RU161879U1 - SCREW DENTAL IMPLANT - Google Patents

Abstract

1. A screw dental implant, consisting of an intraosseous part, on the external surface of which a thread is made, characterized in that the thread is multi-lead, the angle between the sides of adjacent threaded protrusions is performed in intervals from 10 ° to 58 °, the thread stroke is from 0.7 up to 3.0 mm, the thread profile height of the main part of the implant is from 0.41 to 1.5 mm, while the intraosseous part contains an internal cavity made in the form of a seating surface and a blind threaded hole (channel) with an internal thread from 1.8 mm to 2 . 5 mm, grooves (recesses) are made on the seating surface, forming polygonal figures with protruding vertices in the section plane, in the end part the implant is made with a lower thread profile and a reduced inner diameter of the thread compared to the main part of the implant, while the outer diameter of the thread of the implant runs from 4.0 mm to 6.5 mm. 2. A screw dental implant according to claim 1, characterized in that the intraosseous part contains at least two types of thread profile simultaneously on the intraosseous part, differing in profile height and profile angle. A screw dental implant according to claim 1, characterized in that the intraosseous part contains a cervical part with a thread and an apical part with a thread, and the intraosseous part contains at least two types of thread at the same time, differing in thread pitch. A screw dental implant according to claim 1, characterized in that the intraosseous part contains a cervical part with a thread and an apical part with a thread differing in thread pitch, wherein the apical thread progress corresponds to the cervical thread, and the intraosseous part contains

Description

The field of technology.

The utility model relates to medical devices, in particular to medical equipment, and is intended for surgical, orthopedic dentistry, as well as maxillofacial surgery and can be used in implantation and prosthetics as a dental implant.

State of the art

The prior art screw dental implants, consisting of an intraosseous part and a head (abutment), which are interconnected by a detachable connection, while the intraosseous part is fully or partially made with an external thread.

Meanwhile, when developing the thread of implants, it is not taken into account that the angle between the adjacent lateral sides of adjacent threaded protrusions (hereinafter referred to as the angle of the thread contour) is an important factor affecting the process of osteogenesis and osseointegration of the implant, since the volume of bone tissue concentrated in the thread contour is directly depends on the value of the contour angle. Functional loads mainly affect the bone tissue of the implant bed (the response "thread" in the bone tissue) in the area of the thread contour of the implant.

When performing a single thread, the value of the angle of the thread profile corresponds to the angle between adjacent threaded protrusions (turns). If the thread is multi-thread, then the value of the angle of the thread profile may not correspond to the value of the angle of inclination of the adjacent lateral sides of adjacent threaded protrusions.

The thread used in implants usually has a standard profile angle value (60 ° for metric threads). This is due to the ease of production of standard threads.

It is also known to use a trapezoidal thread in implants, in which one side of the profile is performed with an angle between the side and the longitudinal axis of the implant thread close to the direct value (90 degrees). Using a standard trapezoidal thread does not allow to correctly distribute the load on the bone tissue during the operation of the implant, does not allow you to adjust the height

profile by changing the angle of the thread contour at the same step. To increase the height of the profile (with a standard trapezoidal profile) it is necessary to increase the diameter of the implant and the thread pitch, which is impossible with a limited diameter of the implant.

The prior art screw dental implant (US Patent No. 5588838, A61C 8/00, 1996), having a head (abutment) and an intraosseous part containing an apical part with a thread with a rounded profile angle of 60 °, thread pitch ^~ 0, 6 mm, and the cervical part with micro-roughness, which can be made in the form of micro-threads with a height from 0.02 to 0.2 mm. This design has disadvantages: weak fixation force in the bone tissue (especially during direct implantation) due to the low thread profile height and profile angle of 60 ° on the apical part and micro thread on the cervical part of the implant. This implant is manufactured by Astra Tech (Sweden) under the designation - ST. The force of fixation of this implant in the hole of the extracted tooth does not exceed 10-15 kgf, which is not enough to counteract early functional loads. Prosthetics is allowed only after 4-6 months, which delays the treatment time. It is known from the prior art that the larger the area of the support, the contact, the better the fixation of the implant in the bone. Therefore, dental implants are created with a developed rough surface. One way to create a rough surface is micro thread. This term is proposed in US patent No. 5588838, which defines micro-threads: microroughness in the form of micron threads or micro beads with a roughness height of 0.02 to 0.2 mm. The company Astra Tech conducted a computer simulation, confirming the effectiveness of micro-threads.

