RU2817960C1 - Intraosseous screw implant with immediate loading and method of its installation - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: device is made with variable height of one-way thread profile. Projections with increased height of thread profile are localized within the limits of full turns of the helical line. Projections are designed to carry an immediate load of the orthopedic structure. Ledges are located on adjacent turns and are mutually offset in angle. In alternative design, the protrusions are located from each other through the coil. Method of implant installation involves formation of bone bed in form of narrowing hole. Sizes of the hole are selected based on the condition of free accommodation of the predominant part of the implant. Implant is inserted into the cavity of the bed with the projections resting on the spongy layer of the bone. Then the implant is screwed into the bone in several turns for fixation. Shape of the implant is optimized to intensify the osteointegration of the immediately loaded implant. Reduced traumatic effect on bone of screw elements of implant with provision of immediate biomechanical load. Bone tissue particles are compacted in the chip groove on the top of the implant. Increased reliability of osteointegration.

EFFECT: higher survival rate of the implant.

5 cl, 6 dwg

Description

The invention relates to medical equipment, namely to screw-type endosteal load-bearing structures intended for immediate loading after implantation. The primary areas of application of the technical solution are prosthetic dentistry and orthopedics of the musculoskeletal system.

For immediate loading of a screw implant, its high primary biomechanical stability in the bone is required, which is ensured by the structural elements of the device. However, these elements can further injure the bone and lead to further disruption of the osseointegration process, which in practice increases the percentage of rejections.

From patent document US 8932059 B2 dated January 13, 2015, a dental screw implant is known, made with a variable height profile of the turns due to different heights of the two-way threads. A thread with a larger coil profile height serves to give the implant primary stability, and a smaller thread is designed to increase the area of contact between the implant and the bone, which has a positive effect on the process of further osseointegration. The size of the thread turns specified in the known design, which ensures the primary stability of the implant, requires a force to screw in the device that can cause traumatic bone stress and compression necrosis, followed by resorption, and ultimately rejection of the implant. The risk of rejection is high due to the occurrence of bone tissue necrosis along the entire length of the implant in the area of the top of the thread with a higher thread profile. In this case, there is a danger of connecting focal areas of necrosis, which reduces the blood supply to the damaged area and slows down tissue repair. Due to the large pitch of the thread turns, which ensures the primary stability of the known implant, the load on the bone surrounding the implant is so uneven that in the immediate vicinity of the surface of the thread with a higher profile height of the thread turns, foci of bone tissue necrosis may appear. However, alternating threads with different coil profile heights does not allow making an implant with a smaller thread pitch, since this will violate the target properties of the coils of the other thread. In addition, the lead angle of the two-way thread is too high to eliminate the risk of spontaneous rotation of the implant under the influence of axial forces. On the body of the known implant, chip grooves with cutting edges are formed. The helical shape of the grooves ensures the removal of bone particles from the head of the implant body into its middle part during installation of the device. In addition, the grooves stabilize the implant and give it anti-rotation properties. However, in this case, the bone mass in the grooves is greatly loosened, which increases the duration of the restoration process and reduces the effectiveness of the indicated properties of the grooves.

Also from the mentioned patent document there is known a method for installing an intraosseous screw implant made with a variable height profile of the turns, the overall shape of the body in the middle and cervical parts is characterized by a narrowing towards the apex. According to the known method, a bone bed for the implant is first formed, which has the form of a hole narrowed towards the bottom. The implant is then sequentially screwed into the cortical and cancellous bone layers to secure it. However, in this case, thread turns with a higher profile height pass through the hole from the surface of the bone to the bottom of the bed, which is why they have a repeated traumatic effect on the bone tissue with each rotation of the implant body.

The technical problem, the solution of which is provided by using the present invention, is the creation of objects of the invention, devoid of the disadvantages of the known device and method, including optimization of the shape of the screw implant from the condition of intensifying the process of osseointegration of the immediately loaded implant, increasing the reliability of such osseointegration, as well as increasing the survival of the said implant.

