JP2002500055A - Root canal irrigation medium - Google Patents

Abstract

  (57) [Summary] Use of a fungicide in root canal treatment to reduce the growth of bacteria and other microorganisms remaining in the root canal after occlusion.

Description

DETAILED DESCRIPTION OF THE INVENTION

INTRODUCTION AND BACKGROUND OF THE INVENTION The present invention relates to the use of fungicides in root canal therapy to inhibit the growth of bacteria and other microorganisms remaining in the root canal after occlusion. Sodium hypochlorite is widely used as a fungicide for root canal irrigation, and its primary role in root canal treatment is dissolution and lubrication of fungicides, organic materials.
However, the drawback of sodium hypochlorite is that it is quite harmful to human tissues and cells when concentrated, and even at the most effective concentration as an irrigation solution, it is fatal That is the case.

OBJECTS OF THE INVENTION It is an object of the present invention to provide a new, relatively inexpensive and safe root canal irrigation solution.

[0003] According to the abstract the first aspect of the present invention, the use of aqueous solutions for irrigating solution preparation for use in root canal treatment is provided, characterized in that the aqueous solution is electrochemically active . The electrochemically active aqueous solution can consist of an aqueous solution containing anions and / or cations. The aqueous solution containing anions and / or cations can be prepared by electrolyzing an aqueous solution of a salt. The salt can be sodium chloride. In particular, it can be non-iodinated sodium chloride or potassium chloride.

[0004] Anion-containing and associated cation-containing solutions can be made by electrochemical reactors or so-called electrolyzers. Hereinafter, the anion-containing solution is simply referred to as “anolyte”, and the cation-containing solution is hereinafter referred to as “catholyte”. The anolyte and catholyte comprise a through flow and an electrolytic cell having a diaphragm provided to divide the two coaxial electrodes and the annular electrode space between them into a cathode compartment and an anode compartment. Preferably, it is made from an electrochemical reactor.

The anolyte can be made by electrolyzing a 10% aqueous solution of NaCl in the anodic chamber to form an active or excited aqueous solution containing many free radicals. This anolyte has an extremely high oxidation-reduction potential up to about +1170 mV and a p-value of about 2-7.
Has an H value. These activated radical species are unstable and after about 96 hours many radical species will disappear without leaving any residue.

The anolyte is an active radical species such as ClO, ClO ⁻ , HClO, OH ⁻ , HO ₂ ⁻ , H ₂ O ₂ , O ₃ , HO ⁻ , S ₂ O ₈ ²⁻ and Cl ₂ O ₆ ^−. Can be included.

[0007] Active radical species have been found to generally have a synergistic antibacterial and / or antiviral effect that is stronger than the effect of chemical disinfection, and that viral organisms, spores and cyst-forming bacteria (Enterococus faecalis) And Gram-positive and Gram-negative bacteria such as Pseudomonas aeruginosa).

[0008] The catholyte can generally have a pH of about 7-13 and a redox potential of about -980 mV. Catholyte is NaOH; KOH; Ca (OH) ₂ ; Mg (OH
^{_{) 2; HO -; H 3}} O 2 -; HO 2 -; H 2 O 2 -; O 2 -; OH -; O 2 2- active radio local species such as may include.

[0009] The active acid radical species or free radicals present in the anolyte act synergistically as biocides and virus killers at the bacterial cellular level, while the active acid radical species or free radicals present in the catholyte are present. Is believed to act synergistically as a cleaning agent, dissolving the organic material or biofilm that protects or coats the bacteria and dissolves itself with the bacteria.

The effect of the use of anolyte and / or catholyte in the preparation of an irrigation solution for the treatment of root canals depends on the concentration of anolyte and / or catholyte (oxidation-reduction potential of anolyte and / or catholyte ( ORP), ie, as measured by redox potential), exposure time (ie, contact time of the root canal with the anolyte and / or catholyte) and temperature during application. The anolyte has been found to be more effective at relatively low temperatures than at relatively high temperatures.

According to a second aspect of the present invention there is provided an irrigation solution for irrigating a root canal, wherein the irrigation solution comprises an aqueous solution substantially as defined above.

According to a third aspect of the present invention there is provided a method for irrigating a root canal comprising applying an electrochemically active aqueous solution to the root canal as defined below. Is done.

DETAILED DESCRIPTION OF THE INVENTION In a root canal irrigation method, first, a catholyte solution is applied to a root canal for the purpose of removing an organic biofilm or residue (debris) covering the inner wall of the root canal, and then applying a cathodic solution to the root canal. An anolyte is applied to the root canal to disinfect the inner wall of the canal and the inner canal of the tooth.

[0014] will be described with reference to non-limiting examples a preferred embodiment the two embodiments invention.

