RU2849408C1 - Bone expandable orthopedic screw - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to bone screws for dental, orthopaedic, surgical or bone grafting applications, such as orthopaedic screws alone or with plates, dental or ligament implants for joints such as, for example, hips, elbows, ankles, shoulders and knees, or spinal implants for the spine, for example for vertebrae, more specifically, the invention relates to an expandable orthopaedic bone screw, the implantation of which in porous bone is extremely stable. The expandable orthopaedic bone screw comprises an expandable sleeve (2) and a screw body (1). The expandable sleeve (2) is arranged along a longitudinal axis (L) between a proximal section (22) having a first inner diameter and a distal section (23) having a second internal diameter smaller than said first internal diameter, said first and second internal diameters thereby characterising the internal profile of said expandable sleeve (2). The expandable sleeve (2) contains, on one side, a first internal thread (20) inside the expandable sleeve (2) and, on the other side, a second external thread (21) outside the expandable sleeve (2). The body (1) of the screw is located along the longitudinal axis (L) between the proximal section (12) and the distal section (13) and has, on one side, along the specified longitudinal axis (L), an external profile complementary to the specified internal profile of the specified expandable sleeve (2), and, on the other side, an external thread (11) whose pitch is opposite to the pitch of the second external thread (21) of the expandable sleeve (2). The bone screw is designed to be able to transition from a collapsed initial configuration to an expanded configuration by means of a interaction between the specified threads with opposite directions , causing the body (1) of the screw into the expandable sleeve (2) and creating expansion of said expandable sleeve (2) by deformation, thanks to the outer diameter of the body (1) of the screw, which, at least in the distal section, is greater than said second inner diameter of the expandable sleeve (2), in accordance with the tapered part (271). In the expanded configuration of the bone screw, the expandable sleeve (2) has a second inner diameter greater than or equal to its first inner diameter. The expandable sleeve (2) has a cylindrical shape or a truncated conical section formed as a result of the expansion. The bone screw has, near its proximal section in the expanded configuration, a proximal truncated conical section that increases towards the proximal section and is formed either by the outer profile of the expandable sleeve (2), or by the outer profile of the specified screw body (1), or by the complementary shape of the outer profiles of the expandable sleeve (2) and the screw body (1) in the expanded configuration, wherein the specified proximal truncated conical section has an external thread (15) for attachment to the bone along its periphery.

EFFECT: invention is easily implanted into bone tissue and is stable.

13 cl, 13 dwg

Description

FIELD OF TECHNOLOGY AND OBJECT OF INVENTION

The present invention relates to the field of bone screws for dental, orthopedic, surgical, or osteoplastic applications, such as orthopedic screws alone or with plates, dental or ligament implants for joints such as, for example, hips, elbows, ankles, shoulders, and knees, or spinal implants for the spine, for example, for vertebrae. These areas of application are given as examples and do not limit the scope of the present invention.

More specifically, the invention relates to an expandable orthopedic bone screw, the implantation of which into porous bone is extremely stable.

LEVEL OF TECHNOLOGY

An expandable orthopedic bone screw essentially consists of an elongated main part intended for implantation into a skeleton formed in bone tissue, such as the jawbone for dental applications, or, for example, in a vertebra.

It is important that an expandable orthopedic bone screw can be easily inserted into the bone tissue without causing damage, and that the anchoring device within the bone tissue is stable. Indeed, modern expandable orthopedic bone screw devices do not allow fixation without causing more cracks or damage to the bone tissue than is required for the size of the device itself. Furthermore, bone screw fixation must be reliable and extremely stable, as many therapeutic techniques today rely on bone growth, which generally requires that devices anchored in bone tissue remain as immobile as possible.

In addition, it is also necessary that implantation into the bone tissue is easy to perform in order to avoid any risk of incorrect positioning of the bone screw, which may be, in particular, due to difficulties in positioning or implantation in the bone tissue.

Furthermore, in the event of a fall, impact, or accident, it's important that the screw remains in place within the bone tissue, meaning it doesn't move. This requires extremely high screw stability.

