BR102013017139A2 - Dental implantology screw, tool and assembly - Google Patents

Abstract

Dental Implantology Screw, Tool, and Assembly, refers to the patent for dental implantology screw, tool, and system and their components for use in a dynamic abutment assembly. This dynamic abutment assembly is used in the manufacture of dental implants in human implantology to fix screws angled, allowing screwing at angles greater than 25 degrees and therefore correct a greater number of implant angulation problems, providing benefits such as increasing the number of solutions to solve aesthetic and functional problems, less likely that the wrench will lose contact or disengage from the screw while tightening, the less likely that the geometric shape of the screw head will lose its shape, greater flexibility of same costs and costs with respect to screws and wrenches of the current state of the art.

Description

“SCREW, TOOL AND ASSEMBLY FOR DENTAL IMPLANTOLOGY”.

The present patent relates to a dental implant screw, tool and assembly or system having a fixation system and its components to be used in a dynamic abutment assembly or in CAD-CAM laser mechanized and sintered structures. Such a dynamic abutment assembly or mechanized structure is used in the manufacture of dental implant prosthesis implant in human implantology for angled screw fixation. The invention aims to widen the angle of the dynamic abutment screw or mechanized structure, providing benefits by improving the safety of the dynamic abutment screwing system or mechanized implant structure, correcting a larger number of problems, increasing durability, increasing the number of solutions. To solve aesthetic and functional problems, reduce the likelihood that the tool will disengage from the screw head during use, increase the flexibility of use and maintain the cost relative to the screws and keys used in the current state of the art.

International patent application W02006 / 0247680, by the same applicant, describes a system comprising a guide tube, a base, a screw and a key for acting on a dynamic abutment implant. The dynamic pillar object of such invention comprises two independent parts forming the base and the guide tube or chimney, which are connected to each other by a hinge, of which the base has a semi-spherical configuration, and the chimney has at the end of the coupling to the base a complementary configuration, whose articulation allows the chimney to form a maximum angle of 25 ° with the base, which is coupled by means of a screw in the longitudinal drill of the implant inserted into the bone, whose parts, base and chimney, then of glues form only one piece of metal with desired angulation, which allows for correct positioning, saving any incorrect angular positioning of the implant in the bone by screwing such structure with corrected angle directly into the implant.

According to the invention, the combination of the hinged base and chimney parts provide freedom of movement between 0 and 25 degrees to position it between them at the desired angle before proceeding with casting. Another object of the invention is the wrench (coupling / disengaging tool through a dynamic abutment screw of this invention to the implant inserted into the bone), which has a nut-shaped protrusion that acts as the tip of the abutment coupling screw dynamic to the implant by complementary housing provided in the screw head and having an essentially spherical configuration defined by a succession of chambers constructed by truncated spherical ray interpolation surfaces at both ends.

Although the guide tube or chimney has fulfilled the need to orient the key with the screw, its characteristics limit the process of tightening the screw to a maximum angle of 25 °, causing disadvantages in serving a limited number of applications and solutions. for problems, they are more likely to lose thread, less likely to solve aesthetic and functional problems, and less likely to use less flexibility.

The screws and wrench of said invention present the following problems which the present invention solves: a) Limited angle up to a maximum of 25 degrees; b) As the spherical tip of the wrench is hexagonal in shape and the female of the screw head is of the same shape, tightening occurs only through the perfect fit between them; c) The probability that the wrench will disengage from the screw head is very high; and d) Decreases the likelihood that the hexagon of the screw head will lose its hexagonal shape, a very high probability in currently known systems, which causes the tip of the wrench to rotate inside, preventing proper operation of the assembly during its operation. tightening.

Furthermore, in the present state of the art, there are various fastening devices for joining between two elements, in particular, the screws have heads with different geometries that collaborate with complementary screw tips to tighten the screw to another element by means of a thread. In the present state of the art there is no known fastening device having a head at one end and a thread at the opposite end enabling it to actuate with a wrench such that between the shaft of the wrench tip and the screw head which is inserted into the spanner is greater than 25 ° and allows torque with sufficient guarantees.