However, the researchers did not take into account that the bone tissue is not continuous material, but porous and the coefficient of continuity or porosity varies depending on the area of bone tissue - the cortical layer or the spongy layer.

We conducted studies to study the effect of porosity of the material on the area of contact with the surface of the implant (bone screw) with computer simulation and the strength of fixation under functional loads.

These studies have confirmed our assumption that such a parameter as porosity (continuity) affects the contact area and the strength of implant fixation. Therefore, a simple reduction in thread size does not give the effect of increasing the area of contact with the implant bone bed.

A screw implant is known from the prior art - patent for invention RU No. 2190373, consisting of interconnected by a threaded and conical connection of the intraosseous part containing the cervical part

with thread, the apical part, made in the form of a self-tapping screw, the threads of which form plates. The inner landing surface is made in the form of a landing cone.

The disadvantage of the implant is the inconvenience of introducing into the bone tissue. The absence of internal polyhedrons or slots for interfacing with a tool for screwing the implant into the bone makes it difficult to carry out the installation of the implants. This implant is taken as a basis when developing a utility model as the closest analogue.

Utility Model Disclosure

The main fixing element of screw implants that can withstand early functional loads (from 20 to 80 kgf in various parts of the jaw) is thread. By dosing and changing the functional stress in the bone tissue with the parameters of the implant thread, a different tissue response to the load can be obtained.

The implant is held in the bone due to the teeth of the bone tissue i.e. mating thread formed in the bone bed of the implant. It is the teeth of the bone tissue of the implant bed that perceive and counteract the functional load.

The diameter of the implant is always limited by the size (thickness) of the alveolar ridge or (alveolar part) of the jaw. Experimental studies have established that the higher the thread profile - the stronger the fixation of the implant and resistance to functional loads. Obviously, the height of the profile is limited by the angle forming the thread profile.

Therefore, in this utility model, it is proposed to change the profile height, as well as to increase the fixation force and the implant's resistance to stresses by performing a non-standard thread profile, the angle between the adjacent lateral sides of adjacent threaded protrusions in the range from 10 ° to 58 ° (the extreme values here and further included in the interval). Reducing the angle of the profile of the thread allows you to place a larger volume of bone tissue between the threaded protrusions, increase the height of the profile, thereby strengthening the force of fixation of the implant and reduce the time of engraftment of the implant.

Our experimental studies have established that the volume of bone mass concentrated between the threaded protrusions of the standard profile angle of the known implants is insufficient for high-quality fixation of the implant and does not allow to accommodate the bone mass of the same volume as when using a thread with a smaller contour angle, in combination with the optimal for a given angle, thread pitch. Special

critical areas of bone tissue located in the hollows of the contour of the thread of the implant.

The disadvantages of implants with standard thread are insufficient resistance to functional loads, low primary force of implant fixation in bone tissue, on the one hand, and excessive loading or tension in bone tissue, on the other hand.

This insufficient resistance to functional loads manifests itself in such a way that during operation in the thread contour of an implant having a thread with a 60 ° angle between adjacent lateral sides, in combination with a low profile height, foci of stress and stress are formed, the strength of which exceeds the stimulating voltage. This leads to atrophy of bone tissue and its replacement with fibrous tissue.

Experimental studies show that on histological preparations in the area of the thread contour, coarse-fibrous connective tissue is visible, containing a large inclusion of macrophages, osteoclasts. The counter teeth in the implant bed in areas with high voltage have a shortened size and a rounded shape. Such resorption of teeth can occur locally in one area or circularly. If these areas are located in the cervical region of the implant, a wedge-shaped bone pocket is formed, with a violation of the tightness in the gingival region and the formation of a message with the oral cavity. As a result of this, the implant receives micromobility, which exacerbates the situation and the usual cyclic functional loads turn into traumatic.

