RU2036622C1 - Method for finishing dental prostheses - Google Patents

Abstract

FIELD: medical engineering; dental prosthetics. SUBSTANCE: method involves applying gold over a corrosion-resistive alloy by successively immersing a prosthesis under voltage of 4-5 V for 3-6 min into an electrolyte having in % by mass: trivalent gold salt 0.25, cobalt chloride 0.03, citric acid 8.0, amines 0.2, hydrochloric acid making up the rest to reach pH<1 and at voltage of 2-4 V for 30-50 min into an electrolyte having in % by mass: potassium dicyanaurate 0.5, nickel sulfamine 0.4, nitrite triacetic acid 1.7, potassium citrate 6.0, formic acid 1.2, boric acid 2.0, glitter- forming additives 0.1, the rest being filled with water. Intermediate rinse is suggested between the stages of the process. EFFECT: accelerated and simplified gold coating process, improved quality of coating layer.

Description

 The invention relates to medicine, more specifically to the section of dentistry, and can be used in the practice of orthopedic dentistry for the manufacture of dentures from corrosion-resistant alloys with a gold coating.

 A known method of applying a coating based on gold on dentures, including a series of sequential operations: degreasing the denture, etching in 25% hydrochloric acid, washing in water, electrolytic treatment in a solution of composition 1 according to mode 1, then in a solution of composition 2 according to mode 2, washing in water, electrolytic treatment in a solution of composition 3 according to mode 3, washing in water, drying, mechanical polishing.

Composition 1 includes: HAuCl ₄ 0.6 g / l; CuSO ₄ 0.5 g / l; 25% Hcl 1 l.

Mode 1: current density 0.8-1.5 A / dm ² ; duration 2 min; temperature 18-20 ^o C.

Composition 2 includes: K [Au (CN) ₂ ] 4 g / l; citric acid 100 g / l.

Mode 2: current density 0.3-1.5 A / dm ² ; duration 3 min; temperature 18-20 ^o C.

Composition 3 includes: K [Au (CN) ₂ ] 10 g / l; citric acid 60 g / l; cobalt sulfate 0.25 g / l; nickel sulfate 0.25 g / l.

Mode 3: current density 0.5-0.8 A / dm ² ; duration 1.5-2.5 hours; temperature 40-72 ^about C.

 The total duration of processing the prosthesis is 95-155 minutes

 However, this method has a number of significant drawbacks: the process is carried out in three electrolytes, the main gilding mode is when heated, which complicates the circuit of the device. To obtain a shiny surface, additional mechanical processing of the denture is required.

 The aim of the invention is to accelerate, simplify the method of processing dentures by applying gold alloys to a corrosion-resistant alloy and obtaining a shiny coating surface.

 This goal is achieved by the fact that a gold alloy is applied to the frame of a denture made of a corrosion-resistant alloy by successively immersing the prosthesis in electrolyte 1, electrolyte 2, washing in water and drying.

 The method is as follows. The metal surface of a denture made of a corrosion-resistant alloy is degreased and etched in a 25% hydrochloric acid solution. Without washing, the prosthesis is placed in an electrolytic bath with solution 1 of the following composition, wt.

Trivalent Ash Salt
that (for example, K [Au (CN) ₄ ] potassium tetracyanoaurate 0.25 Cobalt chloride 0.03 Citric acid 8.0
Amines (e.g. amino alkanes (diethylamine) 0.2 Hydrochloric acid Else
to pH <1, where within 3-6 minutes the metal is simultaneously activated and a thin layer of gold alloy is deposited. The magnitude of the voltage of the electric current is set equal to 4-5 V.

At the end of the stage, the prosthesis is washed in water and immersed in an electrolyte of composition 2, including, by weight. Potassium dicyanoaurate 0.5 Nickel sulfamic acid 0.4 Acid nitrilotriacetic 1.7 Potassium citrate 6.0 Acid formic 1.2 Boric acid 2.0
Bright-forming
additives, for example, Limeda 0.1 Water Else, set the voltage to 2-4 V and hold for 30-50 minutes to build up the main layer of the gold alloy with a brightening effect.

 The method is carried out at room temperature and constantly stirring the electrolyte by reciprocating the cathode rod, on which the prosthesis is fixed. At the end of the process, the prosthesis is removed from the electrolytic bath, washed in water and dried.