“DENTAL IMPLANTOLOGY SCREW, TOOL AND ASSEMBLY”, object of the present patent, has been developed to overcome the limitations, disadvantages and problems of the state-of-the-art guide tube, screws and keys by constructive changes that improve the safety of the dental implant. dynamic abutment bolt-on system, which allows screwing at angles greater than 25 degrees and, consequently, correct a greater number of implant angulation problems, increasing the number of solutions for malposition problems in the implant sector, increasing screw durability and wrench by having less wear due to increased contact surface and better fit and coupling between them, and allowing greater flexibility of male and female fittings, providing benefits such as increased number of solutions to solve aesthetic and functional problems, less likely that the key will lose contact or develop screw housing during tightening, the less likely that the geometric shape of the screw head loses its shape, greater flexibility of use, and the same costs as with prior-art screws and keys.

In addition to the description being given and for the purpose of assisting in a better understanding of the features of the invention, a set of figures is included, in which for illustrative and non-limiting purposes: Figure 1, showing a view front perspective view of a dynamic abutment guide tube; Figure 2 shows the front perspective view of a dynamic abutment screw; Figure 3 shows the top view of the dynamic abutment screw; Figure 4 shows an enlarged detail top view of the depressions and ridges of the dynamic pillar screw; Figure 5. shows the front and rear cross-sectional view of the dynamic abutment screw; Figure 6 shows the front perspective view of an alternative dynamic abutment screw; Figure 7 shows the top view of the screw of the previous figure; Figure 8 shows the enlarged detail top view of the depressions and ridges of the screw of the previous figure; Figure 9 shows the front and rear sectional view of the screw of the previous figure; Figure 10 shows the perspective view of a dynamic pillar key; Figure 11 shows the top view of the key; Figure 12 shows a side view of the key; and Figure 13. shows a section of abutment base assembly, guide tube and screw. Figure 14 shows a section of the screw with the wrench tip inserted into the screw head. It is therefore a first object of the present invention a clamping device with a thread and a head for receiving a tool. The hexalobular shape presents larger tangent radii in the outer area than the known hexalobular systems, which allows to increase the strength and inclination of the screw and wrench assembly.

A second object of the present invention is a tool.

A third object of the present invention is an implantology assembly comprising a base, a chimney or guide duct and a fixture. The present invention is also applicable to metal implant structures made by the CAD-CAM process, not exclusively for dynamic abutment assemblies. Prosthetic structures made by a casting process require the dynamic abutment as the base piece for modeling the wax structure and then casting the abutment to its correct position. In addition, metal structures made by a CAD-CAM process do not require the dynamic abutment, as the structure is designed by a computer and a machine tool, milling the structure using only the screw and key of the system to screw in angled . The dynamic abutment assembly comprises two independent parts, which are the base (B) that fits an implant and the guide tube or chimney (T), which is coupled to the base and on which the aesthetic material is placed, being connected between by means of a pivot with a semi-ball configuration provided at the free end of the base (B) and a complementary configuration provided at the end of the chimney coupling with the cylindrical configuration, said guide tube (T) having a single access hole on the opposite side of the articulation with the base (B) allowing the introduction of a screw (P) and a wrench (C). The base (B) and guide tube (T), which may be of any material, metal or plastic, form a unique structure in the shape required by the patient's buccal anatomy after being anatomically shaped and subsequently fused, showing the desired angle within the structure to be placed in the correct position over the implant, even if the implant is placed incorrectly. Said unique metal structure is coupled through the base (B), already cast, by means of a concrete retention device, a screw, which is screwed into the longitudinal thread of the implant that is in the bone, having access to the screw head through the screw. hole in the guide tube (T), the metal structure being covered by an aesthetic material that simulates the tooth. The metal frame can also be obtained by a CAD-CAM process, in which the frame is designed by a computer and subsequently produced directly by a machine tool or laser sintered.

