• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The device comprises at least two flanges (6), each flange (6) with the end in the form of thread and a mobile anchor (7) with a projection (8), and a prosthesis (1) with transverse curvature and molding to adapt longitudinally to the curvature of the rib in the area where it will be located. It comprises projections (5) along the central axis (2) to prevent sliding of the prosthesis (1) in the rib and holes (4) for the insertion of the projections (7) of the flanges (6). After locating each fracture to be treated in the same rib, the flanges (6) are fixed to the prosthesis (1) in positions that are on both sides of each fracture to ensure the alignment of the rib. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2574759A1
    申请号:ES201431722
    申请日:2014-11-21
    公开日:2016-06-21
    发明作者:Jose Maria BORRO MATE
    申请人:Jmborro S L;Jmborro SL;
    IPC主号:
    专利说明:

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    DESCRIPTION
    OBJECT OF THE INVENTION
    The object of the present invention consists of a device formed by a prosthesis that allows aligning and fixing fractured ribs by means of flanges that it incorporates, restoring the anatomy of the thorax, reducing pain and enabling the early incorporation of the patient into his habitual life.
    TECHNICAL PROBLEM TO BE SOLVED AND BACKGROUND OF THE INVENTION
    The main function of the thoracic cage is to maintain a rigid structure that allows, with diaphragmatic movements, to create a negative pressure inside so that it expands the lungs, allowing the exchange of gases and, therefore, the oxygenation of the organism.
    Costal fractures are one of the few bone fractures in the body whose treatment does not usually include alignment and fixation. This is mainly due to the structure of the thoracic cage, similar to a rigid cage covered in its entire outer surface by thick muscular structures, which causes the rib fractures, even multiple, as long as they occur at a single level, do not modify the function of the thoracic cage and, therefore, allow lung ventilation to continue.
    Another reason for the costal fixation of fractures is rarely assessed is the need for surgery, and important muscle sections must be made to free the fractured ribs and proceed to fix them.
    However, the rib fracture is very painful, since to the fact that the fracture is always painful, we join the need to move the thoracic cage and the fractured rib itself with each of the respiratory movements, as well! as with the violent movements produced by sneezing or coughing. The pain, usually intense, will make us unconsciously avoid coughing, breathing deeply, which facilitates the development of atelectasis and lung infections, even in spite of systematic analgesics, especially in older people, smokers or patients with pathologies pulmonary
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    previous. Therefore, it would be important to be able to immobilize the fracture by means of costal fixation to reduce pain and complications subsequent to it.
    If multiple fractures include the lower edge of the rib cage or occur at several levels, of more than one contiguous rib, the so-called "costal volet" usually destabilizes the thoracic cage structure and prevents the function of pulmonary ventilation correctly, by making it difficult to achieve the necessary negative pressure, which is why these are the fractures in which the rib fixation is usually indicated and performed in selected cases.
    In the last 40 years, different procedures for fixing rib fractures have been developed, which we can summarize in three main types:
    - Metal bar or resorbable material, placed on the outside of the fractured rib, usually fixed with screws along the bar itself.
    - Metallic bar with various lateral arms on both sides of the bar which, placed on the outside of the fractured rib, allows its immobilization by hugging it with the lateral arms (Judet, Stratos type).
    - Nails or intramedullary rods. Using the nails, a rigid portion is fixed to the rib on both sides of the fracture. The rods are introduced into the rib through an opening made in the vicinity of the fracture, creating an intramedullary reinforcement of the rib that joins the two parts of the fracture.
    All these interventions require the realization of an important incision, of a size that is directly proportional to the number and disposition of the fractures to be repaired and the consecutive muscle sections that allow the fractured ribs to be released.
    In fact, the muscular section that is necessary to perform for the costal repair has been an inconvenience for the fixation of the first 3-4 ribs, since the posterior scapula and the anterior pectoral forced the section of these important muscle groups, reason why the fixation was only carried out when it was necessary to perform thoracotomy due to complications of the thoracic trauma itself.
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    In any case, the treatment of rib fractures usually depends on the number of ribs affected, whether the fracture is at one or several levels, the patient's clinical condition and the need or not of thoracotomy for possible associated injuries.
    At present, the treatment of rib fractures is often conservative if the expected sequelae are not important or if the patient needs ventilation assisted by his clinical situation.
