RU2150250C1 - Method and device for producing artificial denture - Google Patents

Abstract

FIELD: medicine; medical engineering. SUBSTANCE: method involves introducing measuring electrode into implant fixed in mandible bone. The electrode is tightly sealed providing galvanic contact with the implant. Resistance between the implant and surrounding tissues is measured with the ohmmeter, the measuring electrode, auxiliary electrode and additional electrode. Then, the measuring electrode is removed and gingiva former is set into the implant. The gingiva former has controllable electric power supply source which negative pole is galvanically connected to the implant and the positive one is connected to gingiva former cover. Electric stimulation of tissues surrounding the implant is carried out with electric current of 5-50 mcA and concurrent exposure to magnetic field having inductance of 0.1-0.3 Tesla units. The gingiva former is periodically removed in every 5-10 days and substituted with measuring electrode. Resistance is measured with a described method and then, the gingiva former is once more fixed on the implant. Current and magnetic field action is continued with the same current and magnetic field parameters. The dental prosthesis is fixed on the implant by means of a through metal pin built into the dental prosthesis providing galvanic contact between them. The tissues surrounding the implant are continuously subjected to electric stimulation through an additional electrode applied from outward to a pin by means of external electric power supply source with mean current value of 5-50 mcA applied 1-2 times a day and concurrent exposure to magnetic field having inductance of 0.1-0.3 Tesla units applied daily 1-2 times a day during at least 10 days long, in periodically controlling resistance between the implant and surrounding tissues. The gingiva former of the device additionally has an internal cavity and cover. Controllable electric power supply source is placed inside of the cavity. Its negative pole is galvanically connected to the gingiva former casing and the positive one is connected to the cover. The casing and cover are electrically insulated one from another. External surface of the gingiva former is coated with dielectric. The dental prosthesis is additionally provided with a through metal pin having a member for fastening to the implant and outlet to the working surface of a tooth. The device also has measuring, additional and auxiliary electrodes. EFFECT: accelerated osteointegration; prevented and eliminated inflammation processes in the implantation area. 10 cl, 5 dwg

Description

 The present invention relates to orthopedic dentistry.

 A known method of dental prosthetics (Moscow Dental Institute, Russian system of dental implants "Liko") by introducing an implant into the upper or lower jaw as the basis for the subsequent attachment of a denture on it. The method is carried out in three stages. An implant is inserted into the jaw in the form of a pin with an external thread. The opened gum after implant placement is completely sutured and drug stimulation is provided to accelerate the implant osseointegration in the bone tissue. After radiological or ultrasound fixation of the normal osseointegration of the implant in the bone tissue, the gum is opened and the gingiva former is fixed in the implant in an open or closed way. Then, after the soft tissues are repaired and a “lodgement” is formed for the denture, the gum former is extracted and the denture is fixed on the implant.

 However, the method of prosthetics has disadvantages.

 Monitoring of the process of osseointegration is carried out repeatedly using x-rays, which in itself is quite harmful to the patient. The method does not guarantee osseointegration of the implant with bone tissue without complications - rejection of the implant due to resorption in the implant area, inflammation and osteoporosis in the area of implantation.

 All procedures at the stages of surgery related to prosthetics require a long treatment time - from 3 to 6 months.

 A device is known that contains a set of elements (Moscow Dental Institute, Russian system of dental implants "Liko"): an implant in the form of a pin with an external thread, implanted in the bone tissue of the jaw, gum shaper and tooth prosthesis.

 This device as a set of elements has disadvantages. It does not contain elements that accelerate the process of osseointegration, inhibit the development of osteoporosis and inflammatory processes, inhibit the formation of resorption near the implant and, finally, block the rejection of the implant.

 It also does not contain elements of control over the process of osseointegration of the implant with the jaw bone.

 The technical result of the invention is the acceleration of osseointegration of the implant in the jaw bone, the prevention and elimination of inflammatory processes in the field of implantation, the inhibition of the development of resorption and osteoporosis in the area of the implant and the rejection of the implant, the control of the osseointegration process and the postoperative preventive electrical and magnetic effects on the tissues in the area of the implant.