In addition to resorption, portions of the thread contour with a standard profile also undergo dystrophy even at normal stresses or in the absence of load. Due to the lack of normal trophism of the structural elements of bone tissue, concentrated in narrow sections of the thread contour.

From the above it is obvious that with an equal diameter and length of the implant, implants with an angle of the contour of the thread are less effective than the standard value of 60 °, since this allows you to accommodate a larger amount of bone mass between the threaded protrusions, to obtain a larger thread profile, with the same step, and that means - a large force of fixation and the correct distribution of functional loads. It is also obvious that with a low bone density the angle of the thread contour should be less, which allows a larger volume of bone to be accommodated (an amount sufficient to counteract the chewing load) than with a dense bone, since the lower the bone density, the less stable it is to functional loads.

To facilitate the installation of the implant into the bone tissue - self-cutting, the implant in the end part is made with a smooth lowering of the thread profile and reducing the internal diameter of the thread.

Difficulties arise when inserting an implant without first threading (self-cutting) into a dense bone tissue, if such an implant has a high profile (threaded protrusions with a height> 0.4 mm) due to the large moment of rotation. To facilitate insertion, the interface between the implant and the insertion instrument should prevent the instrument from turning in the implant at a high torque. Known from the prior art, tools for introducing an implant into the jawbone contain a hexagon, which rotates at a large moment of rotation, which makes it difficult to install the implant. Therefore, in this device, it is proposed to perform the assembly of the interface between the implant and the tool for introducing the implant in the form of a compound that forms polygonal figures with protruding vertices (corners) in the section plane. The mating unit in the form of polyhedra without protruding vertices is ineffective due to stalling or turning of the tool when the implant is inserted.

The objective of this utility model is to create an implant that contains a combination of all the essential features that make it possible to eliminate the indicated disadvantages of implants known from the prior art, namely: the creation of an implant, the angle of the thread contour of which allows the bone mass to be accommodated between adjacent lateral sides of larger threaded protrusions having threaded protrusions with a profile height of from 0.41 to 1.5 mm. inclusive, with a thread pitch of 0.7 to 3.0 mm. inclusive. In the end part, the implant is made with lowering the thread profile and reducing the internal diameter of the thread; the implant interface is made in the form of an internal landing surface and grooves (recesses) forming polygonal figures with protruding vertices (corners) in the section plane.

Technical result

The technical result is achieved by the fact that a screw dental implant is proposed, consisting of an intraosseous part, on the outer surface of which a multi-thread is performed with an angle between the sides of adjacent threaded protrusions in the intervals from 10 ° to 58 °, with a thread stroke of 0.7 to 3, 0 mm, the height of the thread profile from 0.41 to 1.5 mm, while the intraosseous part contains an internal cavity made in the form of a seating surface and a threaded channel with an internal thread from 1.8 mm to 2.5 mm, on the inner landing surface ying grooves (recess) for coupling the implant to the instrument head or to introduce

implants forming polygonal figures with protruding vertices in the section plane (perpendicular to the longitudinal axis of the implant), in the end part the implant is made with a lower thread profile and a reduced internal diameter of the thread compared to the main part of the implant. The external diameter of the thread of the implant is from 4.0 mm to 6.5 mm.

The combination of all the essential features of the utility model listed above allows one to achieve a technical result - the creation of an implant, the angle of the thread contour of which allows the bone mass to be placed between adjacent lateral sides of larger threaded protrusions; with a thread profile height - from 0.41 to 1.5 mm with a thread pitch from 0.7 to 3.0 mm, which increases the fixation force in the bone; in the end part, the implant is made with a smooth decrease in the thread profile and a decrease in the internal diameter of the thread, which allows the implant to be inserted with self-cutting (or indentation at low bone density); the assembly of the implant and the tool for introducing the implant is made in the form of recesses (grooves), forming in the horizontal plane of the cross-section (section) perpendicular to the axis of the thread of the implant polygonal figures with protruding vertices (angles), which allows you to enter the implant with a large moment of rotation, prevents the tool from spinning and facilitates insertion into bone tissue. These polygonal shapes may have smooth, rounded, or ellipsoidal faces. The protruding peaks may have a sharp or rounded shape.

