GR1009280B - Orthopaedic screw furnished with suitable insertion-and-removal tool - Google Patents

Abstract

Novelty: an orthopaedic screw equipped with a suitable insertion- and-removal tool is disclosed. Constitution: two main screwable parts (1,2) connected via a flexible material 3 (e.g. a spring industrially compatible to the ligament destined to be replaced). The connection is achieved either by embedding or mechanical action so that the system can be able to behavior as a unified system characterized by resilient mechanical return. The screwable part 1 is surgically positioned on the proximal part and the screwable part 2 on the upper part of the bone of the other articular or fractured surface. The flexible material 3 is, thus, placed on the fracture point or the joint space under replacement. Advantages: placement of the screw through a little incision without damaging the surrounding soft tissues and causing iatrogenic injuries (minimally invasive surgery). It substitutes two or more systems of ligaments found at both sides of the articulation.

Description

DESCRIPTION

Orthopedic screw with positioning tool

The invention refers to screws (screws) widely used in orthopedics.

Screws in orthopedics are mainly used to repair fractures and anchor bones or other parts in various ways and techniques. The technical field of the invention concerns the restoration of ligament injuries of small and large joints as well as their use in fracture repair as osteosynthesis material.

Attempts have been made to treat these injuries by suturing the ligaments, by placing autografts or allografts, artificial or not, in place of the torn ligament.

Stitching links has advantages and disadvantages. Its advantage is that the restoration is done with the same biological tissue. Its disadvantage is that the access to find the torn ligament is difficult, for example in the bones of the wrist, causing much greater injuries even than the rupture of the ligament itself. Regarding the placement of allografts, in many cases their placement technique presents disadvantages since it is difficult to impossible to achieve especially in small joints where technical grafts cannot be placed or if placed also cause great damage. Autologous grafts are also often difficult to obtain and often lead to high morbidity and complications from the site of receipt. Fixation of grafts also presents disadvantages since fixation in small joints is problematic and cumbersome leading to detachment and rapid wear of the graft and thus to surgical failure. Many times two operations are required for the ligamentous stabilization of a joint as for example in the scaphoid joint. Finally, surgical access with technical grafts generally shows disadvantages since it is difficult to impossible, especially in small joints due to the fact that the surgical field is very small.

According to this invention, the treatment of the above difficulties and disadvantages is achieved by using the special flexible orthopedic screw.

The invention concerns the placement and anchoring of this special screw on either side of the two bones of the joint or on either side of the descending parts of the bone, with its two threaded ends and which has an intermediate part which is flexible and extensible, with properties corresponding to biomechanics behavior of the link to be replaced. In the case of fractures, the screw as an osteosynthesis material facilitates the perforation due to the micromotion it allows.. This flexible screw is placed as a single body, inside the adjacent bone ends and interosseous spaces, in contrast to the current state of the art where independent articulated parts are placed which are installed piecemeal but mainly without the functional property of elastic self-restoration due to the turning joints and generally the way they are constructed and connected.

It differs from the previous state of the art in that, the orthopedic screw we mention, due to its screw ends which are connected by means of mechanical compression with an intermediate flexible part, constitute a single new type of autonomous screw, which through its special internal lumen allows, (through a special tool - a screwdriver), to be placed and withdrawn only through an entry portal without damaging the surrounding soft tissues or causing iatrogenic injuries since a large skin incision is not required, nor the complete opening of the joint or the fracture site, ( minimally invasive screw insertion).

Also, because it is placed along the longitudinal axis of the two adjacent bone segments to replace systems of two or more ligaments in space, (located on either side of the joint) it exhibits automatic elastic return to the original equilibrium position, due to its unitary construction.

In the case where it is placed transfracture, it allows multiaxial micro-movements in order to improve the pore size of the fracture.

It also differs from the prior art in that the internal hexagonal or other configuration (5) of the lumen (4) greatly facilitates the insertion and extraction of the screw through the same entry port.

It also differs from the prior art in that the nozzle at the distal end of the screw is combined with a specially made screwdriver which extends intraluminally securing the screw, thus allowing safe and easy withdrawal (unscrewing), without trapping the distal end of the screw since considerable axial pulling force is required when removing the screw (although whenever necessary).

The invention is described below by way of example and with reference to the accompanying drawing, in which: figure 1 shows in

sectioning the orthopedic cochlea according to the present invention.

Figure 1 shows two threaded parts (1) and (2) of metal or plastic composite material (e.g. titanium alloy or steel), which are connected to each other, with a stem of flexible material (3) biomechanically compatible with the joint to be replaced or if placed as osteosynthesis material to allow relative micromotion. The connection is made with permanent compaction, so as to ensure elastically and independently (without the influence of external forces) the mechanical restoration of the system to the original equilibrium position. Various materials can be used for the flexible material (3), such as metal polymeric materials, with a suitable geometry, e.g. a spring shown in figure 1 area (3), or a spring of another suitable geometry such as, as well as various meshes, e.g. stent type used in vascular surgery, as long as they satisfactorily simulate the biomechanical properties of the ligament under repair. The threads of parts (1) and (2) may be of the same or different pitch and diameter.