 The technical result of the method is achieved by the fact that the measuring electrode is inserted into the implant fixed in the jaw bone and is galvanically contacted, through which the ohmic resistance between the implant and surrounding tissues is measured using an external auxiliary electrode, an additional electrode and an ohmmeter, after measurement ohmic resistance, the measuring electrode is removed and a gingiva former containing inside a controlled source of electrical energy is fixed in the implant and, the negative pole of which is galvanically connected with the implant, and the positive pole - with the cover of the gingiva former in the absence of direct galvanic contact of the cover with the gum tissues, and to accelerate the osseointegration of the implant with the jaw bone, an electrical effect is applied to the tissues surrounding the implant with an average current of 5-50 μA with simultaneous exposure to a magnetic field with an induction of 0.1-0.3 T, while periodically after 5-10 days the gingiva former is removed, replacing it with a measuring electrode, an ohmic measurement is carried out resistance method as described above, and then the gingiva former is fixed on the implant and the current and magnetic field continue to act on the tissue with the same current and magnetic field parameters, the gingiva former is finally extracted while maintaining ohmic resistance during two consecutive measurements, which means the completion of osseointegration an implant with a jaw bone, after which, using a through metal pin embedded in the denture, the denture is fixed to the implant with galvanic contact between them and continue the electrical effect on the tissue surrounding the implant through an additional electrode, applied externally to the pin using an external controlled source of electric energy with an average current of 5-50 μA 1-2 times a day, with a simultaneous exposure to a magnetic field with induction 0 , 1-0.3 T for 10-30 minutes daily 1-2 times a day for at least 10 days, and at the same time, the ohmic resistance between the implant and surrounding tissues is periodically monitored using the outer part of the pin and an additional element Trodena.

 The technical result of the method is also achieved by the fact that the magnetic effect on the tissue area surrounding the implant is carried out using electromagnetic sources of a magnetic field or rotating permanent magnets with an induction of 0.1-0.3 T.

 The technical result of the method is also achieved by the fact that to measure the ohmic resistance between the implant and surrounding tissues, a metal measuring electrode is used in the form of a cylinder, one end of which is mechanically fixed in the implant to ensure tightness and galvanic contact between them at the place of their joining, and the other end is provided measuring window, and the measuring electrode on the entire surface, except for the measuring window, is covered with a dielectric, after installing the electrode on the implant e o drain and measure ohmic resistance.

 The technical result of the method is also achieved by the fact that an additional electrode is provided with a contact pad, which, when measuring the ohmic resistance between the implant and surrounding tissues, is placed to provide galvanic contact on the measuring window of the measuring electrode or on the outer end of the through metal pin of the tooth prosthesis after it is fixed on the implant and subsequent electrical exposure due to an external source of electrical energy, and an auxiliary electrode when measuring x always placed on the same surface of the patient’s body surface.

 To implement the method proposed by the authors, a device is developed.

 The technical result of the device for prosthetics is achieved by the fact that the gingiva former additionally contains an internal cavity and a lid, a controlled electric energy source is placed inside the cavity, the negative potential of which is galvanically connected to the gum former body and the positive is connected to the lid, the body and lid being electrically isolated from each other, and the outer surface of the gingiva former is covered with a dielectric, the tooth prosthesis is additionally equipped with a through metal pin with a knot m for attachment to an implant and an outlet on the working surface of the tooth prosthesis, and the measuring device is further provided, an additional and auxiliary electrodes.

 The technical result of the device is also achieved by the fact that an electric battery is used as a controlled source of electric energy, the negative potential of which is connected to the body of the healing abutment, and the positive - to the cover of the healing abutment.

 The technical result of the device is also achieved by the fact that an induction coil with a microprocessor that generates the necessary currents through the implant is used as a controlled source of electrical energy, with the negative potential brought to galvanic contact with the implant and the positive potential to the gingiva cover.

 The technical result of the device is also achieved by the fact that the measuring electrode for measuring the resistance between the implant and surrounding tissues is made in the form of a metal cylinder, one of the ends of which is equipped with a docking unit for articulation with the implant, and the other has a contact pad, and its entire surface is provided with a dielectric coating with adhesion to the surface of the electrode, sufficient when it is sterilized.

 The technical result of the device is also achieved by the fact that the auxiliary electrode is equipped with an electric contact pad and a grip for placement on the patient’s body.

 The technical result of the device is also achieved by the fact that the additional electrode is equipped with a contact pad and a current output for connecting to an external controlled source of electrical energy or an ohmmeter made, for example, of electrically conductive rubber, and the electrode over the entire surface except the contact pad is provided with a dielectric coating.

 The invention is illustrated by drawings.

 FIG. 1 is a cross section of a gingiva shaper with a controllable source of electrical energy built into it.

