RU2707502C1 - Method for complex treatment of root canal system in treating inflammatory diseases of pulp - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to dentistry, and can be used in treating inflammatory diseases of pulp. Proposed method for complex treatment of root canal system in treating pulp inflammatory diseases involves the following stages of root canal treatment: sodium hypochlorite solution with concentration 0.5–1.0 % and volume 1–15 ml; photodynamic therapy with ultrasonic activation of the photosensitiser; distilled water; aqueous solution of chlorhexidine with concentration of 0.12–1.0 % and volume of 1–20 ml; wherein all processing steps are carried out with ultrasound activation with frequency of 20–40 kHz and observing time intervals of not more than 3 minutes, taking into account that each treatment step is performed for 3 to 10 minutes.

EFFECT: technical result: providing high quality of treatment, providing reproducible results of drug-induced treatment with certain quantitative use of components of solutions and certain conditions of carrying out and a certain sequence of stages of drug-induced treatment, which excludes a degree of negative effect of preparations.

1 cl, 1 ex

Description

The invention relates to medicine, namely to dentistry and can be used in the treatment of inflammatory pulp diseases.

Complications of dental caries (pulpitis and periodontitis) make up more than a third of the volume of dental diseases and are one of the main causes of tooth extraction. The objectives of endodontic treatment are to eliminate the maximum number of bacteria, dissolve the lubricated layer and prevent re-infection. Endodontic canal treatment remains the main stage in the complex treatment of pulp diseases, and the long-term results of treatment directly depend on how this stage is carried out (Mitronin A.V., Chunikhin A.A., Mitronin V.A., Basova A.A. , Abaev Z.M. Modern technologies in endodontic treatment.Medical alphabet, 2014. V. 3. No. 13. P. 40-43.). The ideas that have developed in dental science about the morphology of tooth pulp, the physiological and pathophysiological processes taking place in it, allow you to take a fresh look at treatment methods, forcing you to find more and more rational solutions.

So, modern methods for identifying pathogenic microorganisms have allowed us to learn more about the composition of the microflora of infected channels, which has contributed to increasing the effectiveness of disinfection. In the rapidly developing technologies of aerobic and anaerobic cultivation of bacteria, researchers unanimously agree that the complications of dental caries are polybacterial in nature. Among the pathogens colonizing the root canals, gram-negative obligate-anaerobic bacilli of different taxonomic groups are distinguished, as well as microaerophilic streptococci. (Tsarev V.N., Mamedova L.A., Siukaeva T.N. Influence of modern endodontic technologies on root canal treatment in the treatment of apical periodontitis. Endodontics Today, 2016. No. 4. P. 39-45.).

Most specialists rightly consider disinfection of the root canal system to be the most important stage of endodontic treatment. The main drug used for root canal irrigation is sodium hypochlorite. The antimicrobial effectiveness of a solution arises due to its ability to oxidize and hydrolyze cell proteins, and, to the same extent, osmotically draw liquid from cells due to its hypertonicity [RU 2158123 C2, Barer GM, 10.27.2000]. The effectiveness of sodium hypochlorite and its ability to dissolve tissues to a certain extent depends on the concentration of the solution. (Clegg MS. Et al, 2006). However, with an increase in the concentration of the drug, not only its activity increases, but also cytotoxicity, which can lead to certain side effects, such as tissue necrosis, pain, swelling when concentrated solution enters the periapical tissues or on the oral mucosa. Therefore, at present there is no consensus on the issue of the optimal concentration of sodium hypochlorite for use in endodontics, and the required amount of the solution used in processing one channel to obtain reproducible results has not been unambiguously determined. Also, sodium hypochlorite, acting for a short time, is not able to penetrate deeply into the tooth tissue, which reduces its activity against microorganisms located in the dentinal tubules [Risovanny SI, Risovannaya ON, Bychkova NP Treatment of periodontitis with the use of bacteriostatic light therapy // Kuban Scientific Medical Bulletin. 2006. No. 5-6. S. 24-27].

An effective antimicrobial agent for root canal irrigation is a chlorhexidine solution [RU 2322276 C2, GOUVPO Samara State Medical University of Roszdrav, 04/20/2008]. It is a cationic biguanide with optimal antimicrobial activity in the pH range from 5.5 to 7.0. Active against a wide range of microorganisms, such as gram-positive and gram-negative bacteria, bacterial spores, lipophilic viruses, yeast fungi. The mechanism of its action is associated with the adsorption of the solution to the wall of the microorganism, which causes leakage of intracellular components. Bacteriostatic in low concentrations, bactericidal in high. However, at the same time, its cytotoxic effect is noted. Chlorhexidine was found to have the same toxicity to both microorganisms and cultured human cells. In domestic dentistry, a 0.05% solution is used, according to foreign literature, 0.2-2% solutions are recommended for use. Experimental and clinical studies have established that the antimicrobial effect of a 0.2% chlorhexidine solution is similar to a 0.5% sodium hypochlorite solution, and 1-2% chlorhexidine gels and gels have the ability to stop growth and eliminate Enterococcus faecalis from root canal and dentin [Basrani, B. Chlorhexidine gluconate / B. Basrani, C. Lemonie // Aus. Endod. J.2005. Vol. 31. P. 48-52.]