    On the other hand, video-assisted surgery is a relatively new surgical procedure that has modified thoracic surgery in the last 20 years. It is a little aggressive method that requires a small incision of about 3 cm and a minimum incision for optics, which allows us to reach anywhere inside the thoracic cavity. Finding the right prosthesis can provide an extraordinary approach to initially assess and treat lesions associated with them! how to align and fix the fractured ribs.
    The main advantages of this type of approach in thoracic trauma will be:
    - Diagnose and treat the main post-traumatic lung, vascular, etc. problems early.
    - The internal placement of the prostheses will be facilitated by the fact that the ribs in the inner part of the costal wall are only covered with the parietal pleura, so the fixation will not require the muscular section for its exposure and placement.
    - Access to all ribs at any previous, middle or later level.
    With all this, it is intended to achieve early recovery of the patient and avoid frequent sequelae and post-traumatic complications.
    The present invention describes a device formed by a prosthesis that allows aligning fractured ribs and fixing them by means of flanges that it incorporates, so that it eliminates the aforementioned problems by providing a fixation with minimal invasion and a high effectiveness in the costal fixation, reducing post-traumatic pain , decreasing
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    complications and restoring the anatomy of the thorax that should allow the early incorporation of the patient into his usual life.
    DESCRIPTION OF THE INVENTION
    The present invention relates to a device for the treatment of rib fractures comprising an elongated prosthesis formed by a central axis with lateral protrusions on both sides of the central axis. The width of the prosthesis will range between 10 and 14 mm in the widest area of the prosthesis and the length will depend on the type of fracture to be fixed. The prosthesis incorporates holes along the central axis.
    The device also comprises at least two flanges that are fixed to the prosthesis and by which the prosthesis is fixed to the rib.
    The flanges incorporate a mobile anchor with a projection for fixation in the prosthesis. The end of the flanges is shaped like a thread, for later manipulation using a Reverdin needle.
    The prosthesis is slightly concave in width, that is, it has transverse curvature, and is longitudinally moldable, so that it adapts to the curvature of the rib in the area where it is located. It also includes cones-shaped projections along the central axis to prevent the sliding of the prosthesis in the rib, and central holes for the insertion of the projections of the flanges and create the fixing of the flanges in the prosthesis.
    The prosthesis is fixed to the rib by means of the flanges that are previously fixed to the prosthesis. Once the prosthesis is placed on a rib, the flanges positioned on both sides of the fracture, the flanges are closed, tensioned and the remaining ends are removed.
    The flange has the known anti-return system that facilitates the fixation to the rib, so it is preferable to a conventional ligature.
    The flange should have the smallest possible thickness (between 1 and 2 mm) to facilitate its passage around the rib, about 6-8 cm in length followed by a resistant thread and of progressively decreasing thickness to facilitate the passage of the flange around the rib
    The prosthesis is positioned on a rib and fixed to it by placing flanges that, by proper tension, ensure fracture alignment and immobilization of
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    the rib. The flanges are placed on each side of the fracture detected, and there may be more than the minimum necessary for greater safety.
    Both the prosthesis and the flanges are made of biocompatible and resorbable material by the body.
    The prosthesis is made of rigid and moldable material, such as titanium or polyether ether ketone, known as PEEK. The flanges are also made of flexible biocompatible polyether ether ketone or similar material. Both the prosthesis and the fixation system are also carried out in biodegradable material which would facilitate its resorption after the fracture callus was consolidated.
    BRIEF DESCRIPTION OF THE FIGURES
    To complete the invention that is being described and in order to help a better understanding of the features of the invention, according to a preferred example of realization thereof, a set of drawings is attached where, with illustrative character and not limiting, the following figures have been represented:
    - Figure 1 represents a perspective view of the prosthesis of the invention.
    - Figure 2 represents a plan view and a side sectional view of the fixing flange.
    - Figure 3 represents a perspective view of a thoracic box with the device of the invention placed in fractured ribs.
    A list of the references used in the figures is given below:
    1. Prosthesis.
    2. Central axis.
    3. Lateral protrusions.
    4. Holes.
    5. Highlights.
    6. Fixing flange.
    7. Mobile anchor.
    8. Projection for flange fixing.
    DESCRIPTION OF A PREFERRED EMBODIMENT OF THE INVENTION
    The present invention describes a rigid and moldable linear prosthesis (1) for alignment
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    of fractured ribs and fixing to the ribs by means of flanges (6).
    The prostheses (1) are factory-made with linear geometry and a slight curvature in the transverse direction to accommodate the rib more easily. Due to the ability to be modeled, the prostheses (1), in all cases, will be retouched to present a slight curvature in the direction of the central axis (2) to adapt to the rib in which it will be implanted.