Example 1 Twenty single-rooted teeth, freshly removed from a patient's mouth, were collected from the Department of Oral and Maxillofacial Surgery, University of Pretoria, Dept. of South Africa.

1.1 Trial The extracted teeth were rinsed with running drinking water and stored for 24 hours in a sample bottle filled with distilled water. The tooth pulp chamber was entered using the fisher bar of the turbine handpiece and the round bar of the contra-angle handpiece. A No. 15 K-type root canal file was then placed in each root canal to ensure the patency of the root canal. The exact length of each root canal was measured by placing a file in the root canal until its tip just came out of the apex. The silicone rubber fastener previously fitted to the file shaft was moved to the crown-side reference point (the intact location of the tooth).

The file was pulled out and the distance from the tip of the file to the silicon fastener was recorded. The working distance was calculated by subtracting 1 mm from the distance measured for each tooth. Gates Glidde, a contra-angle handpiece, for one third of the coronal side for all root canals
Pre-spread using n bars. At this stage, the twenty teeth were randomly divided into two groups of ten. Group A is for washing with a conventional sodium hypochlorite solution, and group B is for washing with the electrochemically activated solution (STEDS) of the present invention.

Group A (Sodium Hypochlorite) Root canal formation in Group A is performed by manually using a set of K-type files (15-60 size) and adding 2.5% sodium hypochlorite solution. The cleaning was performed by using an ultrasonic unit such as a so-called Cavi-Endo (Dentsply) unit. Washing was performed using the same ultrasound unit for at least 10 seconds after each use of each size file.

After forming the root canal to size 60, a final wash was performed for 30 seconds. The washing operation was performed using at least 150 ml of a 2.5% sodium hypochlorite solution per tooth.

Group B (Electrochemically Activated Liquid “STEDS”) STEDS was made in a specially made electrochemical reactor. The reactor consists of a through flow and an electrochemical cell consisting of two coaxial cylindrical electrodes and a coaxial partition present between them and dividing the annular interelectrode space into a cathode compartment and an anode compartment. ing. The STEDS produced is two separate solutions, a catholyte and an anolyte. The anolyte has a pH of about 7.4 and an oxidation-reduction potential of about +1170 mV
The catholyte had a pH of about 9.5 and an oxidation-reduction potential of about -980 mV. The root canal of group B was washed with these solutions. The root canal was formed by the same procedure using a file of the same size and type as in Group A. First, the root canal was washed with the catholyte using the same ultrasonic unit as that of the group B. Each time each size file was used, the root canal was rinsed with anolyte for at least 10 seconds.

After forming to size 60, a final wash was performed using catholyte for 30 seconds. A minimum of 100 ml of anolyte and 50 ml of catholyte were used per tooth.

Immediately after the above forming and cleaning operations, the teeth were again stored in distilled water for 24 hours.
A specimen (about 2 mm x 2 mm) of the root canal wall of the central third of the root canal was prepared. Specimens were handled with rocking forceps throughout the process to prevent human contamination. The specimen was placed in a dust-free incubator and air-dried for 10 days.

The air-dried specimen was mounted on a metal substrate with a conductive adhesive, covered with gold, and observed at various magnifications using a scanning microscope. The amount of residue remaining on the root canal wall was compared by recording the residue on the surface of 20 representative samples of each group.

1.2 Result The residual residue of the group B was very small. In group A, a small but noticeable amount of residue was found on the surface of many specimens. In group B, it was observed that in group A, the so-called smear layer present in all samples was extensively removed.

Under the conditions of this experiment, STEDS is superior to sodium hypochlorite as an irrigation solution. STEDS removed a significant amount of residue from the formed root canal wall surface.

[0026] 2. Example 2 2.1 Trial A root canal was formed in the same manner as in Example 1 for 69 extracted teeth. The teeth were then sterilized by autoclaving and the following microorganisms, E. coli: faec
alis, P .; aeruginosa and S. aeruginosa. Mutant overnight broth cultures with 1.0 ml were placed under sterile conditions in 200 ml of BHI (brain-heart infusion) liquid culture medium. The teeth were kept in this broth for 7 days in a 37 ° C incubator.

On the last day of the seven days, the teeth were removed from the broth with a pair of sterile forceps. Until this period the bioburden was expected to be quite high, and colony counts were performed on the broth with serial 10-fold dilutions in triplicate. Aliquots (100 μl) of the dilutions were placed on a 10% blood agar plate and spread on the plate surface with a sterile metal spreader. After overnight culture at 37 ° C., the plates were counted and the number of colony forming units (cfus) was evaluated.

The teeth were washed with 100 ml of normal saline in a sterile bottle, repeated four times to remove the mixed saline, and washed with fresh saline added. This approach reduced the bioburden to a level at which the technician performing the procedure was not likely to develop infection from the spray aerosol.

