scope, since it eliminates the infection of researchers with pathogenic microorganisms and ensures that the standard model of the dentition is ready for laboratory screening of dental cleaners at almost any time of the day. The presence of such a model eliminates overly long preparation for laboratory screening of drugs and eliminates the delay in the start of the experiment. In addition, the use of a laboratory model eliminates the development of side effects and complications in the oral cavity in patients studying the cleaning activity of pharmacological agents, and also extends the range of biologically active substances studied, since laboratory tests do not require proven dental safety and official approvals for clinical trials studied means.

Covering the entire open surface of the plates in the model of the dentition with a layer of plaque simulator increases the efficiency, safety, speed and accuracy, since it eliminates the infection of researchers, provides round-the-clock availability of biomaterial in the laboratory, ready for application of plaque simulator on the surface of the plates, standardizes the conditions for screening, increases the accuracy and repeatability of the results, and also allows you to find funds with very high efficiency, allowing you to clean the surface of the teeth when it is completely covered with artificial food coating.

The registration of light intensity, carried out immediately before, immediately after applying the biomaterial to the entire area of the open surface of the plates and immediately after the completion of the irrigation process with a solution of the studied agent, which is preliminarily poured into the capacity of the irrigator for the oral cavity at a temperature of +43 - + 65 ° С filling the container and then applying it for 2 minutes on the surface of all plates, increases safety, speed, accuracy and expands the scope, because it standardizes research, provides screening of cleaning agents in a short period of time, ensures repeatability of the results and increases safety of its use. At the same time, recording the intensity of light passing through 4 plates 4 increases the accuracy, since it provides the sum of the light flow delay of each of the 8 surfaces of the wide sides of the plates, which allows to reveal minimal traces of their contamination due to an almost 8-fold increase in the sensitivity of the method. Therefore, the claimed method provides the identification of minimal traces of an almost transparent biomaterial that cannot be detected when light is transmitted through only one layer of biomaterial, covering only one surface of the plates.

The registration of light intensity, carried out each time immediately before applying the biomaterial to the surface and immediately after the completion of the irrigation of the plates with the solution of the test agent, increases the speed, efficiency and accuracy, since it provides screening results in a short time from the start of the laboratory experiment. The fact is that the data on the severity of the cleaning activity depend on the duration of the irrigation of the plates with the solution of the studied agent, and the data on the initial transparency of the plates (control data) before and after applying biomaterial to them depend on the size of the time interval that separates the moments of the studies from each other . This is due to the fact that the degree of transparency of the model dentition and plaque simulator covering the surface of the plates varies depending on the period of time separating one study from another, on humidity, room temperature and atmospheric pressure. In turn, the values of humidity, temperature and atmospheric pressure are variable hourly and daily, and are cyclical in nature. Moreover, the importance of these factors affects the physicochemical properties of all living and non-living objects, including the transparency of biomaterial and quartz glass. Therefore, when screening funds for the proposed method, you should irrigate the surface of the plates with a solution of the studied funds for 2 minutes. This increases the efficiency, accuracy and speed, because it standardizes the study and ensures the use of the entire volume of the solution of the studied drug, poured into the capacity of the household oral irrigator.

On the other hand, a study of the degree of transparency, carried out in laboratory conditions immediately before applying the biomaterial, immediately after applying the biomaterial to the surface of the plates and immediately after the end of the irrigation process of the model dentition with the solution of the studied agent, ensures high speed and standardization of the screening technology, as well as approximates the evaluation conditions the cleansing activity of the product to the conditions of its use in everyday life for cleaning natural teeth in consumers. The fact is that in everyday life, the surface of the teeth in the oral cavity is currently being cleaned using an oral irrigator, which has a standard capacity for a certain volume of a solution of a dental cleaner and a standard power of a water pump that determines the standard flow rate of a cleaner solution. At the same time, the safest and most effective period of irrigation of teeth (that is, the optimal duration of local interaction) lasts no more than 2 minutes. That is why it is proposed to irrigate the surface of the plates of the laboratory model of the dentition with a solution; studied funds for the maximum possible period, namely - for 2 minutes.