Based on the foregoing, dentists are actively seeking alternative and combined methods of endodontic treatment to ensure effective removal of the microbial factor, as well as reduce the toxic effect on tissues. So, photodynamic therapy (PDT) is increasingly being used to disinfect root canals in the treatment of dental caries complications. PDT can be used primarily against pathogenic and conditionally pathogenic bacteria, which are the main cause of inflammatory processes that have developed as complications of caries. This method is based on the use of various photobiological effects caused by the combined use of light radiation, reactive oxygen species (ROS) and a photosensitizer (PS). But the outcome of this therapy may be different, depending on the intensity of ROS generation, the activity of antistress proteins, antioxidant enzyme systems of bacteria, and also on the anatomical structure of the root canal system. Combining a controlled bacteriotoxic effect on the inflammation site, activated by laser light in the presence of a photosensitizer, this method has a biostimulating effect and increases the effectiveness of endodontic treatment. [Drawn S.I., Drawn ON, N., Bychkova N.P. Treatment of periodontitis with the use of bacteriostatic light therapy // Kuban Scientific Medical Bulletin. 2006. No. 5-6. S. 24-27]

Internal tooth morphology is extremely complex and diverse, and even today, having extensive information about the structure of the root canal system, endodontic treatment cannot always be performed efficiently, with a minimum of errors. (Plotino G., Pameijer S.N., et al., 2011). Perfectly round in cross section, the conical root canal with one apical opening is perhaps a rare exception than the rule. Various diameters, irregular shapes, numerous fins and undercuts - all these conditions significantly complicate adequate disinfection and mechanical processing, thereby creating favorable conditions for the development of intracanal infection. (John Rhodes, 2009). Many lateral tubules, which are also found in the area of bifurcations and trifurcations of multi-rooted teeth, depart from the main canal at various levels. Between the root canals there are numerous anastomoses and isthmuses, which are especially common, for example, between the mesial channels of molars of the lower jaw. (Plotino G. 2011; Ricucci D., Siqueira J.F, 2013)

It is considered proven that the use of ultrasonic activation of the irrigant in the process of root canal treatment is a more effective technique compared to the traditional manual processing method [Plotino G., Pameijer SN, Grande N.M., Somma F., 2007]. Experimental and clinical studies have shown that with the use of ultrasonic activation of the irrigant, not only the lubricated layer is effectively removed, but also due to the cavitation effect, the irrigation solution penetrates into hard-to-reach areas better despite the complexity of the root canal morphology. Also, an acoustic vortex flow that arises around the endodontic file during operation breaks up the root canal detritus into sawdust and heats the disinfectant solution, which significantly improves the quality of endodontic treatment and creates conditions for hermetic root canal obturation [Doktor Hol'ger Dennhardt, 2014].

The closest technical solution is the method of complex drug treatment of the root canal of the tooth, in which the treatment is sequentially using sodium hypochlorite concentration of 0.5-5.25 max. %, ozonized saline with a concentration of ozone in solution from 10 μg to 60 mg per liter, and treatment with chlorhexidine with a concentration of 0.12-2 max. % Ultrasound activation of the irrigant was used at all stages. [RU 2540512, Snegirev M.V., Rabinovich I.M. 02/10/2015].

The negative effect of ozone therapy on the body has not been sufficiently studied. Ozone has an indiscriminate interaction with the cells of the human body, thereby accumulating free radicals in tissues, it stimulates the process of damage and destruction of cellular structures. Also, ozone therapy is contraindicated in patients suffering from cardiovascular diseases and with endocrine disorders.

The known method gives good results when processing the root canals of the tooth, however, it does not give unambiguously reproducible results in the treatment.

The objective of the present invention is to remedy the above disadvantages.

The technical result of the claimed invention is the provision of high quality treatment, providing reproducible results of drug treatment with a certain quantitative use of the components of the solutions and certain conditions and a certain sequence of stages of drug treatment, which eliminates the degree of negative influence of drugs.