The prior art includes patent document EP 2603163 B1, which describes an endosseous screw with improved anchorage that can be implanted into bone tissue and includes a fixation device comprising a part called an engaging part in bone tissue and a part called an extending part, wherein these two parts are movable relative to each other. The invention mentioned in this patent also includes the interaction of a mechanical connection unit located, on one side, on the engaging part, and on the other side, on the extending part, in such a way that the relative mobility of both parts is at least one degree of freedom and that the relative displacement of said two parts causes expansion of the engaging part, wherein said expansion causes the engaging part to be captured in bone tissue. The bone screw described in this patent is particularly applicable in the field of dentistry.

However, this solution has disadvantages, since the bone screw, despite its immobility for rotation and movement in the tissue, is at risk of movement, in particular displacement during impact.

The invention therefore aims to address these disadvantages by providing a bone screw that can be implanted and immobilized in bone tissue in an extremely stable manner.

SUMMARY OF THE INVENTION

Thus, the present invention aims to overcome the disadvantages of the prior art by providing an expandable orthopedic bone screw, hereinafter referred to as a bone screw, which is easily implanted into bone tissue and is stable.

To achieve this result, the present invention relates to a bone expandable orthopedic screw comprising:

an expandable sleeve located along the longitudinal axis between a proximal portion having a first internal diameter and a distal portion having a second internal diameter smaller than said first internal diameter, said first and second internal diameters thereby characterizing the internal profile of said expandable sleeve, and comprising, on the one hand, a first internal thread inside the expandable sleeve and, on the other hand, a second external thread outside the expandable sleeve,

a screw body located along the longitudinal axis between the proximal portion and the distal portion and having, on the one hand, along said longitudinal axis, an external profile complementary to said internal profile of said expandable sleeve, and, on the other hand, an external thread, the pitch of which has a direction opposite to the direction of the pitch of said second external thread of the expandable sleeve,

wherein the bone screw is configured to transition from a folded initial configuration to an expanded configuration by engaging said threads in opposite directions, causing the screw body to penetrate the expandable sleeve and creating an expansion of said expandable sleeve by deformation, due to the outer diameter of the screw body, which, at least in the distal portion, is larger than said second inner diameter of the expandable sleeve, in accordance with the tapering portion,

wherein in the expanded configuration of the bone screw, the expandable sleeve has a second internal diameter greater than or equal to its first internal diameter,

characterized in that

the expandable sleeve has a cylindrical shape or a truncated-conical section formed as a result of said expansion,

The bone screw has, near its proximal portion in an expanded configuration, a proximal truncated-conical portion that increases towards the proximal portion and is formed by:

or the external profile of the specified expandable sleeve,

or the external profile of the specified screw body,

either by complementarity of the shape of the external profiles of the expandable sleeve and the screw body in the expanded configuration,

wherein the said proximal truncated-conical section has an external thread for fastening to the bone along its periphery.

In a preferred embodiment, said tapering portion is located relative to the proximal portion and along the longitudinal axis, at a distance determined depending on the depth of penetration into the bone tissue at which said expansion is required.

In a preferred embodiment, the screw body is designed to be implanted into bone tissue by being immersed in an expandable sleeve, wherein its proximal portion comprises an external thread for fastening to the bone, designed to be implanted into bone tissue, and has a truncated-conical external profile at its proximal portion, the opening angle of which is opposite to that of the truncated-conical portion of the expandable sleeve in the expanded configuration.

In a preferred embodiment, the screw body is designed to be implanted into bone tissue by being immersed in an expandable sleeve, wherein its proximal portion comprises an external thread for fastening to the bone, designed to be implanted into the bone tissue, and has a cylindrical external profile in its proximal portion.

In a preferred embodiment, said truncated-conical section of the proximal section of the expandable sleeve and said truncated-conical outer profile of the screw body are located opposite each other.

In a preferred embodiment, the angle of the truncated-conical portion of the proximal portion of the expandable sleeve is greater than the angle of the truncated-conical outer profile of the screw body to provide greater expansion and improve primary stability.

In a preferred embodiment, said screw body comprises at least one distance marker for visualizing the moment when the screw body should be screwed into the expandable sleeve in a direction opposite to the screwing of the expandable sleeve into the bone tissue.