    The prosthesis (1) is of variable dimensions. The width is a function of the rib to be treated, which will depend mainly on the sex and age of the patient. The length of the prosthesis (1) depends on the extent and type of fracture of the rib to be intervened.
    As shown in Figure 1, the prosthesis (1) is formed by a linear central axis (2) that has lateral protrusions (3) protruding perpendicularly on two opposite sides along the entire length of the central axis (2). ), like a fish bone. Throughout the central axis (1), the prosthesis has holes (4) to facilitate the molding of the prosthesis (1) and lighten the weight.
    The lateral protrusions (3) also have a slight curvature in the direction perpendicular to the central axis (2) that give the prosthesis (1) a concave geometry to serve as a cradle to the rib itself in which it is to be incorporated.
    The fixation of the prosthesis (1) to the affected rib is done with a non-return belt system, flange type (6) that, after tensioning it, does not allow tension to be lost.
    Figure 2 represents a plan and side view of the flange (6) used in the present invention.
    As shown in Figure 2, the flanges (6) include a movable anchor (7) that can be moved along the flange (6). The anchor (7) incorporates a projection (8) that is inserted into one of the holes (4) with which the prosthesis (1) has along the entire length of the central axis (2). In this way, there is a pre-assembly of the flanges (6) to the prosthesis (1) that facilitates the subsequent fixation of the assembly to the affected rib. With the pre-assembly it is possible to avoid that the flanges (6) separate from the prosthesis (1) or have to be placed once the prosthesis (1) is positioned in the rib. This projection (8) is of a diameter that corresponds to the diameter of the hole (4) of the prosthesis (1) in which it will be fixed, and
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    of a length similar to the thickness of the prosthesis, so that it is long enough so that the flange (6) does not detach easily from the prosthesis (1), and short enough that it does not protrude from the prosthesis ( 1) and be an obstacle to the alignment of the prosthesis (1) in the rib.
    The prosthesis (1) has along its entire length, interspersed between the holes (4), some protrusions (5) with conical geometry, like spikes, which have the function of immobilizing the prosthesis (1) with respect to the rib and do not slip when it is fixed to it.
    Unlike the prostheses (1), the size of the flanges (6) is fixed, about 8-10cm in length and 1.5mm in width. It must have an additional extension at its end in the form of a wire between 20 and 30 cm. This extension is necessary for the manipulation of the flange (6) when it is placed and cut once it has been fixed to the prosthesis (1).
    The number of flanges (6) to be placed in a prosthesis (1) will depend on the size and number of the fracture of the rib, as many flanges (6) must be placed as necessary to achieve a total fixation of the rib that ensures its immobilization.
    In Figure 3 two fractured ribs can be seen in which two prostheses (1) fixed by means of the corresponding flanges (6) have been placed. It can be seen how the flanges (6) are placed on both sides of each fracture, these being the minimum acceptable conditions for a guarantee of immobilization. Thus, a rib with a fracture requires a minimum of two flanges (6) in the prosthesis (1), and a rib with two fractures requires a minimum of three flanges (6) if the fractures are very close, or, more advisable, four flanges (6) if the fractures are more separated.
    As for the manufacturing material, the prosthesis (1) has the requirement that it be rigid and moldable. The flange (6) must be flexible. Both the prosthesis (1) and the flange (6) are made in biocompatible materials. Preferred materials are titanium or polyether ether ketone as non-absorbable or a biocompatible polymer and preferably degradable those of the "Labtosorb" or "Inion" type that facilitate resorption by the prosthesis body (1) and flanges ( 6) once the fracture is resolved.
    The prosthesis is developed for placement by video loop inside the thoracic cavity, that is, fixed to the rib by the inner area of the thoracic cavity by means of the flanges (6).
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    By means of X-ray images or thoracic CT scan, the fracture is located and the type of prosthesis (1) to be placed is chosen, taking into account both the length and width of the prosthesis (1) necessary, depending on the number of fractures, the Fracture size and the patient's rib size.
    The current possibility of three-dimensional reconstruction of radiological images makes it possible to know precisely the shape of the rib and the location of the fracture (s) of the rib to be fixed. Being the material of the prosthesis (1) moldable, it allows the same geometry to be printed, so that it overlaps with all precision.
    To begin the placement of the prosthesis (1), it is initially positioned outside the thorax, simulating the interior placement. For this, the occasional help of a portable X-ray device can be used.