The problem is solved by the method of complex processing of the root canal system of the tooth in the treatment of inflammatory diseases of the pulp, including the following stages of root canal treatment:

- sodium hypochlorite solution with a concentration of 0.5-1.0% and a volume of 1-15 ml;

- photodynamic therapy with ultrasonic activation of the photosensitizer;

- distilled water;

- an aqueous solution of chlorhexidine with a concentration of 0.12-1.0% and a volume of 1-20 ml,

however, all processing steps are carried out when activated by ultrasound with a frequency of 20-40 kHz and observe time intervals of no more than 3 minutes, taking into account that each processing step is carried out from 3 to 10 minutes.

As our studies have shown, the high quality of endodontic dentistry largely depends on the chosen method of processing the root canals of the tooth

We have experimentally established that to obtain high quality treatment while ensuring reproducible results of drug treatment of the root canal system of the tooth, it is necessary to use a certain combination and sequence of processing steps.

During the preparation of hard tooth tissues by hand or machine tools, a microscopic layer forms on the surface of the dentin. This so-called “smeared layer” consists of pulp fragments, odontoblasts, weakly mineralized predentine, dentin. The lubricated layer is tightly connected to the channel wall by means of “lubricated plugs” immersed in the dentinal tubules. The thickness of the lubricated layer on the surface of the dentin of the root canal is from 1 to 6 μm, and the penetration depth into the dentinal tubules can reach 50 μm. [Malanyin I.V., Bondarenko I.S., Sumelidi A.P., Pavlovich O.A. The effect of the smeared layer on the penetration of infection into the dentinal tubules. Kuban Scientific Medical Bulletin, 2006. No. 5-6. S. 34-35.]. The use of the ultrasonic activation method of the photosensitizer allows, using the minimum frequencies, the ability to transport the photosensitizer to the lateral branches and anastomoses in the apical part of the canal, as well as to the dentinal tubules. Its penetrating efficiency depends on the flow rate of the FS. The higher the speed, the more efficiently the photosensitizer fills hard-to-reach areas in the root canals, which helps to increase the effectiveness of this technique. This effect is achieved due to the formation of many vortex flows, the fastest of which are observed at the top of a vibrating tool (microstreaming).

The method is illustrated by the following example.

Example

Patient M., born in 1991, turned to the outpatient department of the Department of Cariesology and Endodontics with complaints of pain from thermal and mechanical irritants of the tooth 2.6, which passed immediately after elimination. From the anamnesis it was found that previously the tooth was treated for tooth decay, but (according to the patient) was periodically ill. It has been objectively established that on the medial chewing surface of tooth 2.6 there is an old filling made of composite material with signs of violation of the marginal fit. The mucous membrane in the projection of the causative tooth is pale pink. Percussion and palpation are painless. EDI - 35 μA. On a targeted intraoral x-ray, a carious cavity is observed, which communicates with the tooth cavity, without changes in the periapical region.

Based on the clinical and radiological findings of the examination, the patient was diagnosed with K04.03 - chronic pulpitis of the tooth 2.6. An old filling was removed under local infiltration anesthesia, a carious cavity was prepared, an autopsy was performed, a tooth cavity was opened with access to the root canal system, and vital pulp was extirpated. Further, the root canal mouths were expanded, their working length was determined, and subsequent machining by hand and machine tools. After that, the root canals were processed according to the claimed methodology.

At the first stage, the root canal was treated with a sodium hypochlorite solution of 1% concentration, 1-15 ml per root canal, with ultrasound activation at a frequency of 20-40 kHz, with simultaneous ultrasound activation during tooth root canal irrigation, the second stage was performed with using photodynamic therapy with ultrasonic activation of a photosensitizer with a frequency of 20-40 kHz, the third stage was treated with distilled water and the fourth stage was treated using an aqueous solution of chlorhexide at a concentration of 1%, a volume of 1-20 ml per root canal when activated by ultrasound at a frequency of 20-40 kHz. Between these operations observed time intervals of the order of 1 minute.

The claimed algorithm for the integrated processing of the root canal system in the treatment of inflammatory pulp diseases using certain quantitative components of solutions and certain conditions for the execution of the method provides a high quality treatment protocol and its reproducibility.

Claims (6)

A method for complex processing of the root canal system of a tooth in the treatment of inflammatory pulp diseases, including the following stages of root canal treatment: - sodium hypochlorite solution with a concentration of 0.5-1.0% and a volume of 1-15 ml; - photodynamic therapy with ultrasonic activation of the photosensitizer; - distilled water; - an aqueous solution of chlorhexidine with a concentration of 0.12-1.0% and a volume of 1-20 ml, however, all processing steps are carried out when activated by ultrasound with a frequency of 20-40 kHz and observe time intervals of no more than 3 minutes, taking into account that each processing step is carried out from 3 to 10 minutes.