The screw (1) is surgically placed in the proximal part of the bone of one articular surface and the screw (2) in the distal part of the bone of the other articular surface with the help of a metal guide of suitable diameter. The flexible material (3) is thus placed in the medial space to be restored.

The orthopedic screw is guided to the two bones to be replaced through a central guide through the lumen (4) which initially passes through the bones in the appropriate position due to the mass of the bones and is hexagonal or of another type of internal configuration (5).

The central (1) and peripheral (2) threaded portions of Figure 1 are constructed to allow the flexible portion (3) to be anchored by chemical, thermal bonding or other mechanical means of permanent setting, and also to allow mechanical interconnection between them so that screwing is implemented, i.e. the simultaneous rotation of parts (1) and (2) of figure 1. That is, when part (1) rotates, part (2) rotates accordingly.

Also, the screw sections (1) and (2) have such a step as to allow the controlled compression of the two bone articular sections.

Also the installation as well as the withdrawal of this screw, figure 1, requires a special screwdriver, figure 2, which is slotted (1) and accepts two diameter guides, one for inserting the screw (smaller diameter guide) and one for removal of the screw (larger diameter driver), and has an outer perimeter hexagonal configuration (3) and handle (2). The insertion-withdrawal screwdriver, Figure 2, terminates in a through slot (4) and internal narrowing of the tip (5), so that the whole mechanism by inserting the larger diameter guide (suitable diameter) is radially expanded and wedged into the peripheral end of screw (2) in Figure 1 to ensure screw withdrawal.

Claims (10)

1) Orthopedic screw, figure 1, with threads at both ends (1) and (2) characterized by the fact that the connection of the two ends is made by a stem (3) of flexible material. The connection of the two ends (1), (2) with the stem (3) is made by chemical, thermal gluing or another mechanical method of permanent compaction, in order to ensure elastic and independent (without the influence of external forces) the mechanical reset of the system in the initial equilibrium position. The compaction does not allow independent turns of parts (1), (2), and (3), that is, the connection of parts (1), (2), and (3) is not hinged. The construction is a single screw with flexible properties in its middle part (3) that allows relative movement (rotations and extensions) in all axes in space. The flexible material (3) consists of a spring of a suitable geometry as shown in figure 1 area (3), or a spring of another suitable geometry. The two threaded ends (1) and (2) also have an internal groove (4) that serves as a guide for the placement of the screw, with a hexagonal or other internal configuration (5), for the insertion of a tool (retraction screwdriver), figure 2, in order to achieve the insertion and extraction of the screw into the bones. The "head" of the screw (6) has an external thread which can be screwed into the bone or into an osteosynthesis plate with a corresponding thread. The screw insertion-retraction screwdriver, figure 2, which is slotted (1) and receives two diameter guides, one for inserting the screw (smaller diameter guide) and one for removing the screw (larger diameter guide), and has outer perimeter hexagonal configuration (3) and handle (2). This screwdriver ends in a through slot (4) and internal narrowing of the tip (5), so that the whole mechanism by inserting the larger diameter guide (suitable diameter) expands radially and wedges into the distal end of the screw (2) in Figure 1 to ensure screw withdrawal. 2)  Orthopedic screw as described in claim 1 characterized in that the flexible stem (3) consists of a polymeric material biomechanically compatible with the ligamentous joint under repair. 3) Orthopedic screw as described in claim 1, characterized in that the flexible stem (3) consists of a metallic material such as steel, titanium or alloys, biomechanically compatible with the ligamentous joint under repair. 4) Orthopedic screw as described in claim 1, characterized in that the flexible stem (3) consists of a composite material, e.g. metal with polymer, biomechanically compatible with the ligamentous joint under repair. 5) Orthopedic screw as described in claim 1, characterized in that the flexible stem (3) consists of a metallic material, e.g. stainless steel, titanium or bellows or accordion-type alloys with sections of suitable geometry, so as to be industrially compatible with the ligament under repair joint. 6) Orthopedic screw as described in claim 1, characterized in that the flexible part (3) consists of a metal mesh of the "stent" type, used in vascular surgery, of stainless steel, titanium or various alloys, biomechanically compatible with the ligament under repair joint. 7) Orthopedic screw as described in all the above claims characterized in that the threads of the parts (1), (2) and (6) are of different pitch, length and diameter. 8) Orthopedic screw as described in all the above claims characterized in that the threads of the parts (1), (2) and (6) are of the same pitch and diameter. 9) Orthopedic screw as described in all the above claims characterized in that the "head" of the screw (6) has a conical shape. 10)  Orthopedic screw as described in all the above claims characterized in that the "head" of the screw (6) has 1 or more elongated slots running the entire length of the thread of the head.