 PRI me R. A 47-year-old patient K., suffering from a generalized form of periodontitis complicated by secondary partial adentia of the upper jaw of Class III according to Kennedy, is shown the manufacture of an integral cast splint arch prosthesis from a high-strength cobalt-chromium alloy (KHS). In the patient’s oral cavity there are clinically satisfactory dental crowns on 14, 27, 36, 37, 45, 46 and 47 teeth made of gold alloy. When using dentures made of dissimilar alloys, galvanism phenomena may occur that significantly worsen the pathology of the maxillofacial system and the general condition of a person. Therefore, it is necessary to process the clasp prosthesis by applying a gold alloy to the frame of the prosthesis from a corrosion-resistant cobalt-chrome alloy: an arc, clasps, splinting elements without damaging the plastic artificial gums and artificial porcelain teeth. Dental cobalt-chromium alloys, such as KHS, are highly corrosion-resistant alloys and require special preparation of the metal surface to obtain high-quality adhesion of the gold coating to the base.

 After the manufacture of a one-piece cobalt-chrome splinting clasp prosthesis in a known manner and careful fitting in the patient's oral cavity, the prosthesis was treated with the proposed method.

 The gold coating was applied in electrolytic baths with a volume of 1 liter. A prosthesis with a thoroughly defatted metal surface was etched in a 25% hydrochloric acid solution for 1 min and hung on a copper cathode in electrolyte 1, of the following composition, wt.

Trivalent gold salt 0.25 Cobalt chloride 0.03 Citric acid 8.0 Amines 0.2 Hydrochloric acid Else
to pH <1, the voltage in the circuit was set to 4.5 V. After min the current was turned off, the prosthesis was removed, thoroughly washed with running water and hung in an electrolytic bath with solution 2, of the following composition, wt. Potassium Dicyanoaurate 0.5
Nickel sulfamic acid 0.4
Nitrilotri- acetic acid 1.7 Potassium citrate 6.0 Formic acid 1.2 Boric acid 2.0
Brightening additives 0.1 Water The rest was set to a voltage of 2.8 V. The main build-up of the gold layer was carried out for 45 minutes with constant stirring of the solution by reciprocating movement of the cathode rod, on which the prosthesis was fixed. The whole method was carried out at room temperature. After washing in water and drying, the prosthesis was placed in the patient's oral cavity. Visual examination of artificial teeth and a plastic gum, closure density of the dentition did not reveal distortions, deformations, color changes. The subjective sensation of the patient is good. The patient was especially pleased with the high cosmetic effect of the matching color of the clasps with the coating and supporting gold crowns, as well as the shiny surface of the palatine arch and branches. During follow-up examinations after 6 months, 1 year and 1.5 years, there were no complaints of the patient about a burning sensation, the taste of metal, etc., there were no changes in the potentials of dentures during measurements in the oral cavity. An objective examination of the metal parts of the prosthesis revealed no abrasion and tarnishing of the gold coating. At the control examination 24 months after the manufacture of the prosthesis, abrasion of the gold coating on the occlusal surface of the clasps was revealed. The coating was reconstructed using the described method.

 High functional and cosmetic effect, simplicity of the method and high productivity allows us to recommend this method for widespread use in dental practice.

Claims (1)

 METHOD FOR PROCESSING DENTAL PROSTHESES by applying gold alloys to a corrosion-resistant alloy, including the successive immersion of the prosthesis in two gilding electrolytes, keeping them at a given voltage, washing and drying, characterized in that, in order to accelerate, simplify the method and obtain a shiny surface coatings, as the electrolyte of the first composition, a solution containing a salt of trivalent gold, cobalt chloride, citric acid, amines, hydrochloric acid, taken in the following ratios, is used, ma from. Trivalent Gold Salt 0.25
Cobalt Chloride 0.03
Citric Acid 8.0
Amines 0.2
Hydrochloric acid Rest to pH 1
and as the electrolyte of the second composition, a solution is used containing potassium dicyanoaurate, nickel sulfamic acid, nitrilotriacetic acid, potassium citrate, formic acid, boric acid, brightening additives and water, taken in the following ratios, wt. Potassium Dicyanoaurate 0.5
Nickel sulfamic acid 0.4
Nitrilotriacetic acid 1.7
Potassium Citrate 6.0
Boric acid 2.0
Formic acid 1.2
Brightening additives 0.1
Water Else
while the exposure time in the electrolyte of the first solution is 3
6 min at a voltage of 4 5 V, and in the second solution 30 50 min at a voltage of 2 4 V at room temperature.