In this utility model, it is proposed to change the height of the profile, as well as to increase the fixation force and the implant's resistance to stresses by performing a non-standard thread profile, the angle between the adjacent lateral sides of adjacent threaded protrusions, which is performed in the range from 10 ° to 58 °. Reducing the angle of the thread profile allows, without changing the pitch of the thread, to increase the height of the profile and place a larger volume of bone tissue between the threaded protrusions. In a preferred embodiment, the implant is performed with a thread profile made in the form of an isosceles triangle, the apex of which can be sharp or rounded.

In the end part, the implant is made with a lower thread profile and a reduced inner diameter of the thread, compared with the main part of the implant, while the outer diameter of the thread of the main part of the implant is performed from 4.0 mm to 6.5 mm. The external diameter of the thread of the implant is an essential feature, it optimizes the intraosseous part with a limited thickness of the alveolar part of the jaw at the installation site, allows you to use the implant with a maximum diameter for a given angle of the contour and the thread pitch, which in combination with the above

thread parameters increases resistance to functional loads. The internal diameter of the thread of the end part of the implant allows you to choose the minimum possible diameter of the rod, which also allows you to accommodate a larger volume of bone in the thread contour of the implant. The internal diameter of the thread of the implant is measured beyond the projection of the internal threaded channel. The values of the parameters of the implant (height of the profile, the outer diameter of the thread, the inner diameter of the thread and the diameter of the threaded channel) are selected in such a way that, in any case, the size of the internal diameter of the thread of the implant exceeds the dimensions of the internal threaded channel by at least 0.3 mm.

The diameter of the internal thread can have values from 1.8 to 2.5 mm inclusive and allows the most reliable fixation of extraosseous elements (head) at the maximum strength of the implant shaft. For small implant diameters (4.0 mm), an internal thread of 1.8 mm is used; for a large diameter (6.5 mm), it is preferable to use an internal thread of -2.5 mm, otherwise 2.0 mm.

The intraosseous part is usually performed without separation into the cervical and apical. As an embodiment, the intraosseous part contains the cervical part with a thread and the apical part with a thread, while the cervical and apical parts contain different threads, differing by the pitch of the thread and (or) the height of the profile, and (or) the angle of the contour.

As an embodiment, the intraosseous part may comprise a cervical part conical or cylindrical with thread and an apical part conical or cylindrical with thread. As an embodiment, the intraosseous part may contain the cervical part, the diameter of which (or the diameter of the thread of which) is smaller, greater than or equal to the diameter of the thread of the apical part. In a preferred embodiment, the implant is performed with the cervical part equal or larger in diameter (thread diameter) with the thread diameter of the apical part.

As an embodiment, the intraosseous part is performed without separation into the cervical and apical and contains at least two types of thread at the same time, differing in the pitch of the thread. As an embodiment, the intraosseous part is partially performed with a lower thread profile height (<0.41 mm). The intraosseous part at the beginning usually has a section without a thread - a neck, which is smooth or rough, cylindrical or conical in shape.

Brief Description of the Drawings

The essence of the utility model is illustrated in FIG. 1 and FIG. 2.

In FIG. 1 shows a General view of the intraosseous part.

In FIG. 2 shows an embodiment of the implant.

The implant consists of an intraosseous part 1. The intraosseous part is made in the form of a self-tapping screw (screw) and contains a multi-thread on the outer surface with an angle V between adjacent side sides of adjacent threaded protrusions (thread contour angle) from 10 ° to 58 °, which allows bone mass of a larger volume than with the standard value of the angle, with a thread (screw movement per revolution) from 0.7 to 3.0 mm., with a profile height h 0.4-1.5 mm. The height of the thread profile can be changed by changing the angle of the thread profile or the angle of the thread contour. The thread profile on the intraosseous part of the implant can be made triangular or other shape, but the angle of the thread contour is performed within the above limits. The threaded protrusion can be made with an incomplete profile, a truncated profile, with a bevel on one side, with a rounding at the top, with a rounding at the base; the thread profile may be inclined relative to the threaded axis of the implant.

