BR102012026806A2 - Prosthetic Component Extract for Connected Morse - Google Patents

Abstract

PROSTHETIC COMPONENT EXTRACTOR FOR IMPLANTS FITTED WITH MORSE CONE CONNECTION, comprised by an implant, which is provided on the external face with a fixing thread, while the top has a seating base, which centrally projects an internal conical cavity, below which it if a blind hole, and in the internal conical cavity, a connecting pin is inserted under pressure, characterized by the connecting pin in its upper internal section, it projects a cylindrical cavity partially provided with thread that ends close to a slope wall , which abruptly reduces the diameter of said cylindrical cavity forming a through hole where a cylindrical pin is inserted, whose upper section holds a thread extractor followed by a cylindrical shaped head that projects a hexagon internally, configuring an extractor device.

Description

“Prosthetic Component Extractor for Implant Connected Morse Implants”.

This patent application relates to a "CONE MORSE CONNECTION FACTORY FITTING 5 IMPACT COMPONENT EXTRACTOR" which has been developed for the purpose of allowing the abutment pin to be removed from the interior of the implant by rotary movement. of the extraction component without force, ensuring that the implant will not suffer stress during the healing period, this procedure eliminates the process of extraction of the 10 abutment pins that are currently removed, with lateral movements and tensile force that impairs the bone-integration process and undermining the longevity of prosthetic rehabilitation

State of the Art

The use of implants and screws for various purposes of bone fixation and reconstruction of lost or weakened structures has been widely used since the characterization of Titanium as a highly biocompatible material (and other materials on a smaller scale), which allowed the advancement of technique for placement of these implants and their shape. Today many schools adopt 20 different implant techniques and formats, but all with the same principles of osseointegration, biomechanics, and surgery.

Implantation techniques consist of scaled bone drilling of drills that can be cylindrical or tapered according to the fixation model, until the fixation measurement is achieved when the tapping male is used or a measurement before the implant diameter when used. superb fixation and or implant. The scaling of the drills ranges from 0.5 mm to 0.5 mm. In these perforations the bone material present in the transverse drill bit grooves that is removed to create the fixation receptor bed is lost at each drill bit change. In some cases this bone material is used to fill cavities in the region of the placed implant. In drilling with the drills it is normal to lock them in the perforated bone due to the active cutting edge of the same that are used with low speed and high torque motors to avoid heating and necrosis of the bone present in the fixation receptor bed. In some techniques the surgical motor is used to fix the fixation and in others this maneuver is manual or with the aid of a torque wrench. The osseointegration time of biomaterials varies between 4 and 6 months according to the literature, varying here more or less according to the primary locking torque at the time of placement, fixation and quality and density of the receiving bed, as well as the region to be implanted.

Thus, the greater the amount of bone used in osseointegration, the better, since larger implants with greater strength, greater contact surface and, consequently, greater osseointegration area can be used.

Modern implantology has revolutionized therapeutic options

in Dentistry. Areas partially or totally edentulous could be fully rehabilitated, recovering the lost anatomy, function and aesthetics. However, as the scope of osseointegration has expanded, prosthetic requirements have become more demanding in pursuit of a level of excellence in outcomes.

With the increasing applicability of oral implants for unit restorations, the connections developed an important role: to prevent the rotation of the prosthesis. This encouraged manufacturers to increase torque values on the bolt and to make changes in the type of material on the bolt. In addition, components were manufactured more accurately in the 5 hexagon socket and new abutment / implant interface designs were created such as the External Hexagon and Internal Hexagon connections.

Another type of connection is the internal conic also known as the morse cone. The cone morse concept was developed by Sthepen A. Morse in 1864 and is widely used in the mechanical field due to its high degree of strength and precision. The internal tapered connection has the great advantage of its superior ability to withstand transverse loads because it has a larger contact area between implant and abutment when compared to implants with the same macro geometry. The design of the internal tapered connection promotes an intimate fit between the parts, acquiring mechanical strength similar to a single body part. Adapted to the line of implants since 1985 to reproduce as closely as possible the prosthetic characteristics of the natural tooth, implants with internal conical connection have more than twenty years of clinical cases, although they have gained prominence in the national market for over ten years.

The tapered connection has three fixing formats being divided into:

- Fixing by single body screw: In this type of fixing the screw is part of the conical body itself, thus the conical seating has the function of supporting the applied load and the screw has the function of holding the part where it will be fixed, allowing the withdrawal of the component. - Fastening by bolt: In this type of fastening the screw is not part of the conical body, thus the conical seating has the function of supporting the applied load, being fixed by the screw where it should be kept.

- Press fastening: In this type of fastening there is no screw.

The fixation of the conical body is made by friction between the faces of the cone and the component where it will be fixed.

The lower the inclination of the cone, the greater the locking power of the assembly and the lesser the need for screws to assist in the assembly locking.