The use of a solution of potential cleaning agent heated to a temperature of +43 - + 65 ° C increases the speed, efficiency and accuracy, since according to the Arrhenius law hyperthermia increases the speed of all chemical and physico-chemical processes, including the process of physical melting, chemical dissolution and physico-chemical loosening thick plaque, pus, as well as clots and blood stains and food debris. By heating the claimed agent to a temperature of +43 - + 65 ° C, the optimal value of the local temperature of the agent is ensured when it is thrown from the tip of the irrigator onto the cleaned surface of the dentition model. The indicated temperature range enhances the cleaning activity of the product, accelerates the cleaning process of selected surfaces and accelerates the identification of the cleaning effectiveness of the drug, and at the same time eliminates thermal burns of soft tissues of the oral cavity, pharynx and esophagus.

The selected temperature range is optimal because it corresponds to a safe, but effective temperature range of dental cleansers at home. The fact is that when the warm solution of the cleaning agent is poured into the capacity of the irrigator, the solution gradually cools due to the transfer of part of its heat to the elements of the irrigator having room temperature. In this case, the minimum value of the indicated temperature range is justified by the need to keep the product warm at the time of throwing the tip of the irrigator onto the selected surface. In other words, the minimum temperature in the claimed tool is justified by the need to maintain its "working" temperature in the range exceeding the level of + 37 ° C, since when throwing the solution out of the irrigator with a temperature of + 43 ° C, the solution flows inside the parts of the irrigator before it leaves the tip The irrigator is cooled at 6 ° C, since all working parts of the irrigator are colder and have room temperature. The maximum temperature value of the solution of the studied drug is justified by the need for temperature enhancement of the whitening activity of the drug and increase the efficiency of plaque removal with the simultaneous absence of the cauterizing effect of the claimed agent on soft tissues of the oral cavity in case of the introduction of heated liquid by mistake directly into the oral cavity. At the same time, the maximum temperature of liquids, which is still thermally safe for soft tissues of the oral cavity, pharynx and esophagus, does not exceed + 65 ° C (http://nastroenie.tv/episode/109118. Found on the Internet on April 23, 2019).

The results of our studies showed that the maximum temperature range indicated by us for the studied drug does not cause thermal damage to the soft and hard tissues of the oral cavity because, if the liquid is ejected from the tip of the irrigator, it cools from the initial temperature level in the tank of the irrigator + 65 ° C to a temperature of + 51 ° C.

The use of oat jelly at a temperature of +60 - + 65 ° C and fresh infusion of black tea leaves at a temperature of + 25 ° C as a biomaterial for simulating plaque increases the speed, safety and accuracy, since it excludes infection of researchers with infectious diseases, a long wait for the process to complete draining excess jelly from the surface of the plates, standardizes the screening technology, ensures the independence of screening from the presence of laboratory animals and human volunteers. The proposed temperature range of jelly provides the optimal performance of its enveloping properties necessary for enveloping the entire surface of the plates in the dentition model and the subsequent removal of excess jelly from the surface of the teeth under the force of gravity. In turn, the proposed temperature of the infusion of tea leaves and the priority of its application ensures standardization, research accuracy and eliminates the dissolution (softening) and washing off of jelly from the surface of the plates. The use of the infusion of black tea leaves increases the sensitivity of the method, since the infusion, by means of astringents having a dark brown color, covers the surface of the plates with a colored film and paints them in brown, which increases the light delay.

In addition, the use of oatmeal jelly and fresh infusion of tea leaves standardizes the technology, eliminates the use of low-quality products and brings artificial quality plaque in the model of the dentition closer to natural plaque in many people. In addition, the proposed plaque simulator is similar in composition to fresh plaque, most often covering teeth in most people daily after breakfast, since so many people on the planet eat warm oatmeal in the morning and take a cup of tea for breakfast.

