FR2926460A1 - Use of composition made of opal dispersed in thermofusible plastic polymeric material comprising polyethylene, polypropylene, polyacrylate and polymethacrylate, to introduce in canal cavity and also cavity created in tooth/implant - Google Patents

Abstract

Use of a composition made of opal dispersed in a thermofusible plastic polymeric material comprising polyethylene, polypropylene, polyacrylate and poly methacrylate, to be introduced in canal cavity and also a cavity created in a tooth or in an implant, is claimed.

Description

GB VI - FR PATENT OF INVENTION 10 15 NEW USE OF OPAL IN DENTAL SURGERY AND COMPOSITIONS THEREFOR 20 USE INOVAT 2 NEW USE OF THE OPAL IN DENTAL SURGERY AND THE COMPOSITIONS THEREFOR invention is addressed to the necessities of life and in particular to dental surgery. The invention is particularly directed to the problems of denture strength and occlusion stability by increasing the amount of compression material around the root in a safe and effective manner.

The present invention therefore proposes to solve the problem of dental mobility or weakness of implant integration by a method based on the migration of cells from the healthy bone to the site of the responsible cell deficit. of mobility. The cells migrate within the extracellular matrix. This is one of the processes necessary to immobilize the tooth or prosthesis (implant): The first step is to restore the cell population and subsequently to reconstruct the extracellular matrix and the ligaments of the dental cells. This newly formed extracellular matrix holds the cells in place and constitutes a contention material.

It has been found that tooth mobility affects a large number of patients of all ages but that mobility increases with age. This tooth mobility is increased by opportunistic microbial infections, it degrades the patient's comfort and reduces his life expectancy. Dental mobility disrupts chewing. It is currently reduced by difficult and cumbersome surgical techniques with weak and unsatisfactory results. Indeed, the placement of a prosthesis does not stop the process of gingival destruction and promotes the bacterial accumulation induced by the retention of food. Blocking is done using dental implants. Deep periodontal pockets are associated with tooth mobility. Cell migration causes a reduction in periodontal pockets. If it is desired to immobilize a tooth or abutment, it will be necessary to tighten the root of the tooth or implant in the jaw. This requires increasing the amount of material around the base of the tooth for the purpose of mechanically tightening it in the bone. In addition the contribution of cells will allow the reconstruction of the alveolos-dental ligaments destroyed by senescence, infection (necrosis), by trauma or by a degenerative process. In addition, this material helps to better structure the bone-implant interface.

Prior Art It has been shown that opal accelerates cell migration. (See French Patent Application No. 07- 04336 filed on 18/06/2007). The applicants have shown that the silicate, material of the opal is organized into spheres arranged in plan. During the synthesis in the laboratory, the spheres are sometimes arranged as in the natural state; most often the spheres are associated in the form of agglomerates. These agglomerates of spheres can, under certain conditions, emit an attractive signal from eukaryotic cells. The authors also found that the signal emitted by the opal passes through a number of materials such as ceramics (derived from alumina) and zircon can be used as a prosthetic material, better suited to the use of the opal as metals.

When a tooth becomes mobile, the nerve is very quickly damaged because the slough through which it passes from the pulp to the bone through the root is extraordinarily fine. The nerve at this level of the root passes through a hole of a few tens of microns. It is easy to imagine that a movement of a few millimeters creates a shearing effect sufficient to cause the rupture of the nerve itself. The removal of the pulp and its nerve quickly becomes essential to desensitize the tooth. The opening of a sluice in the enamel to the pulp makes easy access to this natural cavity or artificially open. It is then possible to consider introducing opal within this cavity to cause a migration of cells to the root. The placement of opal in the dental canal to replace the pulp and nerve is difficult. Indeed, the dental canal is irregular and often it is impossible to make it rectilinear. Its diameter varies from a few tens of microns to hardly more than one millimeter. Channel reboring can not guarantee root canal sealing. The handling is difficult also because of the uncertain flow of the powder. The powder could be advantageously mixed with a liquid. The flow of a liquid in the channel immediately poses the problem of the rheology of the introduction and the control of the introduced dose. The association with cones of wax or gutta can be considered but the thing is difficult because the material is friable and can break before reaching the bottom, which is detrimental to obtaining a good result.

Therefore, the opal must be able to be introduced in a suitable form for the purpose of reaching the entire dental canal, that is to say penetrate as deeply as possible into the canal and thus block the part of the canal. narrower than the widest part.