In a preferred embodiment, the thread height of the second external thread of the expandable sleeve is greater than that of the rectangular first internal thread of the expandable sleeve and the external thread of the screw body.

In a preferred embodiment, said bone screw further comprises a conical rod, wherein the distal portion of the expandable sleeve has a truncated-conical portion containing a thread on the conical rod of the bone screw, which provides the expandable sleeve with the ability to penetrate deeply into the bone.

In a preferred embodiment, the distal portion further comprises self-tapping recesses.

In a preferred embodiment, the expandable sleeve further comprises longitudinal through-slots extending upward to the distal portion.

In a preferred embodiment, the number of self-tapping recesses corresponds to the number of longitudinal through slots.

In a preferred embodiment, the expandable sleeve further comprises longitudinal blind slots.

BRIEF DESCRIPTION OF GRAPHIC MATERIALS

Other characteristics and advantages of the invention will be apparent from reading the detailed description of embodiments of the invention, given only by way of example and with reference to the graphic materials, in which:

[Fig. 1a], [Fig. 1b] and [Fig. 2] show a detailed view of the elements that make up a bone screw according to the invention.

[Fig. 3a] shows a detailed view of the expandable sleeve before expansion in accordance with the invention.

[Fig. 3b] shows a detailed view of the expandable sleeve after expansion in accordance with the invention.

[Fig. 3c] shows a detailed view of the proximal truncated-conical section in the deployed position, formed by the outer profile of the sleeve, in accordance with the invention.

[Fig. 4a] and [Fig. 4b] show a cross-sectional diagram of the inner portion of the bone screw sleeve before expansion of the expandable sleeve according to the invention.

[Fig. 5] shows a detailed view of the proximal truncated-conical section in the deployed position, formed by the external profile of the screw, in accordance with the invention.

[Fig. 6] and [Fig. 7] show a diagram of a bone screw in an expanded position in accordance with the invention.

[Fig. 8] and [Fig. 9] show a view of the expandable sleeve in an expanded position in accordance with the invention.

[Fig. 10a], [Fig. 10b] and [Fig. 11] show a view of the inside of a bone screw in an expanded position in accordance with the invention.

[Fig. 12] shows a diagram of a screw tip in accordance with the invention.

[Fig. 13] shows a detailed view of the proximal truncated-conical section in the deployed position, formed by the outer profiles of the screw and sleeve, in accordance with the invention.

DETAILED DESCRIPTION OF ONE EMBODIMENT OF THE INVENTION

Various embodiments of the invention are described below, in particular with reference to illustrative and non-limiting figures.

The present application relates to the implantation of a bone screw into bone tissue.

It should be noted here that the term "implantation" refers to the insertion of a bone screw into bone tissue, essentially by screwing it in. Implantation, as proposed in this application, means sufficiently strong and stable insertion of a bone screw to ensure proper retention of the bone screw in the bone tissue.

Additionally, the term "bone tissue(s)" essentially means all types of bones, regardless of whether they are compact bones (such as cortical bone or periosteum) or spongy (soft, porous) bones, since the bone screw system of the present application is implantable in any type of bone tissue.

Additionally, the terms used should not be interpreted in their general meaning, but rather should be understood in light of the functional aspects described in detail in this application.

[Fig. 1a], [Fig. 1b] and [Fig. 2] are illustrative and non-limiting examples of the embodiment of a bone screw.

As shown, for example, in [Fig. 1a], [Fig. 1b] and [Fig. 2], a bone screw adapted to be implanted into bone tissue comprises: an expandable sleeve (2) extending between a proximal portion (22) and a distal portion (23), the ends of these two portions defining a longitudinal axis (L) and comprising, on the one hand, at least a first thread (20) inside the expandable sleeve (2) and, on the other hand, at least a second thread (21) outside the expandable sleeve (2).

The terms "proximal" and "distal" in the present application mean, respectively, the part in which the implantation device is held to ensure its implantation into the bone tissue, and the part that is implanted first into the bone tissue (opposite the proximal portion).