 FIG. 2 is a cross-sectional view of a measuring electrode coupled to an implant.

 FIG. 3 is a cross section of an auxiliary electrode.

 FIG. 4 is a cross section of a tooth prosthesis with a through metal pin docked with an implant.

 FIG. 5 is a cross section of an additional electrode.

 In accordance with the invention, the gingival former 1 (Fig. 1) comprises a housing 2, a cavity 3 in the housing 2, a controllable source of electric energy 4 with current leads from it, one of which 5 has a negative potential and is galvanically connected to the body 2, and the second current lead 6 has a positive potential and is galvanically connected with the cover 7 of the body 2 of the gingiva former 1, and the cover 7 and the body 2 are electrically isolated from each other by a dielectric layer 8. The dielectric layer 8 at the same time seals the joint of the cover 7 and the body 2. In order to provide To isolate the casing 2 from the environment, the outer surface of the casing 2 is completely covered with a dielectric 9 except for the fixing pin 10, intended for mechanical and galvanic coupling of the casing 2 of the gingiva former 1 and the implant 11. A measuring electrode 12 is used to measure the ohmic resistance between the implant 11 and the surrounding tissues ( Fig. 2), comprising a housing 13, an outer dielectric coating 14 for electrical isolation from surrounding tissues, a pin 15 for mounting on an implant, and a measuring window 16 for connection current lead 17 ohmmeter (not shown).

 The auxiliary electrode 18 (Fig. 3) contains a spring grip 19, contact pads 20 made, for example, of conductive rubber and current lead 21 also for connection to an ohmmeter.

 The tooth prosthesis 22 (Fig. 4) additionally contains a through metal pin 23, one end of which 24 secures the tooth prosthesis to the implant 11, and the other end 25 allows contact with the current lead of an external controlled electric energy source or an ohmmeter current lead using an additional electrode 26 ( Fig. 5).

 The additional electrode 26 (Fig. 5) contains a contact pad 27 made, for example, of conductive rubber, a solid electrical insulation coating 28 and a current lead 29.

 A device consisting of an implant 11, a gingival former 1, a tooth prosthesis 22 and additional elements are used as follows.

 First, the implant 11 is fixed in the jaw bone. Then, a measuring electrode 12 (FIG. 2) is inserted into the implant 11 to measure the initial ohmic resistance between the implant 11 and the surrounding tissues.

 It should be noted that the electrical resistance of soft tissues, blood and other liquor substances is significantly less than the electrical resistance of the periosteum, connective tissue and bone. At the initial moment after the implant 11 is inserted into the jaw bone, it comes into contact with blood plasma and other electrically conductive fluids and the electrical resistance will be quite small. As osseointegration, this electrical resistance will increase.

 When carrying out the measurement of ohmic resistance, a contact pad 27 of the additional electrode 26 is applied to the measuring window 16 of the measuring electrode 12, and it is connected to an ohmmeter by a current lead 29. The auxiliary electrode 18 (Fig. 3) is placed on the patient’s body, always in the same place for all subsequent ohmic resistance measurements, and is also connected to an ohmmeter through the current lead 21. A mandatory procedure is the need to drain the surface of the measuring electrode 12 (Fig. 2) in order to eliminate shunt currents on its surface and improve the accuracy of measurements.

 After measuring the ohmic resistance, the measuring electrode is removed and a gingiva former 1 (Fig. 1) is inserted into the implant 11 using a pin 10. At the same time, an electric current of 4 is applied to the gum former 1 and is supplied with an electric current 4 of 5-50 μA and a magnetic field with an induction of 0.1-0.3 T on the tissue near the implant 11. After 5-10 days, removing the healing abutment 1 (Fig. 1), using the measuring electrode 12 (Fig. 2), introduced instead of the healing abutment 1 (Fig. 1), repeat the measurement of ohmic resistance ivleniya by the above procedure, and then re-fastened healing abutment 11 to the implant 1 and continue to impact the current and the magnetic field on the fabric with the same parameters. The ohmic resistance measurements at the indicated time intervals are repeated until it stops increasing. Moreover, the osseointegration of implant 11 with the jaw bone is actually complete. After that, the gingival former 1 is finally removed and a denture 22 is fixed in its place in the implant 11 (Fig. 4). This ensures a galvanic connection of the external output 25 of the through pin 23 with the implant 11. Simultaneously with the electrical impact on the tissue near the implant 11 due to the electric energy source 4, which is built into the healing abutment 1 (Fig. 1) or after the installation of the tooth prosthesis 22 (Fig. 4) using an external source of electrical energy through a through pin 23, they are exposed to a magnetic field with an induction of 0.1 - 0.3 T. Exposure sessions are carried out 1-2 times daily for 10-30 minutes for at least 10 days.