    Once the location of the fractures has been seen, as many flanges (6) are placed in the prosthesis (1) as deemed necessary and some points are marked in the thorax that will represent the puncture points for the manipulation of the device.
    Once the puncture points have been chosen, an entry incision is made in the patient's chest, located according to the area in which the fractures are located, so that work and vision for placement are facilitated.
    In this way, the prosthesis (1) is placed with the flanges (6) positioned in the corresponding holes (4) and positioned at the edge of the incision.
    After placing the flanges (2) aligned with the prosthesis (1), the prosthesis (1) is introduced into the thorax and placed in the fracture area using the flanges (6) as glues and with the help of a clamp of videoruugla.
    A Reverdin needle is inserted into the thorax in the marked area that indicates the reference point of the rib, and the end of the first flange (6), which is passed around the rib, is threaded into it. It goes out with the end of the flange on the needle on the opposite side of the rib, avoiding injuring the vasculonervious package.
    The end of the flange (6) is collected and passed through the closure of the flange (6). The flanges (6) are tightened with the necessary tension to achieve the alignment and fixation of the fractures.
    The maneuver is repeated with the rest of the flanges (6), which will usually be between 2 and 4.
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    Finally, the ends of the flanges (6) that exit the closure of the flanges (6) are cut to be removed.
    It is very important that the fixation of the prosthesis (1) on both sides of the fracture prevents its mobility, since it is the only way to avoid pain following the fracture movement.
    In any case, the present invention should not be limited to the embodiment described here for both the device and the method of placement. Other 15 configurations can be made by those skilled in the art in view of the present description. Accordingly, the scope of the invention is defined by the following claims.
    权利要求:
    Claims (6)
    [1]
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    1. - Device for the treatment of rib fractures comprising an elongated prosthesis (1) formed by a central axis (2) with lateral protrusions (3) located along the central axis (2) on two opposite sides, characterized by that:
    - comprises at least two flanges (6), each flange (6) with the thread-shaped end and a movable anchor (7) with a projection (8), and
    - the prosthesis (1) has transverse curvature and is moldable to adapt longitudinally to the curvature of the rib in the area where it is to be located, and comprises:
    - projections (5) along the central axis (2) to prevent sliding of the prosthesis (1) in the rib,
    - holes (4) for insertion of the projections (7) of the flanges (6),
    where, after the localization of each fracture to be treated in the same rib, the flanges (6) are fixed to the prosthesis (1) in positions that are left on both sides of each fracture to ensure the alignment of the rib.
    [2]
    2. - Device for the treatment of rib fractures according to claim 1,
    characterized in that both the prosthesis (1) and the flanges (6) are made of biocompatible materials.
    [3]
    3. - Device for the treatment of rib fractures according to claim 2,
    characterized in that the material is reabsorbable by the body.
    [4]
    4. - Device for the treatment of rib fractures according to claim 2,
    characterized in that the prosthesis is made of titanium.
    [5]
    5. - Device for the treatment of rib fractures according to claim 2,
    characterized in that the prosthesis is made in polyether ether ketone.
    [6]
    6. - Device for the treatment of rib fractures according to claim 2,
    characterized in that the flange is made of polyether ether ketone.
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    同族专利:
    公开号 | 公开日
    WO2016079365A1|2016-05-26|
    ES2574759B1|2017-04-06|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    WO2021047787A1|2019-09-09|2021-03-18|OROMI, Gaston Enrique|Elastic prosthetics of ribs|US5190545A|1991-08-27|1993-03-02|Pfizer Hospital Products Group, Inc.|Cerclage wire positioning insert|
    US20060276896A1|2005-06-02|2006-12-07|Medicinelodge, Inc.|Bone implants with integrated line locks|
    法律状态:
    2015-06-03| PC2A| Transfer of patent|Owner name: JMBORRO S.L. Effective date: 20150528 |
    2017-04-06| FG2A| Definitive protection|Ref document number: 2574759 Country of ref document: ES Kind code of ref document: B1 Effective date: 20170406 |
    2017-10-26| FA2A| Application withdrawn|Effective date: 20171020 |
    优先权:
    申请号 | 申请日 | 专利标题
    ES201431722A|ES2574759B1|2014-11-21|2014-11-21|DEVICE FOR THE TREATMENT OF COSTAL FRACTURES|ES201431722A| ES2574759B1|2014-11-21|2014-11-21|DEVICE FOR THE TREATMENT OF COSTAL FRACTURES|
    PCT/ES2015/070829| WO2016079365A1|2014-11-21|2015-11-19|Device for treating rib fractures|
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