The terms "proximal and distal portions" in this application mean portions located in the immediate vicinity of the distal and proximal ends.

In the present application, the term "expandable sleeve (2)" essentially denotes a hollow generalized cylinder.

In some embodiments, the bone screw also comprises a screw (1) extending between the proximal portion (12) and the distal portion (13) along an axis collinear with the axis (L) and having, on the one hand, along said longitudinal axis (L), an external profile complementary to the internal profile of said expandable sleeve (2) and, on the other hand, at least one external thread (11), the thread pitch of which is opposite to said second external thread (21) of the expandable sleeve (2).

It should be noted that the proximal portion (12) of the screw (1) is implanted directly into the cortical bone substance.

In some embodiments, the proximal end of the screw (1) comprises a drive means that allows the screw (1) to be screwed in, wherein said drive means has a design of any shape required by the healthcare professional, depending on its application, as, for example, shown in [Fig. 1b]. The drive means is, for example, a hexagonal hole, or a star-shaped hole, or a cross-shaped hole, or any other drive means, and the proximal end of the screw (1) can have various shapes depending on the desired purpose of the bone expandable orthopedic screw (a head for fixing a polyaxial or non-polyaxial beam for osteosynthesis, or for fixing a plate or any other device).

In some embodiments, the screw (1) comprises a cannula passing through the screw (1), which allows the healthcare professional to inject, for example, cement if he deems it necessary.

It should be noted that the bone screw is made of titanium, or implantable medical stainless steel, or polyetheretherketone (PEEK), or polyetherketoneketone (PEEK), or any other material that can be determined by those skilled in the art to be acceptable based on its mechanical, physicochemical properties and its biocompatibility.

In some embodiments, the screw (1) comprises a cannula passing through the screw (1), which allows the healthcare professional to inject, for example, cement if he deems it necessary.

In some embodiments, the second thread (21) outside the expandable sleeve (2) provides bone anchorage. The term "bone anchorage" as used in the present application generally denotes various types of devices comprising at least one element designed to penetrate bone tissue in a straight line under the action of a push, essentially exerted in the form of repeated screwing, impact or striking operations. It is known that the thread for fastening to the bone has a thread height that is substantially greater than that of the mechanical thread in order to provide better anchorage. In addition, the thread for fastening to the bone is substantially different from the mechanical thread, and those skilled in the art know that depending on the type of bone and the desired application, the core diameter, the thread pitch and the height of the wire ligature can be varied, and the present application covers these various embodiments. The thread height of the second external thread (21) of the expandable sleeve (2) is greater than the mechanical thread of the first thread (20) inside the expandable sleeve (2) and the external thread (11) of the screw. (1) Thus, the second thread (21) has higher edges compared to the first thread (20) for inserting the bone screw into the bone and securing it therein.

Additionally, in some embodiments, certain mechanical threads, such as trapezoidal threads, offer less resistance, facilitating penetration of the screw (1) into the expandable sleeve (2) anchored in the bone. Trapezoidal threads also allow greater bone compression loads to be distributed to the bone screw.

In some embodiments, the distal portion (23) of the expandable sleeve (2) has a truncated conical portion (291) containing a thread (232) with a conical core allowing the expandable sleeve (2) to be deeply inserted into the bone, such as shown in [Fig. 1a]-[Fig. 4b].

In some embodiments, the distal section (23) of the sleeve (2) is self-tapping and comprises self-tapping (milling and cutting) recesses (231), as shown, for example, in [Fig. 3a]-[Fig. 4b]. This distal section (23) allows for bone preservation during implantation, while avoiding pre-drilling before inserting the screw, and thus allows for the preservation of the maximum amount of bone around the implantation area, which increases the stability of the bone screw. Indeed, the osseointegration time is reduced in this way, which limits the need to add any type of bone filling material, synthetic or natural. Additionally, the distribution of the recesses (231) ensures proper balance between each part of the distal section (23) and, thus, proper uniformity of force distribution during insertion of the screw into the bone tissue.

In some embodiments, the screw (1) comprises at least one distance marker (16), as shown in [Fig. 2], to visualize the moment when the screw (1) should be screwed into the expandable sleeve (2) in the direction opposite to the screwing of the expandable sleeve (2) into the bone tissue.