A similar situation arises when the surgeon sets up a dental implant. The base for receiving the implant, always has a cavity for prosthetic connections that are put in place four months later. These 4 months (implant integration period) can be reduced considerably by incorporating in the aforementioned cavity a polymer containing opal as described below.

This form of use of the opal object of the invention must have the following advantages for the practitioner: a) Easy sterilization. b) Safety. c) Maintenance of the properties of the opal. d) Resistance to common solvents e) Easy handling, adaptation to the dental cavity and introduction into the dental canal f) Possibility of removal. g) Possibility to guarantee a sealing seal.

In the prior art, the filling of the cavity for receiving the prosthetic connections was blocked with a healing screw. The shortening thereof or its absence will leave room to insert the polymer containing the opal. In the same way the filling of the dental canal after its recess, is done with cones, waxes or gutta. Heat fusible waxes have many advantages because they consist of glycerol esters or long-chain alcohol ethers, they are malleable and their physico-chemical properties as well as their biocompatibility are well known. Another advantage of waxes lies in the ability to form conical or cylindrical elements suitable for introduction into the dental canal and to compact them. The disadvantage of the waxes is due to the fact that either, they break when introduced into the channel, or if they are too soft, they poorly transmit the signal generated by the opal agglomerates. The use of gutta is also very suitable as regards the filling of the channel but it has the disadvantage of smothering the signal of the opal particles introduced therein.

These properties suggest the use of thermo-fusible plastic polymers of polyethylene or polypropylene type whose melting temperatures are of the order of 100 ° C. They also have a well-established history as biomaterials implanted in the human body. Their possible degradation is done without releasing harmful debris. Their resistance without deformation allows their introduction into the canal and the possible extraction out of the dental canal of the equipment set up by the practitioner. Their melting temperature makes it possible to work the product in the mouth. The invention therefore consists in the use of a synthetic or natural opal-based composition incorporated in a readily fusible polymer in the form of cylindrical fibers or ribbons intended to be inserted into the dental canal.

The easily fusible polymer is preferably polyethylene and mainly high density polyethylene (HDPE), polyethylene medium density (MDPE) or low density polyethylene (BDPE). Polypropylene also fusible is suitable in a similar manner as well as polyacrylates and polymethacrylates. Polyacrylates and polymethacrylates additionally have the distinction of being liquid in the form of monomer or oligomer and it is possible to disperse in this liquid the appropriate amount of opal powder (from 0.5 to 20% and preferably from 1 to 15% by weight) and then polymerization of the monomer according to conventional polymerization methods. It is common practice in dentistry to photopolymerize these resins with violet light ultraviolet light (150 to 300 nm). According to particular embodiments of the invention it has been possible to incorporate up to 20% opal in the polyethylene (PE) melt at 110 ° C. The varieties HDPE, MDPE and BDPE gave fairly similar results. The opal powder is characterized by the fact that it is composed of spheres whose diameter is between 150 and 600 nm agglomerated in clusters of size between 0.500 and 3.00 m. The results on the migration rate show a better efficiency when using spheres whose diameter is between 200 and 500 nm forming clusters of sizes between 0.5 and 1.5 m. Tests have made it possible to obtain satisfactory results with materials such as polypropylenes, unlike polybutadiene which substantially stifles the signal just like gutta. The polyamide fibers are too flexible to be introduced into the channel.

Applicants have determined that 10% opal concentrations are preferable for better preservation of polymer properties to optimize intra-ductal placement.

The applicants have also obtained satisfactory results with polyacrylates, especially polymethyl methacrylate. The oligomer solution of this polymer may be incorporated, such as polyethylenes or polypropylenes from 0.5 to 20% and preferably from 2 to 10% of opal powder. The polymerization is easily done with a physical UV or chemical initiator such as a peroxide or any other polymerization agent associated or not with a crosslinking agent. Acrylate can be used for very thin roots (0.1-0.2 mm) because it is not very flexible and can penetrate deeper into the channels. After having inserted the first acrylic cone in depth, it will be possible to compact flexible cones of polyamides or others to obtain a sealing tightness.

The test material is characterized in that it is either in the form of cylindrical fibers with a diameter of between 0.3 and 1.5 mm, or in cylindrical form with a diameter of between 0.3 and 1.5 mm, or thin ribbon 0.3 mm thick and 0.3 to 1 mm wide. The length of these materials is not very decisive because only the part introduced deep within the cavity of the tooth will be effective, the excess material containing the opal can be sectioned using the appropriate instrument.