The technical result achieved by this invention is to reduce the traumatic effect on the bone of the screw elements of the implant while ensuring that they bear the immediate biomechanical load applied to the implant, as well as to increase the density of bone tissue particles in the chip groove at the top of the implant.

The technical result is achieved due to the fact that the intraosseous screw implant, made with a variable thread profile height, contains such turns of the helix line that within each of them at least one protrusion with an increased thread profile height, having a shorter length compared to the length of the turn, is localized thread. In this case, these protrusions are located on adjacent turns and are mutually offset along the angle. In an alternative embodiment of the device, the protrusions are separated from each other through a coil.

In a particular case of the invention, the protrusions are formed in the middle part of the implant body and are placed on its surface in a checkerboard pattern.

In another particular case, straight chip grooves are made at the top of the implant body, turning into helical chip grooves in the middle part of the implant body. In this case, these grooves divide the thread to form rows of blades, and blades with different profile heights alternate along the thread.

In another special case, blades with different profile heights alternate in each row.

Also, the technical result is achieved due to the fact that for the installation of an intraosseous screw implant, the overall shape of the body of which in the middle and cervical parts is characterized by a narrowing towards the apex, containing such complete turns of the helical line that within each of them at least one protrusion with increased height of the thread profile, first a bone bed is formed in the form of a tapering hole, the dimensions of which are selected from the condition of freely accommodating the predominant part of the implant with an emphasis on the spongy layer of bone of the protrusions with an increased height of the thread profile. Then the implant is inserted into the cavity of the bed until it stops, and then screwed into the bone to secure it.

The essence of the invention is illustrated by the following drawings, which show two main designs of a dental root-shaped implant as preferred examples of technical solutions.

Fig. 1-2: general view of the implant and cross-sections of its body.

Fig. 3-4: alternative design of the implant, general view and cross-sections.

Fig. 5-6: schematic cross-sectional representation of an implant with one and two protrusions with an increased thread profile height.

The presented technical solution is a supporting-retaining endosteal part of a device intended for one-stage dental implantation with immediate loading of an orthopedic structure.

On the lateral surface of the body of the implant 1, retention elements are made, having the form of an external screw thread 2 in the middle and apical parts of the body 1 (Figs. 1 and 2), providing the possibility of primary and secondary stability of the implant in the cancellous layer of bone. A retention screw microthread 3 is cut on the neck of the body 1 to secure the implant in the thick and dense cortical bone layer.

On the body 1 there are three open peripheral grooves, each of which consists of interconnected chip grooves 4 and 5, dividing the thread 2 into longitudinal rows of blades in the form of separate segments of intermittent threads with cutting edges. In each row, the blades are shifted along an axial angle. The chip grooves 4 on the top of the body 1 are straight, since they are located parallel to the longitudinal axis of this body. The chip flutes 5 in the middle part of the body 1 have a helical configuration and serve as a continuation of the straight chip flutes 4. Three separate helical chip flutes 6 are formed on the neck of the body 1.

Thread 2 is made single-stroke and consists of a single thread with a small angle of inclination of the turns, sufficient to form 7-10 full turns of thread in the middle and apical parts of the body of 1 implant. If on the neck of the implant, instead of microthread 3, thread 2 is cut (Figs. 3 and 4), which is acceptable in the case of a thin cortical layer, then the number of turns of thread 2 exceeds the specified values.

The helical thread line 2 is characterized by a variable height of its profile due to the fact that within the full turns of the helical line in the middle and apical parts of the body 1, thread protrusions 7 are localized, each of which represents a protruding part of the body 1, limited by the helical surface of the thread and having the form of a blade with an increased height of the thread profile 2 (Fig. 2 and 4). Microthread 3 is made without protrusions.

The geometric parameters of the thread elements are selected from the following system of independent inequalities.