In some embodiments, the distance marker (16) is a laser marker.

In some embodiments, screw placement comprises the following steps:

screwing the bone screw in the direction of the external thread (21) until the distance marker (16) is level with the surface of the cortical bone,

screwing in the bone screw by screwing in the direction of the second thread (11) to complete the screwing of the threaded screw (1) into the bone and proceeding to the expansion of said expandable sleeve (2).

In some embodiments of the invention, the cortical bone is perforated using a cortical perforation instrument.

The present application also relates to the expansion of a bone screw in bone tissue.

In some embodiments, the outer profile of the screw (1) and the inner profile of the expandable sleeve (2) are complementary so that in the expanded configuration they provide:

proximal bearing supported by the complementarity of the outer diameter of the screw (1) with the inner diameter of the expandable sleeve (2),

a distal bearing supported by the interaction between an expandable sleeve (2), the internal diameter of which tapers towards the distal portion until it becomes smaller than the external diameter of the screw (1), and the screw (1),

"central" bearing located between these two bearings, formed by the interaction between the outer diameter of the screw (1) and the inner diameter of the expandable sleeve (2), which create an outer diameter of the expandable sleeve (2) at the "central" level that is larger than the outer diameter of the expandable sleeve (2) at the proximal bearing.

In some embodiments, such as shown in [Fig. 4a] and [Fig. 4b], the screw is capable of moving from a folded rest position to an expanded position by actuating a reverse thread, causing the screw (1) to penetrate the expandable sleeve (2) and creating an expansion of said expandable sleeve (2) by deformation, due to the fact that the outer diameter of the screw (1) is larger than the inner diameter of the expandable sleeve (2) by at least one tapering portion (271) at the distal portion.

In some embodiments, the tapering portion (271) is located relative to the proximal portion and along the longitudinal axis (L) at a distance determined depending on the depth within the bone tissue at which said expansion is required. It should be noted that said distance is determined by the healthcare professional himself, in particular with respect to the cortical bone substance and/or the desired compression, as shown, for example, in [Fig. 4a] and [Fig. 4b].

In some embodiments, the intermediate section between the proximal end and the distal end of the expandable sleeve (2), the channel of which is larger than the diameter of the location of the central bearing, has a difference in diameter.

In some embodiments, the channel of the expandable sleeve (2) of the intermediate section between the proximal end and the distal end has a variable slope. Thus, the tapered portion (271) can be positioned at a variable distance from the proximal end to provide expansion at different depths depending, for example, on the bone type.

In some embodiments, the proximal portion of the screw (1) includes: an external thread (15) for attachment to the bone, as shown, for example, in [Fig. 1a], [Fig. 1b] and [Fig. 2].

In some embodiments, the screw (1) is configured to be implanted into bone tissue by being immersed inside an expandable sleeve (2), wherein its proximal portion, containing an external thread (15) for fastening to the bone, is configured to be implanted into bone tissue and has a truncated-conical portion, the flare of which is opposite to the flare of the proximal portion of the expandable sleeve (2) in the deployed position, as shown, for example, in [Fig. 11]. To change the direction of flare of the two truncated cones, compression and/or friction is required, which improves the stability of the screw, in particular due to the fact that these two truncated cones are located around the cortical substance of the bone.

In some embodiments, the screw (1) is designed to be implanted into bone tissue by being immersed in an expandable sleeve (2), wherein its proximal portion comprises an external thread (15) for fastening to the bone, designed to be implanted into bone tissue, and has a cylindrical portion or a portion of any offset shape.

The resulting inverted double cone allows for gradual screw insertion, distributing the bone screw's forces within the bone tissue during implantation, allowing the forces to be transmitted along a conical surface rather than a cylindrical line. Furthermore, the inverted double cone ensures axial locking of the cortex of the most dense vertebrae. Thus, it contributes to the bone screw's hyperstability within the bone tissue.

In some embodiments, such as shown in [Fig. 3a], the expandable sleeve (2) has an acute angle α at the end of its distal portion (23). This angle α opens and increases as the screw (1) enters the expandable sleeve (2) during expansion.