According to Figure 1, a dynamic abutment guide tube (T) comprises a stepped and tapered cylindrical shaped body (T1) with semi-circular body improvements (T1) at the lower edge of the side, allowing for maximum inclination 30 °, preferably 28 ° for the dynamic abutment due to the drawing of the half-height of the dynamic abutment base, and up to 35 °, preferably 30 ° for the angled channel obtained by CAD- CAM by adjusting the design of the bolt passage in each case to the length of the bolt.

According to Figures 2 to 5, the dynamic abutment screw (P) comprises a cylindrical shaped head (Pl) followed by a frusto-conical shaped body (P-2) with its lower end with a screw thread. bolting with conical seating and at the bottom, semi-spherical shape. The head (Pl) has a female hexalobular inner part (P-1-A) with the circular center and periphery alternating six depressions and six ridges, with the head (Pl) having an outer diameter (DE-1) that varies between 1.8 mm and 2.7 mm, larger inside diameter (DIMA-1), ranging from 1.3 to 2.4 mm, smaller inside diameter (DIME-1) ranging from 1.0 to 2.0 mm, an internal height (AI-1) ranging from 0.5 to 1.5 mm, a depression radius (RDP-1) ranging from 0.15 to 0.35 mm, a ridge radius (RCP-1), ranging from 0.15-0.35 mm, a cone angle (ADC-1) ranging from 25 to 65 degrees and a total height (AT-1) ranging from 2 to 15 mm.

6 to 9 shows an alternative bolt (P) of the dynamic abutment of the present industrial design may comprise a cylindrically shaped head (P-11) with a straight seat and a body (P-12) of similar shape. cylindrical with a lower end having a cylindrical body with a diameter smaller than that of the head and followed by a thread with an outer diameter larger than that of the cylinder body terminating in a semi-spherical shape at the bottom. The head (P-11) has a hexalobular-shaped inner part (P-11-A) with a circular center and periphery alternating six depressions and six ridges, with the head (P-11) of external diameter (DE-11) varying. from 1.8mm to 2.7mm, a larger inside diameter (DIMA-11) ranging from 1.3 to 2.4mm, a larger inside diameter (DIME-11) ranging from 1.0 to 2.0mm , an internal height (AI-11) ranging from 0.5 to 1.5 mm, a radius of depression (RDP-11), ranging from 0.15 to 0.35 mm, a radius of the summit (RCP-11) ranging from 0.15 to 0.35 mm and a total height (AT-11) of which ranges from 2 to 15mm.

Due to the unique hexalobular geometrical design, with radiuses with strong cross section and adapted fit between screw and wrench allows up to 35 ° effective inclination, preferably 30 °, to apply tightening torque and loosen screw.

According to Figures 10 to 12, the dynamic abutment key (C) comprising a cylindrical and trunk-conical shaped body (Cl) with preferably "T" shaped upper part with the curved upper face and an end face. widened section cut on upper cylinder, intermediate and lower tapered and lower grooved and curved with improved tip (C-2), semi-spherical with hollow (C-2-A) and protruding (C-2-B) curves forming a male hexalobular type wrench, with an outside diameter (OD) ranging from 1.3 to 2.4 mm, an inside diameter (D1) between 1.0 and 2.0 mm, the radius of depression (RDC), ranging from 0.15 to 0.35 mm, the radius of depression (RCC) ranging from 0.15 to 0.35 mm and a total height (ATC) ranging from 18 to 35 mm . The engagement between the screw and the wrench is accomplished by means of tangential radii adapted between said screw and wrench thus allowing to apply a tilting torque of up to 35 °, preferably 30 °.

By means of the above elements, in particular by coupling and connection between the screw and the key, it is possible to achieve a joint which allows the guide tube or chimney (T) to form an angle from 0 ° to 35 °, preferably 30 °. ° with respect to the base (B) as seen in figures 13 and 14.