A screw implant typically comprises an implant head 2 connected to the implant by a detachable threaded connection and a seating surface.

The intraosseous part in the embodiment contains the cervical 3 and apical parts 4. The parietal part is conical or cylindrical. The apical part is cylindrical; as an embodiment, it can be conical. The diameters of the cervical part can be equal to, or greater, or less than the diameter of the apical part. The apical and cervical part can be performed in a combined form, i.e. it can partially be conical, and partially cylindrical. In addition, two different types of threads can be made on the apical and cervical parts. On the outer surface of the apical and cervical part, single-thread or multi-thread is performed. As an embodiment, the cervical part can be performed without thread, while it can be polished or have a rough surface (sandblasted or etched).

The implant has a conical section 5 at the end of the intraosseous part with a reduced thread profile compared to the rest (main) part of the implant and a reduced inner diameter of the thread (implant shaft), which gives the thread self-tapping properties, facilitates screwing into bone tissue.

The end of the apical part 6 is usually made rounded or flat, may have a hole. On the outer surface of the intraosseous part, longitudinal or spiral (curved) depressions with a cutting edge for self-cutting and anti-rotation (grooves, chamfers, flats, recesses) 7 are usually performed, which also gives the implant self-cutting properties. These grooves also give the implant anti-rotational properties, since bone tissue grows in them during the implant engraftment. Recesses can be performed in the terminal, middle and cervical parts of the implant. The indicated Depressions (grooves) can be made with a bend or with an inclination relative to the longitudinal threaded axis of the implant, as well as in a spiral.

Inside, the intraosseous part contains an internal landing cavity (interface unit) made in the form of a seating surface 8 and a threaded channel 9 with an internal thread having a thread diameter of 1.8 to 2.5 mm, and grooves (recesses) 10 are made on the walls of the inner landing surface, forming in the plane of the section (horizontal (perpendicular) section relative to the axis of the implant) polygonal or ellipsoidal figures with protruding vertices.

On the outer edge of the intraosseous part, a circular girdle 11 is usually made (the neck, cervical part) conical or cylindrical, which can be polished or sandblasted. The belt can be polished or sandblasted. The belt may have a bevel angle from minimally close to 0 to as close as possible to 90 degrees. Inside the implant has a landing cavity (channel), conical (landing cone) or cylindrical. On the landing surface (cone) or below it, recesses are made, which can be triangular, rectangular, rounded, and also in the form of a trapezoid. The number of recesses can be from 1 to 12. Their combination can form polygonal (triangle, square, hexagon, etc.) or ellipsoidal figures with protruding vertices. These recesses (grooves) can be used to connect with a tool for introducing an implant into bone tissue, having mating protrusions or polyhedra with protruding apices. These recesses (grooves) can serve as antirotations when connected to implant heads.

The extraosseous part is usually integral, consists of the following elements: the crown part 12, the gingival cone 13, the truncated landing cone 14 and the external thread 15 (threaded rod), usually has a thread 16 inside which a polyhedron 17 is made.

Utility Model Implementation

We have proposed industrially applicable dental implants produced on lathes, CNC lathes, and also on machining centers.

Implants are made from titanium rods of grades VT1-0, VT6, VT6 ELI, BT 7 or their analogues in the international classification, as well as zirconium.

For implantation operations with low bone density, implants are used mainly with an angle between the sides of adjacent turns, in the interval from 10 ° to 44 °, and for medium and high density bone tissue (type 1-2) from 47 ° to 58 °.

The use of an implant with a thread stroke from 0.7 to 1.0 mm is most preferable for high bone density, and from 1.0 to 3.0 mm for low bone density, in addition, the specified thread stroke allows the use of multi-thread with a smaller pitch or a multiple step relative to the thread progress, as well as to combine in the implant different thread parameters, for example, thread with a different step on the neck and apical part and / or profile height, but with the same thread stroke, which facilitates screwing, allows you to tighten the impl antat in the bone tissue without breaking the thread.