 If resorption or inflammation occurs in the area of the implant 11 already after the installation of the tooth prosthesis 22 (Fig. 4), it is possible to repeat the electrical and magnetic effects on the tissue near the implant 11 and eliminate them by using an external source of electrical energy with average currents of 5-50 μA. Moreover, its negative potential with the help of an additional electrode 26 (Fig. 5) is brought to the through pin 23 of the tooth prosthesis, and positive to the auxiliary electrode 18 (Fig. 3), which is placed on the patient’s body.

 Control over the elimination of resorption or the inflammatory process is provided by measuring the ohmic resistance with an ohmmeter, additional 26 (Fig. 5) and auxiliary 18 (Fig. 3) electrodes. In this case, an additional electrode 26 is placed on the prosthesis of the tooth 22, providing galvanic contact of the end face of the pin 25 (Fig. 4) with the contact pad 27 of the additional electrode 26 (Fig. 5). Before measurements, the surface of the tooth prosthesis 22 must be drained to eliminate shunting of the measuring circuit by currents along its surface.

 The authors carried out the necessary work, which allowed to determine the necessary parameters of the acting electric current due to the source of electric energy 4, built into the cavity 3 of the gingiva former 1 and the external magnetic field.

The electric current flowing in the tissues has a specific effect. The most pronounced in this case are processes occurring near the electrodes. The neutralization of positive ions (Na ⁺ , K ⁺ and other alkaline elements) at the cathode leads to additional generation of OH ^- hydroxyls, which provides alkalization of the cathode region. This improves the innervation of the nerve channels in this area. Due to the presence of a negative potential on the implant, positive ions (polar, polarized molecules of protein, collagen, Ca ²⁺ ) with a sufficiently high adhesion energy adhere to it. In this case, the effective encapsulation of the implant occurs. Furthermore, the formation of the negative space charge due to the generation at the cathode the alkali ions OH ^- provides a blockade of inflammatory processes. This is confirmed by the fact that a positive space charge is always formed in the area of inflammation. Its blockade by a negative space charge OH ^- leads to the attenuation of the inflammatory process. Near the positive electrode — the anode — due to Cl– ions ^, whose density is high enough, the generation of positive H ⁺ ions (or hydroxonium) takes place. An increase in their concentration leads to acidification of the anode region. At the same time, membrane potentials increase, which leads to a decrease in the rate of metabolic processes, the rate of mitosis of pathogenic microbes and a decrease in pain. Formed a kind of "dead zone" disinfection.

 Both processes (cathode and anode) complement each other, providing the effects of asepsis, eliminating inflammation and encapsulating the implant, i.e., osseointegration of the implant. Due to the small distances between the implant and the bone tissue of the jaw, the currents can be selected quite small (5-50 μA), and the duration of the pulses obtained using controlled sources of electric energy built into the healing abutment or external can be several milliseconds, since this time is determined by the time of diffuse transfer of molecules that form the encapsulation of the implant, which is small.

 The magnetic field in the area of the implant, i.e. surrounding tissues, improves capillary hemodynamics. The increase in the linear blood flow velocity observed in the clinic is 20-150%. In addition, the specifics of the interaction of the magnetic field and hemoglobin leads to a conformation of the latter and an increase in blood saturation with oxyhemoglobin, and the surrounding tissues lead to increased oxygenation. The latter promotes regenerative processes in the field of the surgical field and the activation of metabolic processes in all tissue structures. Ultimately, these processes stop inflammation in the area of influence, promote tissue regeneration and encapsulation of the implant in the bone tissue and prevent the resorption of the bone tissue region near the implant. Based on the analysis of clinical results when applying magnetic fields in the treatment process, the values of induction in the range of 0.1-0.3 T are selected.