In some embodiments, such as shown in [Fig. 3b], the angle α, which opens more and more during expansion, becomes angle β, wherein angle β represents the angle of the expanded expandable sleeve (2).

In some embodiments, such as that shown in [Fig. 3c], the cortex compresses the bone screw and the cortex has an angle γ created by the expandable sleeve (2) or the screw (1), or both. The angle α, which opens more and more, becomes the angle β of the expandable sleeve (2) and is opposed to the angle γ.

It should be noted that in the deployed position, the walls of the expandable sleeve (2) may, in some embodiments, be parallel instead of creating an angle β.

In some embodiments, the expandable sleeve (2) has a dome-shaped form on the central bearing, as shown, for example, in [Fig. 5], due to the presence of angles α and β.

Indeed, in some embodiments, the screw is configured to expand between, on the one hand, a rest configuration in which the abutment mechanism (26) interlocks said expandable sleeve (2) and said screw body (1) by reversing the direction of these two thread pitches, as shown, for example, in [Fig. 1a], [Fig. 1b], [Fig. 4a], [Fig. 4b], [Fig. 6], [Fig. 8]-[Fig. 10b], and, on the other hand, an expanded configuration obtained by the actuation of said complementary internal and external threads of the expandable sleeve (2) and the screw (1) mutually, causing the penetration of the screw (1) into the expandable sleeve (2) and creating an expansion of said expandable sleeve (2) due to the external diameter of the screw (1), which is larger than the internal diameter of the expandable sleeve (2) at least in the distal section, due to the deformation of the expandable sleeve (2) when the screw (1) penetrates into the expandable sleeve (2).

In some embodiments, in the expanded position of the screw, the second distal diameter of the expandable sleeve (2) is greater than or equal to the first proximal diameter of the sleeve (2), so that the sleeve (2) has a cylindrical shape or a truncated-conical section obtained due to said expansion.

The screw has, near its proximal section in the deployed position, a proximal truncated-conical section that expands towards the proximal section and is formed by:

or along the external profile of the said expandable sleeve (2), as, for example, shown in [Fig. 3c], in modes where the angle γ is created by the expandable sleeve (2),

or along the external profile of the said body (1) of the screw, as, for example, shown in [Fig. 5], in modes where the angle γ is created by the screw (1),

or in a shape complementary to the external profiles of the sleeve (2) and the body (1) of the screw, in the deployed position, as, for example, shown in [Fig. 13], in modes where the angle γ is created by the screw (1) and the expandable sleeve (2).

The said proximal truncated-conical section has an external thread (15, 215) for attachment to the bone along its periphery.

In some embodiments, in the deployed position of the screw, the expandable sleeve (2) has a truncated-conical shape at at least one proximal portion (22), as shown, for example, in [Fig. 5]-[Fig. 10b], expanding towards the distal portion of the screw (1) near the proximal portion.

In some embodiments, the expandable sleeve (2) has a cylindrical or conical shape at least in one proximal portion (22).

In some embodiments, the screw (1) comprises a tip (17) at the end of the distal portion (13), such as shown in [Fig. 1a], [Fig. 1b], [Fig. 2], [Fig. 5], [Fig. 10a], [Fig. 10b] and [Fig. 12], the outer profile of which is complementary to the inner profile of the distal portion (23) of the expandable sleeve (2).

In some embodiments, said truncated-conical section of the proximal section of the expandable sleeve (2) and said truncated-conical outer profile of the screw (1) are located end to end or facing each other and connected to the proximal section (22) of the expandable sleeve (2), wherein the angle of said truncated-conical section of the proximal section of the expandable sleeve (2) is greater than the angle of said truncated-conical outer profile of the screw (1), which allows for greater flaring and/or facilitates expansion of the whole.

In some embodiments, such as shown in [Fig. 2], [Fig. 3], [Fig. 5], [Fig. 6], [Fig. 7] and [Fig. 8], the expandable sleeve (2) includes longitudinal through slots (24) extending upward to its distal portion (23) and longitudinal blind slots (25) that provide expansion of the expandable sleeve (2). It is preferable to have several through (24) and blind (25) slots, and for the distal portion (23) to include two types of slots, i.e. longitudinal through slots (24) and longitudinal blind slots (25).