In addition, the procedure for correcting incorrectly positioned implants through the dynamic abutment and the elements of the present invention comprises the following steps: Obtaining an impression of the patient's mouth having the implant; - Obtaining a working model of the patient's mouth, with the exact implant position that the patient has; - Tighten using the screw (P) and wrench (C) of a dynamic abutment with its base (B) and guide tube (T) in a replica of the implant in the working model and position the guide tube (T ) at the desired angle to the base (B); - Fixing the position between the base (B) and the guide tube (T) at a predefined angle; - Anatomical modeling of the customer shape on the base (B) and guide tube (T); - Unscrew, using screw (P) and wrench (C), from the replica of the implant the assembly formed by the base (B) and the guide tube (T); - Casting the base assembly (B) and guide tube (T) to obtain a single metal structure; - Screw using the screw (P) and the wrench (C) of the metal frame over the implant in the patient's mouth; - The metal structure is covered with an aesthetic material that simulates the tooth.

In addition, the procedure for correcting incorrectly positioned implants via CAD-CAM and the elements of the present invention comprises the following steps: Obtaining an impression of the patient's mouth with the implant; - Obtaining a working model of the patient's mouth, with the exact implant position that the patient has; - Model scan to reproduce in 3D; - Modeling of the future metal structure with CAD software; - The structure drawing is sent to a machine tool that will split the structure with CAM software commands; - Screw using the screw (P) and wrench (C) of the metal frame into the implant of the patient's mouth, and - The metal frame is covered with an aesthetic material that simulates the tooth.

As mentioned above, instead of using a milling machine, it is possible to use a laser sintering machine to execute CAM software commands.

Claims (7)

1. “SCREW, TOOL AND ASSEMBLY FOR DENTAL IMPLANTOLOGY”, with a head and a thread at its opposite end, where the screw head has a female hexalobular inner part (PlA) with circular center and periphery alternating six depressions and six ridges, showing that the hexalobular system according to ISO 10664, located in the outer zone, allow a slope between 0o and 35 ° for the application of a tightening torque by a wrench. "DENTAL IMPLANT SCREW" according to claim 1, characterized in that the inner part of the head (PlA) has an outer diameter (DE-1) ranging from 1.8 mm to 2.7 mm in diameter. , a larger inside diameter (DIMA-1) ranging from 1.3 to 2.4 mm, a larger inside diameter (DIME-1) ranging from 1.0 to 2.0 mm and an inside height (AI-1) ranging from 0, 5 to 1.5 mm. 3. "DENTAL IMPLANT SCREW" according to claim 1, characterized in that the radius of depression (RDP-1) ranges from 0.15 to 0.35 mm and the radius of ridge (RCP-1) varies from 0.15 to 0.35 mm. 4. "DENTAL IMPLANT SCREW" according to claim 1, characterized in that the cone angle (ADC-1) varies from 25 to 65 degrees. 5. “TOOL FOR DENTAL IMPLANTATION”, characterized in that key (C) comprises a semi-spherical shaped tip (C-2) with curved inlets and protrusions (C-2-B) forming a male hexalobular type key. that the hexalobular system in accordance with ISO 10664, located on the outer profile and with a spherical profile which allows an inclination of between 0o and 35 ° for the application of a tightening torque on the screw. 6. "DENTAL IMPLANT TOOL" according to claim 5, characterized in that it comprises a tip (C-2) with an outer diameter (DE) ranging from 1.3 to 2.4 mm in inner diameter (D1). ) ranging from 1.0 to 2mm, a depression radius (RDC) ranging from 0.15 to 0.35 mm, a ridge radius (RCC) ranging from 0.15 to 0.35 mm and a total height (ATC) ranging from 18 to 35 mm. 7. “DENTAL IMPLANT ASSEMBLY” with a base (B) for coupling with the implant end, a guide tube (T) comprising a body (T1) and a screw (P) comprising a head (Pl) cylindrical in shape and a threaded body (P-2); characterized by the fact that the head of the screw has an inner part (PlA), in the form of hexalobular female with circular center and periphery alternating six depressions and six ridges, the hexalobular system according to ISO 10664, located in the outer zone allowing an inclination between 0 ° and 35 ° for tightening torque by a wrench on the screw.