Coating the surface of the plates by completely short-term immersing them for 1-2 seconds, first in the infusion, then in the kissel, after each immersion, placing the dentition model in the position with the plates down, waiting in this position for the completion of the process of draining excess biomaterial from them, blowing off the surface of the plates using a household hairdryer with a stream of dry air at room temperature up to the seal determined on the eye and turning it into a film that is firmly glued to the surface of the plates, it increases efficiency, accuracy, speed and safety, since it ensures that screening is independent of the need for people and / or animals with natural teeth coated with natural plaque, and also provides repeatability and reliability of the results of screening, as it standardizes the technology of applying a plaque simulator on the surface of the plates of the dentition model in laboratory conditions.

Placing the dentition after this model in the sink in such a position in the space in which it is placed with the plates up, fixing the model in this position and in this position irrigating the surface of the plates with the solution of the studied drug increases the accuracy, as it standardizes the method of screening for dental cleaners.

The method is as follows. If it is necessary to screen several compounds that pretend to be dental cleaners, they use a pre-made laboratory model of the dentition, a light source and a photosensor from an oxyhemograph sensor or other similar ones, as well as an ammeter, fresh brewed infusion of black tea leaves, boiled oat jelly, and aqueous solutions studied products with working concentrations of ingredients and an oral irrigator. Pre-made laboratory model of the dentition, made in the form of a comb having 4 teeth, which are plates made of transparent and colorless quartz glass, placed perpendicular to the surface of the base in one row and across its center line. All plates are firmly fixed with narrow edges in a row on a common base in the form of teeth of a comb with gaps of 2 mm. Moreover, each plate has a thickness of 2 mm, a width of 4 mm and a height of 10 mm. The light source and the photosensor are installed and fixed in a position opposite each other at a distance that ensures placement of the dentition model between them for transmission through the rays from the light source of all the plates simultaneously. In this case, the photosensor is connected to a highly sensitive ammeter by electric wires. First, using the light source, photosensor and ammeter, the intensity of light passing through all the plates is determined by the current strength that appears in the photo sensor in control, namely, before applying a plaque simulator and the studied funds on the model plates. Measurement of the transparency of the model is carried out in complete darkness. To darken, you can cover the model with a light source and a photosensor as a whole with a flap of opaque black fabric. After measurement, the model of the dentition is removed and immersed for 1-2 seconds in a fresh infusion of black tea leaves at a temperature of + 25 ° C, then the model is removed from the infusion, placed with the plates down and in this position they are waiting for the completion of the process of draining excess infusion from them. Then, the surface of the plates is blown with a stream of dry air at room temperature with a household hair dryer, up to the densification of the remnants of the infusion determined by the eye and turning them into a film firmly glued to the surface of the plates. The field of this plate of the model is completely lowered for 1-2 seconds in oat jelly at a temperature of +60 - + 65 ° C, removed from it, placed with the plates down and in this position they wait for the completion of the process of draining excess jelly from them. Then, the surface of the plates is blown with a stream of dry air at room temperature with a household hair dryer, until the jelly residues are compacted on the eye and converted into a film firmly glued to the surface of the plates. Immediately after this, the intensity of the light passing through all the plates by the intensity of the current arising in the photo sensor is re-determined using a light source, a photosensor and an ammeter. The transparency of the model is measured in complete darkness, for which a model with a light source and a photosensor is covered with a flap of opaque black fabric. Then the model is taken out, placed on the bottom of the bath with the plates up, fixed in this position, and the plates are irrigated with a solution of the studied agent. Before this, the solution of the studied agent is poured at a temperature of +43 - + 65 ° C into the irrigator tank until it is completely filled, then the solution is applied using the tip of the irrigator for 2 minutes to the surface of all the plates. They analyze the results and give a conclusion about the ability of the studied means to quickly clean the surface of the simulator, plaque. After that, the surfaces of the dentition model plates are thoroughly cleaned, dried, and a similar study is repeated with another agent. Analyze the results and issue a conclusion.