Where:

W ₀ - base height of thread profile;

W ₁ - height of the thread protrusion profile;

α is the angular length of the thread protrusion;

β is the mutual angular displacement of the thread projections.

Each protrusion 7 is characterized by a greater height of the thread profile W ₁ relative to the base height of the profile W ₀ of the given thread. The base height W ₀ is selected from the condition of minimizing the time of tissue healing and osseointegration of the implant, and the height W ₁ of the protrusions 7 is selected from the condition of ensuring the maximum possible primary stabilization when an immediate load is applied to the device after implantation. The angular length α of the protrusion 7 is smaller than the angular length of the full turn of the thread 8 (Fig. 5), which is 360°. Moreover, the edges of the protrusions 7 on adjacent turns are shifted relative to each other by an angle β (Fig. 6). Blades with different heights of turns alternate along the thread. Since the device contains an odd number of rows of blades, they alternate in each row. In an alternative embodiment of the device, the projections are distributed over the surface of the middle part of the implant in a checkerboard pattern.

The top of body 1 is rounded. The overall shape of body 1 in the middle and cervical parts is characterized by a slight narrowing towards the apex. In general, the body 1 has a circular cross-section.

The body of the implant 1 is made of titanium alloy, zirconium dioxide or similar medical material with suitable properties.

Installation of a screw implant into the bone is carried out in one stage as follows.

First, a bone bed is formed in the form of a tapered blind hole using a conical or stepped drill. The size of the drill is selected from the condition of its compliance with the overall shape of the implant, so that it is possible to freely insert the body of the implant 1 into the prepared hole approximately two-thirds of the length of this body. Then the implant is inserted into the cavity of the bed to the specified depth with the protrusions 7 resting primarily on the spongy layer of bone, the microthread 3 is located in close proximity to the cortical bone layer. To ensure primary stability of the implant, body 1 is screwed into the bone 2-3 full turns. In this case, the cutting edges of the blades form particles of the spongy layer of bone, which are first compacted by the walls of the straight chip grooves 4, and then move into the middle part of the body 1 by helical chip grooves 5. Particles of the cortical layer are retracted by the grooves 6. After completion of the fixation of the implant body 1 in the bone to An abutment and denture are attached to the implant.

Over time, osteoclastic processes occur at the implantation site, leading to the removal of bone tissue damaged by the helical blades of body 1, due to which the primary stability of the implant gradually decreases. However, at the same time, secondary stability increases due to the development of osseointegration, which fully covers first the compressed bone particles in the chip grooves 4, and then the particles in the grooves 5, 6.

The traumatic effect on the bone of the screw elements of the implant, while ensuring the immediate biomechanical load is carried, is reduced due to the reduction in the size of the threads bearing the immediate load. At the same time, the value of the primary stability of the implant is left unchanged due to an increase in the number of thread elements bearing immediate load, which makes it possible to maintain a sufficiently large working area of the thread surface, ensuring the primary stability of the implant. The increase in the number of these elements is ensured by combining sections within the turns both to maximize primary stabilization when applying immediate load to the device after implantation, and to minimize the time of tissue healing and osseointegration of the implant, for which the thread thread contains at least two full turns, within each of which at least one protrusion with an increased thread profile height is localized. Also, the reduction in the size of the threads bearing the immediate load is ensured by a more uniform distribution of the biomechanical load on the bone surrounding the implant. Uniform distribution of the load is achieved by making the indicated protrusions on adjacent thread turns with mutual displacement along the angle or through the turn, which ensures the separation of different types of implant retention elements from each other. To increase the uniformity of load distribution on the tubular bone layer, it is advisable to make protrusions on the thread in the middle part of the implant body and place them on its surface in a checkerboard pattern. When making a thread in the form of rows of blades, increasing the uniformity of load distribution is preferably ensured by alternating blades with different profile heights along the thread. If, in this case, blades with different profile heights also alternate in each specified row, then the magnitude of the uniformity of load distribution is maximum, which makes it possible to optimize the size of the thread projections. Spacing the thread projections in space prevents the risk of combining focal areas of necrosis and creates conditions for increasing the blood supply to damaged areas and rapid repair of bone tissue, since when necrosis occurs, its zones are localized by the thread projections and are displaced relative to each other, due to which the blood supply to limited necrotic areas is increased, which leads to accelerated osseointegration and reduces the risk of implant rejection.