Claims (10)

 1. A method of dental prosthetics, including fixing the implant in the jaw bone, introducing the gum former into the implant in an open way, extracting it after gum repair and installing the tooth prosthesis on the implant, characterized in that the implant is fixed in the jaw bone and is hermetically sealed galvanic contact with it, a measuring electrode is introduced, through which the ohmic resistance between the implant and the surrounding area is measured using an external auxiliary electrode, an additional electrode and an ohmmeter tissues, after measuring the ohmic resistance, the measuring electrode is removed and the gingiva former is fixed in the implant, containing inside it a controlled source of electric energy, the negative pole of which is galvanically connected to the implant, and the positive pole is connected to the gum former cover in the absence of direct galvanic contact of the cover with the gum tissues, and to accelerate osseointegration of the implant with the jaw bone, an electrical effect is applied to the tissues surrounding the implant with an average current of 5 - 50 μA, simultaneous exposure to a magnetic field with an induction of 0.1 - 0.3 T, while periodically after 5 - 10 days, the gingiva former is removed, replacing it with a measuring electrode, the ohmic resistance is measured as described above, and then the gingival former is fixed on the implant and continued exposure to current and a magnetic field on tissues with the same current and magnetic field parameters, the gingiva former is finally extracted while maintaining ohmic resistance during two consecutive measurements, which begins the completion of osseointegration of the implant with the jaw bone, after which, using a through metal pin embedded in the tooth prosthesis, the tooth prosthesis is fixed on the implant with galvanic contact between them and the electric effect on the tissues surrounding the implant is continued through an additional electrode applied externally to the pin using an external controlled source of electric energy with an average current of 5 - 50 μA 1 - 2 times a day, with a simultaneous exposure to a magnetic field with an induction of 0.1 - 0.3 T, 10-30 m in daily 1 - 2 times a day for at least 10 days, while the ohmic resistance between the implant and surrounding tissues is periodically monitored using the outer part of the pin and an additional electrode.  2. The method according to claim 1, characterized in that the magnetic effect on the area of tissues surrounding the implant is carried out using electromagnetic sources of a magnetic field or rotating permanent magnets with an induction of 0.1 - 0.3 T.  3. The method according to claim 1, characterized in that for measuring the ohmic resistance between the implant and surrounding tissues, a metal measuring electrode is used in the form of a cylinder, one end of which is mechanically fixed in the implant to ensure tightness and galvanic contact between them at the place of their docking, and the other end is provided with a measuring window, and the measuring electrode is covered with a dielectric over the entire surface, except for the measuring window, after installing the electrode on the implant, it is drained and measured Fertility ohmic resistance.  4. The method according to claim 1, characterized in that the additional electrode is provided with a contact pad, which, when measuring the ohmic resistance between the implant and surrounding tissues, is placed to provide galvanic contact on the measuring window of the measuring electrode or on the outer end of the through metal pin of the tooth prosthesis after it is fixed on the implant and subsequent electrical exposure due to an external source of electrical energy, and the auxiliary electrode during measurements is always placed on one Mr. and the same area of the patient’s body surface.  5. A device for dental prosthetics containing an implant, a gingiva former and a tooth prosthesis, characterized in that the gum former further comprises an internal cavity and a lid, a controlled source of electrical energy is placed inside the cavity, the negative potential of which is galvanically connected to the gum former body and the positive with a lid, the body and the lid being electrically isolated from each other, and the outer surface of the gingiva former is covered with a dielectric, the tooth prosthesis is additionally equipped with oznym metal pin with a hub for fixing to the implant and an outlet on the working surface of the tooth prosthesis, and the measuring device is further provided, an additional and auxiliary electrodes.  6. The device according to p. 5, characterized in that an electric battery is used as a controlled source of electrical energy, the negative potential of which is connected to the body of the healing abutment, and the positive - to the cover of the healing abutment.  7. The device according to claim 5, characterized in that an induction coil with a microprocessor that generates the necessary currents through the implant is used as a controlled source of electrical energy, with the negative potential brought to galvanic contact with the implant and the positive potential to the gingiva cover.  8. The device according to claim 5, characterized in that the measuring electrode for measuring the resistance between the implant and the surrounding tissues is made in the form of a metal cylinder, one of the ends of which is equipped with a docking unit for articulation with the implant, and the other a contact pad, and its entire surface equipped with a dielectric coating with adhesion to the surface of the electrode, sufficient when it is sterilized.  9. The device according to p. 5, characterized in that the auxiliary electrode is equipped with an electric contact pad and a grip for placement on the patient’s body.  10. The device according to p. 5, characterized in that the additional electrode is equipped with a contact pad and a current output for connecting to an external controlled source of electrical energy or an ohmmeter made, for example, of electrically conductive rubber, and the electrode on the entire surface except the contact pad is equipped with a dielectric coated.

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