Cell culture assays show that if the migration of human skin fibroblasts is strongly accelerated, since it passes as an example from 3 m / h to more than 8 m / h, similar results are obtained with cementoblasts , osteoblasts and keratinocytes, in particular gingival keratinocytes and even keratinocytes derived from explants of human skin. These cells always have lower migration rates of the order of a few microns per hour when they are not subjected to the signal from the polymer containing 10% opal. In the presence of the compositions containing opal, the applicants observed an increase in the migration rate most often between 50% and 125%.

7 The placement of 2 to 6 HDPE polyethylene elements in the dental canals of the molars as well as in the canine or incisors canal is very easy. Dental mobility is reduced by an average of 30 to 50% in a few weeks. The speed of obtaining the clinical results depends on the size of the channel and therefore the amount of opal that can be introduced into the channel. The size of the tooth plays an important role. The larger the root diameter, the faster the result is obtained because cell recruitment is more important. Similarly, the filling of a cavity of a prosthesis depends on the amount of polymer used. The amount of opal is very important, because the migration rate (and therefore the efficiency) is directly proportional to the amount of progenitor cells that can be recruited in the vicinity of alveolodental ligaments or inserted implant. This recruitment or the dimension of the diameter formed by the population of recruited cells is directly a function of the amount of signal emitted and therefore of the amount of opal present in the channel. The intensity of the signal therefore depends on the quantity of opal available.

The decrease in dental mobility is also reflected clinically by the improvement of the jaw occlusion and thus by a better efficiency of the chewing because the patient will have a reproducible mandibular position for an adequate occlusion and masticatory muscles will be less stressed and therefore less tired trying to find the position of maximum masticatory force. Similarly the better integration of the implant will allow faster loading and possible repair of a perimplantitis. For use with a plastic gutter plated with Opal (prevention method) flexible strips 0.4 mm wide and 0.3 mm high will be made, the length of which is determined objectively by a device intended for this use which will stick them on the external and internal edges of the gutters, corresponding to the junction epithelium that will become more resistant against external aggression (microbial or traumatic). This method requires no dental care action, only a banal take and is recommended for all patients to preventively strengthen the natural gingiva during the night allowing a faster implant integration and better quality because the progenitor cells will arrive at the implant-bone interface level before embedding epithelial cells. Another use relates to the treatment of periimplantitis by attraction of the progenitor cells in the altered zones. This will be achieved by introducing the Opal inside the implant, into the existing hole to receive the prosthetic elements or by using gutters plated with Opal.

Claims (11)

1. Use of an opal composition dispersed in a thermally fusible plastic polymeric material selected from polyethylene, polypropylenes, polyacrylates and poly methacrylates to be introduced into the root canal cavity as well as into a cavity created in a tooth or in an implant. 2. Use according to claim 1 of the opal dispersed in a heat-fusible polymeric material to reduce the mobility of a tooth or to improve the integration of an implant in which the composition is introduced into a naturally-dug canal cavity. artificially. 3. Use according to claim 1 wherein the thermally fusible polymeric material is a polyacrylate or a poly methacrylate. The use of claim 1 wherein the polyacrylate or poly methacrylate is employed as a monomer or oligomer in which the opal powder is dispersed. The use of claim 1 or claim 2 wherein the thermally fusible polymeric material is a polyethylene selected from a biocompatible polymer for reducing tooth mobility or enhancing implant integration. The use of claim 1 or claim 2 wherein the biocompatible polymeric material for reducing tooth mobility or enhancing implant integration is polypropylene. 7. Use according to one of the preceding claims wherein the monomer or acrylic oligomer contains from 0.5 to 20% of natural or synthetic Opal diffusion. 8. Use according to claim wherein the acrylic polymer preferably contains from 1 to 15% natural or synthetic Opal. 45 9. Use according to one of the preceding claims wherein the composition is in the form of filaments, cylindrical fibers of diameter ranging from 0.1 to 1.5 mm or in the form of tape having a thickness of 0.1. mm to 0.5 mm and a width varying from 0.1 to 3 mm. 5. Use of the composition according to claim 1 for the emission of a signal causing the migration of the cells to reduce the mobility of a tooth or to improve the integration of an implant, which is transmissible through the body. Enamel of the tooth, zircon and ceramic. 10 11. Use of the composition according to claim 1 characterized in that it causes the migration of fibroblast cells, osteoblasts% of d., ~ Cementoblastsgingival keratinocytes or keratinocytes from expliants of human skin. 15