In some embodiments, the synergy between the through slots (24) and the blind slots (25) also provides a truncated cone geometry and/or a dome shape in the deployed position.

In some embodiments, there are as many self-tapping recesses (231) as longitudinal through slots (24).

In some embodiments, the through slots (24) and the blind slots (25) are arranged offset relative to each other along the length of the expandable sleeve (2). The offset of the through slots (24) and the blind slots (25) along the length increases the flexibility and mechanical strength of the expandable sleeve (2) during expansion.

In some embodiments of the invention, expansion of the bone anchorage is possible (15, 215).

In some embodiments, longitudinal through (24) and blind (25) slots in the distal section (23) provide cylindrical expansion of the expandable sleeve (2). The longitudinal blind slots (25) promote the stability of the bone screw in the bone tissue by providing the ability to maintain a contact profile on three bearings between the expandable sleeve (2) and the screw (1) during expansion and by providing a uniform distribution of forces caused by expansion along the periphery of the expanded expandable sleeve (2). The longitudinal through (24) and blind (25) slots provide radial expansion of the proximal section (22) of the expandable sleeve (2) by maintaining the elastic limit of the material of the expandable sleeve (2) and its elastic tapering portion during unscrewing.

In some embodiments, said longitudinal through slots (24) occupy from 10 to 90% of the length of the expandable sleeve (2).

In some embodiments, such as shown in [Fig. 3a], the portion of the expandable sleeve (2) includes a cone angle alpha (α) at the bottom of the thread, ensuring self-centering of the expandable sleeve (2) in the cavity formed by the tool for anatomical conical matrices with the shape of the expandable sleeve (2) during the screwing operation.

According to one alternative embodiment (not shown), the screw (1) does not include a portion with a cortical thread. This embodiment allows for a shorter screw (1) and expandable sleeve (2) assembly, adapted to other implantation conditions.

Those skilled in the art will appreciate that various types of tips and structures can be added to the proximal portion of the screw (1) in accordance with other assembly modes by adapting the shape of this portion to the intended purpose and the screw's intended purpose. As non-limiting examples, these assemblies can be fabricated using screws, clamps, dowels, adhesives, or welding.

Thus, the bone screw proposed in the invention can be quickly and accurately implanted into bone tissue and remain implanted in the bone tissue in a very stable manner.

This application describes various technical characteristics and advantages with reference to figures and/or various embodiments. Those skilled in the art will recognize that the technical characteristics of a given embodiment may indeed be combined with the characteristics of one or more other embodiments, unless expressly stated to the contrary, or unless these characteristics are incompatible, or unless the combination fails.

More generally, combinations of various types of screw retention means and/or spinal retention means are envisaged, which will be understood by those skilled in the art using the functional and structural aspects provided in this application. Furthermore, the technical characteristics described in this embodiment may be separated from other characteristics of this mode, unless expressly stated otherwise, in particular because the functional aspects provided in this application will provide sufficient explanation so that structural adaptations that may be necessary will be feasible for those skilled in the art.

Those skilled in the art, after reading this application, will understand that embodiments in many specific forms other than those described in detail are possible without departing from the claimed scope of the present invention. Therefore, the present embodiments should be considered as illustrative, but they can be modified within the scope defined by the appended claims, and the invention should not be limited to the above details.