The teeth were placed in a sterile microtiter tray with the root canal opening side up. Before treatment, the root canal opening of all teeth was made with a syringe using 50 ml of sterile water.
Washed "irrigated" for minutes. This is similar to hand irrigation in dental surgery. The teeth were then inverted for a few seconds to drain most of the water. The teeth were then divided into different groups for various treatments.

Three groups of twenty teeth each were made with three individual teeth serving as catholyte control groups and six other teeth for a full tooth test.

In Group A (negative control), all root canals were irrigated with saline for 5 minutes using a sharp tuberculin syringe. Then, 30 μl of physiological saline was aspirated from the root canal, serially diluted, spread on a 10% blood agar plate, and cultured at 37 ° C. for 24 hours.

In group B, 20 teeth were similarly treated with sodium hypochlorite for 5 and 10 minutes, respectively. After 5 minutes, and after another 10 minutes, the root canal was filled with saline, then 30 μl of saline was aspirated, diluted, plated, and cultured.

In group C, all teeth were first treated with catholyte for 5 minutes. afterwards,
The catholyte was washed off with the anolyte. The teeth were then treated with the anolyte for 5 and 10 minutes, respectively. On the last day of the period, samples were taken from the root canal using saline and using a similar culture method.

The full tooth test was performed on six teeth, as described above. Two teeth were stored in sodium hypochlorite and cultures were harvested after 5 and 10 minutes. The two remaining teeth were stored in catholyte, washed with anolyte and stored. Cultures were harvested after 5 and 10 minutes storage times.

2.2 Results 2.2.1 Basal Counts The broth cultured for 7 days with frequent addition of fresh medium contained 4.4 × 10 ¹⁰ cfu. The average number of microorganisms present in the root canal treated only with saline is 1.4 ×
Was 10 ⁶ cfu. The reason for such high counts is that most microorganisms were hidden behind as biofilms. An unexpected fact was that after catholyte treatment (no anolyte), the count increased to 2 × 10 ⁷ cfu. This is probably because the catholyte lifted the biofilm off the surface so that it was known to act like a surfactant.

2.2.2 Test Product

[Table 1]

2.2.3 Whole tooth count When teeth were treated with sodium hypochlorite alone for 5 minutes, the average count was 4
× 10 ² cfu. When left for 10 minutes, the count dropped to zero.

When only the anolyte is used (no pretreatment with the catholyte), the average count is 1.2
× 10 ⁵ However, when exposed to the catholyte and washed, and then treated with the anolyte for 10 minutes, the count dropped to zero.

From this in vitro test, it was found that the anolyte was very effective in eliminating floating and epiphytic microorganisms attached to the tooth surface.

It is important to use the catholyte first and then wash away the catholyte and the lifted biofilm in order to really improve the effect using the anolyte.

Without departing from the scope and / or spirit of the invention as defined by the appended claims,
It should be understood that many small variations are possible.

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Claims (10)

[Claims] 1. Use of an aqueous solution in the preparation of an irrigation medium for use in root canal treatment, wherein the aqueous solution is electrochemically activated. 2. The use according to claim 1, wherein the electrochemically activated aqueous solution comprises an anion-containing aqueous solution and a cation-containing aqueous solution. 3. The use according to claim 1, wherein the aqueous solution containing anions and the aqueous solution containing cations are prepared by electrolyzing an aqueous solution of a salt. 4. An anion-containing solution and a cation-containing solution comprising a through-flow electrochemical cell having two coaxial electrodes and a coaxial diaphragm separating the electrodes into a cathode compartment and an anode compartment, separating the annular interelectrode space. Use according to any one of the preceding claims, characterized in that it is made by an electrochemical reactor. 5. The anion-containing solution is made from a 10% aqueous solution of NaCl and electrolyzed to produce activated or excited radical cation species and radical anion species. Use according to any one of the preceding claims, characterized in that it has an extremely high redox potential up to +1170 mV. 6. The anion-containing solution has a pH of about 2-7, and about +1170 mV.
Use according to claim 5, characterized in that it has a redox potential of 7. The cation-containing solution has a pH of about 7 to 13, and about -980.
6. Use according to claim 5, characterized in that it has a redox potential of mV. 8. An irrigation medium for irrigating a root canal, wherein the irrigation medium comprises an electrochemically active saline solution. 9. A method for irrigating a root canal, comprising the step of applying a saline solution, which has been electrochemically activated for the purpose of irrigating the root canal. 10. First, a cation-containing solution is applied to the root canal to remove an organic film and residue (debris) covering the inner wall of the root canal, and then the inner wall of the root canal and the inner canal of the tooth are removed. The method of claim 9, comprising applying an anion-containing solution to the root canal for disinfection.