In addition, the traumatic effect on the bone of the screw elements of the implant, while ensuring the immediate biomechanical load is carried, is reduced due to the implementation of the implant with a narrowing towards the top of the overall shape of its body in the middle and cervical parts. To install this implant, the bone bed is formed in the form of a tapering hole, the dimensions of which are selected from the condition of freely accommodating the predominant part of the implant with an emphasis on the spongy layer of bone of the protrusions with an increased height of the thread profile, which avoids repeated traumatic effects on the bone when screwing the implant into the bone to secure it. bone tissue with each rotation of the implant body, since for reliable fixation of the implant in the bone, only a few full rotations of the implant around the longitudinal axis are sufficient without creating unwanted overheating of the bone, leading to tissue necrosis. In this case, protrusions with an increased thread profile height do not pass through the cortical part of the bone and do not damage this layer, in which only the microthread is fixed on the neck of the implant body.

Making the implant body with chip grooves ensures the collection and accumulation of bone tissue particles during the installation of the device, and during the process of osseointegration gives the implant stability and anti-rotation properties. Moreover, thanks to straight chip grooves, the density of bone tissue particles at the top of the implant is increased due to the compression of these particles, which leads to an acceleration of the process of restoration of bone tissue in this area and prompt manifestation of the stability of the implant and its anti-rotation properties, since the resulting bone tissue stops the implant. In addition, due to the chip grooves, which occupy the entire length of the implant body, multiple cutting edges of the thread blades are formed, thanks to which, when installing the implant, it is not necessary to apply great force with traumatic consequences. Helical flutes also provide increased torsional mechanical rigidity of the implant body, which has a positive effect on further osseointegration.

The connection between the implant and the bone is sufficiently strong, including due to the design of the implant body with a one-way thread, which reduces the risk of unwanted rotation of the endosteal part of the implant under the influence of axial forces applied to the prosthesis.

This optimization of the shape of the screw implant leads to an intensification of the osseointegration process of the immediately loaded implant, an increase in the reliability of such osseointegration, and as a result, to an increase in the survival rate of the implant.

Claims (5)

1. An intraosseous screw implant made with a variable thread profile height, characterized in that it contains such turns of the helix line that within each of them at least one protrusion with an increased thread profile height and having a shorter length compared to the length of the thread turn is localized , wherein said protrusions are located on adjacent turns and are mutually offset along the angle or are separated from each other through a turn. 2. The implant according to claim 1, characterized in that the protrusions are formed in the middle part of the implant body and are placed on its surface in a checkerboard pattern. 3. The implant according to claim 1, characterized in that at its top there are straight chip grooves, turning into helical chip grooves in the middle part of the implant body, while these grooves divide the thread to form rows of blades, and along the thread the blades alternate with different profile heights. 4. The implant according to claim 3, characterized in that blades with different profile heights alternate in each row. 5. A method for installing an intraosseous screw implant, the overall shape of the body of which in the middle and cervical parts is characterized by a narrowing towards the apex, containing such turns of the helical line that within each of them at least one protrusion with an increased height of the thread profile is localized, including the formation of bone a bed in the form of a tapering hole, the dimensions of which are selected from the condition of freely accommodating the predominant part of the implant with emphasis on the spongy layer of bone of the protrusions with an increased height of the thread profile, after which the implant is inserted into the cavity of the bed until it stops, and then screwed into the bone for fastening.

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