Claims (24)

1. A bone expandable orthopedic screw comprising: an expandable sleeve (2) located along the longitudinal axis (L) between a proximal portion (22) having a first internal diameter and a distal portion (23) having a second internal diameter smaller than said first internal diameter, said first and second internal diameters thereby characterizing the internal profile of said expandable sleeve (2), and comprising, on the one hand, a first internal thread (20) inside the expandable sleeve (2) and, on the other hand, a second external thread (21) outside the expandable sleeve (2), a screw body (1) located along the longitudinal axis (L) between the proximal section (12) and the distal section (13) and having, on the one hand, along said longitudinal axis (L) an external profile complementary to said internal profile of said expandable sleeve (2), and, on the other hand, an external thread (11), the pitch of which has a direction opposite to the direction of the pitch of said second external thread (21) of the expandable sleeve (2), wherein the bone screw is configured to transition from a folded initial configuration to an expanded configuration by engaging said threads with opposite directions, causing the screw body (1) to penetrate into the expandable sleeve (2) and creating an expansion of said expandable sleeve (2) by deformation, due to the outer diameter of the screw body (1), which, at least in the distal portion, is larger than said second inner diameter of the expandable sleeve (2), in accordance with the tapering portion (271), wherein in the expanded configuration of the bone screw, the expandable sleeve (2) has a second internal diameter greater than or equal to its first internal diameter, characterized in that the expandable sleeve (2) has a cylindrical shape or a truncated-conical section formed as a result of said expansion, The bone screw has, near its proximal portion in an expanded configuration, a proximal truncated-conical portion that increases towards the proximal portion and is formed by: or the external profile of the specified expandable sleeve (2), or the external profile of the specified body (1) of the screw, or by means of complementarity of the shape of the external profiles of the expandable sleeve (2) and the body (1) of the screw in the expanded configuration, wherein the said proximal truncated-conical section has an external thread (15, 252) for fastening to the bone along its periphery. 2. A bone screw according to claim 1, characterized in that said tapering portion (271) is located relative to the proximal portion and along the longitudinal axis (L), at a distance determined depending on the depth of penetration into the bone tissue at which said expansion is required. 3. A bone screw according to claim 1 or 2, characterized in that the body (1) of the screw is designed with the possibility of implantation into bone tissue by immersion into an expandable sleeve (2), and its proximal section contains an external thread (15) for fastening to the bone, designed with the possibility of implantation into bone tissue, and has a truncated-conical external profile at its proximal section, the opening angle of which is opposite to that of the truncated-conical section of the expandable sleeve (2) in the expanded configuration. 4. A bone screw according to claim 1 or 2, characterized in that the body (1) of the screw is designed with the possibility of implantation into bone tissue by immersion into an expandable sleeve (2), and its proximal section contains an external thread (15) for fastening to the bone, designed with the possibility of implantation into bone tissue, and has a cylindrical external profile in its proximal section. 5. A bone screw according to claim 3, characterized in that said truncated-conical section of the proximal section of the expandable sleeve (2) and said truncated-conical outer profile of the body (1) of the screw are located opposite each other. 6. A bone screw according to claim 5, characterized in that the angle of the truncated-conical section of the proximal section of the expandable sleeve (2) is greater than the angle of the truncated-conical outer profile of the body (1) of the screw to ensure greater expansion and improve primary stability. 7. A bone screw according to claim 6, characterized in that said screw body (1) contains at least one distance marker (16) for visualizing the moment when the screw body (1) is to be screwed into the expandable sleeve (2) in a direction opposite to the screwing of the expandable sleeve (2) into the bone tissue. 8. A bone screw according to any of the preceding paragraphs, characterized in that the thread height of the second external thread (21) of the expandable sleeve (2) is greater than that of the rectangular first internal thread (20) of the expandable sleeve (2) and the external thread (11) of the body (1) of the screw. 9. A bone screw according to any of the preceding claims, characterized in that it further comprises a conical rod, wherein the distal section (23) of the expandable sleeve (2) has a truncated-conical section (291) containing a thread (232) on the conical rod of the bone screw, providing the expandable sleeve (2) with the ability to penetrate deeply into the bone. 10. A bone screw according to any of the preceding claims, characterized in that the distal portion (23) further comprises self-tapping notches (231). 11. A bone screw according to any of the preceding claims, characterized in that the expandable sleeve (2) additionally comprises longitudinal through slots (24) extending upward to the distal portion (23). 12. A bone screw according to claim 11, characterized in that the number of self-tapping notches (231) corresponds to the number of longitudinal through slots (24). 13. A bone screw according to any of the preceding paragraphs, characterized in that the expandable sleeve (2) additionally contains longitudinal blind slots (25).