Example. For the initial screening of the pharmacological activity of candidates for inclusion in the pharmacological group of dental express cleaners, 2 new chemical compounds were received, which received the laboratory name, respectively, Cl ₁ and Cl ₂ . All compounds are highly soluble in water, therefore, can be used as a solution for oral hygiene at a therapeutic concentration of 0.1-10%. In this regard, solutions were prepared that included separately 1% of each of the tested compounds. In parallel, we ordered and received from the factory laboratory a model of the dentition, in which 4 plates made of transparent and colorless quartz glass with a thickness of 2 mm, a width of 4 mm and a height of 10 mm, installed with narrow ends on a single base in a row across him and perpendicular to the surface of the base parallel and mirror to each other with 2 mm intervals, as well as an ammeter, a mini white light emitter and a photosensor from the oxyhemograph sensor, they prepared oat kissel and infusion of black tea leaves and purchased an irrigator for the oral cavity. After that, the emitter and photosensor were installed on a flat surface in a position opposite each other at a distance exceeding 5 mm the size of the working part of the dentition model, the electrical wires from the photosensor to the ammeter were connected, the dentition model was placed between the emitter and the photosensor at a distance of 2.5 mm from the surfaces of the outer plates, sheathed the resulting structure with a flap; of opaque black fabric, the light emitter and ammeter were turned on and the intensity of the light transmitted through all the plates was measured by the current strength that appeared in the photosensor before applying the plaque simulator and the studied funds on the model plates.

After that, the model of the dentition was immersed for 1 second in a fresh infusion of black tea leaves at a temperature of + 25 ° C, then the model was removed from the infusion, placed with the plates down until the excess infusion was drained from them. Then, the surface of the plates was blown with a stream of dry air at a temperature of + 25 ° C using a household hair dryer, until the infusion was detected by eye and turned into a film that was firmly glued to the surface of the plates. The field of this model, the plates were completely lowered for 2 seconds into oatmeal jelly at a temperature of +60 - + 65 ° C, they were taken out of it, the model was placed with the plates down, held in this position until the excess jelly was drained from them, and then the surface was blown off plates with a stream of dry air at a temperature of + 25 ° C using a household hair dryer up to the thickening of jelly residues determined by eye and turning them into a film that is firmly glued to the surface of the plates. Immediately after this, a dentition model with a plaque simulator was placed between the light emitter and the photosensor at a distance of 2.5 mm from the outer plates, the created structure was covered with a flap of black opaque fabric, the light emitter and ammeter were turned on, and the intensity of the light transmitted through all the plates was determined by the strength of the current arising in the photo sensor. Then the model of the dentition was removed, placed on the bottom of the sink in the bathroom with the plates up, fixed in this position, and the model plates were irrigated with a solution of Cl ₁ using the tip of the irrigator. Before this, the solution of the studied Cl ₁ agent at a temperature of +43 - + 65 ° С was poured into the capacity of the irrigator until it was completely filled. We carried out an analysis of the results obtained, which testified to the ability of the studied agent to quickly and almost completely clean the surface of the plates from the plaque simulator available on it. After that, the surfaces of the plates of the dentition model were thoroughly cleaned using sanitary-hygienic means, dried and a similar study was repeated with a solution of Cl ₂ .

As a result, the following results were obtained. The plates in the dentition model before applying the plaque simulator and solutions of the studied compounds in both cases were transparent and freely passed light from the emitter with the same intensity, which was taken as 100%. The surfaces of the dentition model plates after applying a thickened infusion of black tea leaves and oat jelly on them in the first and second application of the method looked dirty and completely covered with gray-light yellow films. The intensity of the light passing through them decreased in the first and second cases by 17% and 18% (respectively) compared to the initial values. After irrigating these plates for 2 minutes from the tip of the irrigator with a warm solution of compound Cl _{1, the} surfaces of the plates looked almost cleaned, and the intensity of the light passing through them was 4% lower than the initial value. At the same time, after irrigating these plates for 2 minutes from the tip of the irrigator with a warm solution of compound Cl _{2, the} surfaces of the plates looked dirty and completely covered with gray films. At the same time, the intensity of light passing through them was 12% lower than the initial value.