The main complicating factor of the use of pressure morse taper in dental implants (without fixation screw) is its difficulty in removal if improperly positioned, since newly installed implants cannot undergo traction or compression forces may compromise their primary stability and consequently their success.

Aiming to improve the current surgical techniques, the inventor, after studies, developed a “CONE 20 MORSE CONNECTION FACTORY DENTURE IMPLANT EXTRACTOR”, comprised of an implant, which is fitted on the external face with a fixation thread, while the top holds a seating base, which centrally projects an inner tapered cavity, below which a blind hole is found, and in the inner tapered cavity is inserted a snap-fit connector pin, characterized by the connector pin in its inner upper section projects. a partially threaded cylindrical cavity that is close to a slope wall, which abruptly reduces the diameter of said cylindrical cavity by forming a through hole where a cylindrical pin is inserted, the upper section of which has an extractor thread segment followed by a cylindrical shaped head that internally projects a hexagon, setting up an extra device actor.

So you can get a perfect understanding of what was out

illustrative drawings to which numerical references are made together with the following detailed description, where:

Figure 1 - shows an exploded perspective view of the

set.

Figure 2 - shows an exploded partial sectional view of the

set.

Figure 3 - shows a sectional view of the implant coupled to the connector pin component.

Figure 4 - shows a partial sectional view of the assembly

mounted.

Figure 5 - shows a partial cross-sectional view of the set with extracted pin component coupled to the extractor device.

As illustrated by the figures and in their details, the "Prosthetic Component Extractor 20 for Connected Morse Implant Implants", comprised of an implant (1), which is provided on the outer face (2) with a clamping thread (3), while the top (4) holds a seating base (5), which centrally projects an inner tapered cavity (6), below which there is a blind hole (7), 25 in which the inner tapered cavity (6) is A snap-fit connector pin (8) is inserted, characterized in that the connector pin (8) in its inner upper section (9) projects a cylindrical cavity (10) partially fitted with a thread (11) that is close to a slope wall

(12), which abruptly reduces the diameter of said cylindrical cavity (10) by forming a through hole (13) into which a cylindrical pin (14) is inserted, whose upper section (15) holds an extractor thread segment (16) followed by a cylindrically shaped head (17) which internally projects a hexagon (18), forming an extractor device (19).

Based on what is described and illustrated, we can see that the “Prosthetic Component Extractor for Cone MORSE DONATED CONNECTION IMPLANTS” has huge advantages because 10 The new concept of implant and prosthetic component developed has the pressure-fixed morse cone system ( without screw), equipped with prosthesis extraction device.

The device consists of an internally through screw the component (connector pin) that touches the implant bottom 15 transmitting the torque (swivel) applied by the operator to the assembly and expelling the component (locked to the implant by pressure) without the need for horizontal and lateral efforts. , which could interfere with the bone integration process.

The use is simplified where initially adapts20 if the component (connector pin) in the implant through pressure (performed by the morse cone), to remove the component is necessary to insert the extractor screw in the prosthetic component with an internal thread, apply the torque in the extraction device is reached until it reaches the maximum point of contact with the interior of the implant, when forced against the implant bottom the extraction device finds the resistance pulling the prosthetic component in the opposite direction, unlocking it no need for vertical and horizontal movements.

Because it is innovative and hitherto not understood in the state of the art, the proposed process fits perfectly within the criteria that define the invention patent. Your claims are as follows.

Claims (5)

1. “PROTETIC COMPONENT EXTRACTOR FOR CONE MORSE FITTED IMPLANT IMPLANTS”, comprising an implant (1), which is provided on the outer face (2) with a clamping thread (3), while the top (4) has a base (5), which centrally projects an inner tapered cavity (6), below which there is a blind hole (7), and in the inner tapered cavity (6) a fixing pin (8) is inserted under pressure, characterized in that the connecting pin (8) in its inner upper section (9) projects a cylindrical cavity (10) partially fitted with thread (11) that is close to a sloping wall (12), which abruptly reduces the diameter of said cylindrical cavity (10) forming a through hole (13) into which a cylindrical pin (14) is inserted, whose upper section (15) holds an extractor thread segment (16) followed by a shaped head (17) cylinder that internally projects a hexagon (18), configuring an extractor device (19). 2. “Prosthetic Component Extractor for Connected Morse Implant Implants” characterized by the extraction device (19) touching the bottom of the implant (1) transmitting the applied torque over the extraction device (19) finding resistance by pulling the connecting pin component ( 8) in the opposite direction, unlocking and expelling it. 3. “Prosthetic component extractor for conse-more implants”, characterized in that the connection pin component (8) is extracted through the thread coupling (11) in the extraction thread segment (16) extraction device (19). 4. “Prosthetic Component Extractor for Connected Morse Implant Implants”, characterized in that the extraction device (19) eliminates vertical and horizontal movements and with pulling force to remove the connector pin (8). 5. “Prosthetic Component Extractor for Connected Morse Implant Implants”, characterized in that the removal of the abutment pin from the interior of the implant occurs through rotary movement of the extraction component.