A thread profile height with a higher value is usually applied on the apical part (or on the entire surface of the implant with a low bone density). Profile height with a lower value from the parameters indicated above is used at high density, as well as on the apical part of the implant. In addition, the implant may have multiple threads on the entire surface of the implant with the same or different profile heights, depending on the type of bone.

The implant comes with an implant head (abutment), as well as a cap and a gingiva former.

To install this implant, it is proposed to carry out the following procedure at the surgical stage for implant placement:

When performing intraosseous implantation in the toothless area of the alveolar ridge, the formation of the implant bed is performed with peeling of the mucoperiosteal flap. First, a hole is formed with a cylindrical drill in bone tissue, to a depth equal to the length of the implant, successively starting with a smaller diameter and ending with a drill having a diameter equal to the diameter of the implant shaft, a cylindrical hole is created to a depth equal to the length of the implant. Then a milling cutter or a countersink, (conical or cylindrical) having a diameter smaller than the diameter

implant by the value of the thread profile, drill to a depth equal to the length of the cervical part of the implant, thus creating a bed for the implant.

The implant is screwed in, having a maximum thread diameter of the apical part equal to or smaller in diameter of the neck thread, thus, the high thread profile freely passes through the cortical layer of the bone tissue and begins self-cutting only in the cancellous bone, screwing the implant several turns turns the thread profile into full operation the depth of the profile, the implant receives significant resistance from lateral displacements and disruption, which allows the thread of the cervical part to be screwed into the cortical dense bone self-cutting it. The presence of a thread with a smaller contour angle and a larger profile height facilitates the process of self-cutting, reduces friction, increases stability during installation. The implant is inserted into the bone tissue, cutting the response thread by rotation of the implant, thereby creating a metered compression in the bone tissue.

After the implant is installed, a stub is inserted into it, the mucoperiosteal flap is put in place and sutured. Usually, in the period from 3 weeks to 2 months, the second surgical stage is performed. The mucous membrane of the alveolar ridge is cut above the implant in a circular, parallel or cruciform incision, the cap is unscrewed and the gum former is installed. After wound healing within 3 days to 2 weeks, the shaper is unscrewed, the implant head is installed, casts are taken or scanning (laser measurement) is performed to make the prosthesis.

Claims (6)

1. A screw dental implant, consisting of an intraosseous part, on the external surface of which a thread is made, characterized in that the thread is multi-lead, the angle between the sides of adjacent threaded protrusions is performed in intervals from 10 ° to 58 °, the thread stroke is from 0.7 up to 3.0 mm, the thread profile height of the main part of the implant is from 0.41 to 1.5 mm, while the intraosseous part contains an internal cavity made in the form of a seating surface and a blind threaded hole (channel) with an internal thread from 1.8 mm to 2 . 5 mm, grooves (recesses) are made on the landing surface, forming polygonal figures with protruding vertices in the section plane, in the end part the implant is made with a lower thread profile and a reduced inner diameter of the thread compared to the main part of the implant, while the outer diameter of the thread of the implant runs from 4.0 mm to 6.5 mm. 2. A screw dental implant according to claim 1, characterized in that the intraosseous part contains at least two types of thread profile simultaneously on the intraosseous part, differing in profile height and profile angle. 3. A screw dental implant according to claim 1, characterized in that the intraosseous part contains a cervical part with a thread and an apical part with a thread, and the intraosseous part contains at least two types of thread at the same time, differing in thread pitch. 4. A screw dental implant according to claim 1, characterized in that the intraosseous part contains a cervical part with a thread and an apical part with a thread differing in thread pitch, while the apical thread progress corresponds to the cervical thread, and the intraosseous part contains at least two types of profile at the same time. 5. A screw dental implant according to claim 1, characterized in that the internal (landing) cavity is made conical. 6. A screw dental implant according to claim 1, characterized in that the internal (landing) cavity is cylindrical.

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