Therefore, a single irrigation with a solution containing 1% of the compound with the laboratory name Cl ₁ , the surfaces of the plates of the model dentition, covered with a plaque simulator, provides a highly effective express cleansing of fresh plaque. Therefore, a solution containing 1% of the compound with the laboratory name Cl ₁ has the pharmacological activity characteristic of dental cleaners. In this regard, it is advisable to continue the study of the pharmacological activity of this agent.

On the other hand, a single irrigation with a solution containing 1% of the compound having the laboratory name Cl _{2 of the} surfaces of the dentition plates coated with a plaque simulator does not provide an urgent effective cleansing of them from fresh food * plaque, that is, it does not have the pharmacological activity characteristic for dental cleaners.

Thus, the proposed method improves the efficiency, speed, accuracy, safety and expands the scope of application due to the use of a laboratory model of transparent incisors of an adult, coating their surfaces with a simulator of food plaque and quickly obtaining information about their total transparency before, immediately after applying food plaque and immediately after completion of the process of surface irrigation with the solution of the test compound using the tip of the irrigator. The method provides rapid screening of compounds in the absence of vivarium with experimental animals, volunteers, as well as in conditions that exclude infection of researchers and the development of local irritation and inflammation of the soft tissues in the oral cavity of patients.

List of references:

1. Urakov A. L., Urakova N. A., Nikityuk D. B., Fisher E. L., Chernova L. V., Al-Hassaun X. Bleeding bleaches. New pharmacological group of drugs. The successes of modern science. 2015. No1. S. 1102-1107.

2. Urakov A.L., Urakova N.A., Lovtsova L.V., Sorokina Yu.A., Kasatkin A.A., Baimurzin D.Yu. A method for screening bleach bleach. RUS Patent No. 2634268. Applicant Urakov Aleksandr Livievich. Application No. 2016118126, declared 05/10/2016, publ. 10.24.2017. Bull. No. 30.

Claims (1)

A method for screening dental cleaners based on comparing the transparency of a laboratory model before and after exposure to a test agent by determining with ammeter in dark conditions the electric current in the photosensor from an oxyhemograph sensor when light emitted from a white mini-emitter passes through it biological material and plates made of colorless transparent quartz glass in the form of rectangular even flat sheets mounted on the base with wide planes parallel and mirror-like to each other at certain intervals, and on the analysis of the results obtained, which assume that the decrease in the photocurrent strength indicates increasing the content of biomaterial that absorbs light, characterized in that 4 plates are firmly fixed with narrow ends on a common base in one row across and perpendicular to the surface of the base with 2 mm intervals, each plate has a thickness of 2 m m, a width of 4 mm and a height of 10 mm, the light intensity is recorded immediately before, immediately after applying the biomaterial to the entire area of the open surface of the plates and immediately after the completion of the irrigation process with a solution of the studied medium, the solution of the studied medium is poured at a temperature of +43 - + 65 ° С into the container of the irrigator for the oral cavity until the container is filled and then the solution is applied using the tip of the irrigator for 2 minutes to the surface of all the plates, as a biomaterial use fresh infusion of black tea leaves at a temperature of + 25 ° C and oat jelly at a temperature of +60 - + 65 ° C, the plates are immersed completely alternately for 1-2 seconds, first in the infusion, then in the jelly, after each immersion, the dentition model is placed with the plates down and in this position they are waiting for the excess material to drain off from them, then the surface of the plates is blown with using a household hairdryer with a stream of dry air at room temperature to determine the thickening of liquid bio materials until they are turned into a film that is firmly glued to the surface of the plates, then the model is placed in the sink, in which it is placed with the plates up, fixed in this position and irrigated by the solution of the studied tool, analyze the results and give an opinion on the ability of the studied tool quickly clean tooth surfaces from plaque simulator, if necessary, reapply the method, the surfaces of the plates are cleaned to full cleanliness, dried and the method is reused with the same or other means, analyze the results and issue a final conclusion.