巴西专利BR112013020351B1 external orthopedic fixator for elbow joints and kit

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专利摘要:
EXTERNAL ORTHOPEDIC FIXER FOR ELBOW JOINTS AND KIT An external orthopedic fixator (1) for elbow joints comprising: proximal anchoring device (2) intended to be integrally associated with a proximal bone (100) of a patient's upper limb; the distal anchoring device (3) intended to be integrally associated with a distal bone (101) of a patient's upper limb; an articulator (4) that articulates together with said proximal (2) and distal (3) anchoring devices along a geometric axis of articulation (x), intended to be positioned in correspondence with an elbow joint (102) that connects to the proximal (100) and distal (101) bones; said articulator (4) comprising a radiolucent centering window (40) intended to frame the elbow joint (102) when the external orthopedic fixator (1) is positioned, said articulation axis (x) passing through said window centralization (40).
公开号:BR112013020351B1
申请号:R112013020351-0
申请日:2011-09-09
公开日:2020-11-17
发明作者:Andrea Ottoboni；Daniele Venturini
申请人:Orthofix S.R.L；
IPC主号:

专利说明:

FIELD OF THE INVENTION
[001] The present invention applies to the field of orthopedic surgery and refers to a device for treating fractures and joint stiffness in the elbow joint.
[002] In particular, the device is an external articulated fixator of the type comprising a proximal part and a distal part, intended to be associated respectively with a humerus and ulna of a patient's upper limb, being articulated with each other by means of an articulator arranged in correspondence with the elbow joint. BACKGROUND OF THE INVENTION
[003] The flexion contracture of joints due to the treatment of joint joint trauma or other causes (inflammation, burns, arthritis), assumes particular clinical importance in terms of the frequency and extent of disability.
[004] In fact, even small contractures (about 30 ° to 40 °) considerably reduce the functionality of the upper limb. In many cases, the recovery of mobility after contracture, through rehabilitation or distraction arthroplasty, may be limited or prevented by pain and / or swelling, with a significant shortening of the tendon muscle on both sides of the joint.
[005] Some techniques, such as early active movement, general therapy, continuous passive movement (CPM), can be used to confront the problem, but they do not guarantee in any way that the problem will be solved.
[006] Early active movement can reduce the severity of the contracture, but it requires constant commitment and effort on the part of the patient.
[007] In general therapy, passive stretching performed with the help of a therapist can cause formation of heterotopic bone and ossifying myositis.
[008] Finally, CPM devices allow rapid mobility recovery, but they do not reach the ends of the cinematic movement, which is where the need for rehabilitation is greatest.
[009] From the above, it is clear that there is a need for external fixators for elbow joints, which, in addition to allowing the joint to be protected in the event of fracture or instability, also allow the joint to be deflected towards rehabilitation purposes.
[010] These fasteners should allow the elbow joint to move both actively and passively, reproducing the entire kinematic movement generally allowed for a healthy joint and promoting the extension of the soft tissue at the flexion and extension end positions.
[011] At the moment, there are only a few orthopedic devices that meet these requirements, with limited effectiveness.
[012] In fact, articulated external fixators on the market are not specifically designed for the rehabilitation of joint stiffness and therefore they have a number of disadvantages that make them unsuitable for the purpose.
[013] The first disadvantage stems from the difficulty of centralizing and repositioning the external fixator in relation to the elbow joint. In fact, this centralization is hindered both by the components of the radiopaque fixator that reduces the visibility of the bone joint, and by the difficulty in identifying the geometric axes of articulation of the device.
[014] Another disadvantage stems from the fact that external fixators on the market do not allow complete kinematic movement of the elbow joint with which they are associated.
[015] An additional disadvantage is due to the size and excessive weight of the currently known elbow joint fasteners.
[016] The technical problem underlying the present invention is, therefore, to provide an external orthopedic device for the elbow joints that resolve one or more of the aforementioned disadvantages and that is the most suitable possible to solve the joint stiffness. DESCRIPTION OF THE INVENTION
[017] The technical problem mentioned above is solved by an external orthopedic fixator for elbow joints comprising: proximal anchoring device intended to be integrally associated with a proximal bone of a patient's upper limb; distal anchoring device intended to be integrally associated with a distal bone of a patient's upper limb; an articulator that articulates said proximal and distal anchoring devices along a geometric axis of articulation, intended to be positioned in correspondence with an elbow joint that connects said proximal and distal bones, where the articulator comprises a radiolucent centering window intended to frame the elbow joint when the external orthopedic fixator is positioned, said geometric articulation axis passing through said centralization window.
[018] It is also clear to a non-technician in the matter that the presence of the radiolucent window helps considerably in the stage of centralization of the geometric axis of the joint, which is generally recognized as the most critical stage of the intervention to implant the orthopedic fixator.
[019] Additional assistance in the centralization stage comes from radiopaque references in the centralization window that guide the centralization of the elbow joint.
[020] Furthermore, this centering window can advantageously comprise a central tube oriented along the geometric axis of articulation, to allow the possible insertion of a reference cable of the known type, such as, for example, a Kirchner cable .
[021] The proximal anchoring means may comprise at least one proximal rod connected to the articulator and fixed to the proximal bone by means of endostep pins supported by at least one proximal clamp.
[022] In a particularly advantageous embodiment, said proximal clamp comprises a first coupling element arranged to lock proximal end pins, and a second coupling element arranged to lock the proximal stem, these coupling elements being articulated with each other by means of of a pivot pin comprising a head associated with the first coupling element and an associated leg as a second coupling element.
[023] Then, the second coupling element can be selectively rotated around the geometric axis of the pivot pin. Selectively rotating means that rotation can be advantageously blocked if necessary. For example, a nut can be used, associated with a threaded end of the pivot pin leg and intended to push, by fixing, the second coupling element against the first coupling element, thereby preventing its relative rotation.
[024] Furthermore, the pivot pin head can advantageously have an orifice, through which a geometric axis passes that is transverse to the first coupling element, so that said pivot pin is selectively rotatable with respect to said transverse geometric axis. In this case too, the expression “selectively rotating” indicates the possibility of blocking this rotation if necessary. For this purpose, it is possible to use the same nut that also blocks the rotation of the second coupling element with respect to the geometric axis of the articulation pin. In addition, said transverse geometric axis can be defined by a fixing cam which becomes an additional degree of approach between the first and second possible coupling elements, then locking the joint more firmly between the elements of the proximal clamp.
[025] Said transverse geometric axis is preferably perpendicular to the geometric axis of the articulation pin and parallel to the geometric axis of fixation of said proximal endosseous pins, so that these endosseous pins have a wide range of orientation possibilities at their disposal.
[026] The aforementioned anchoring devices may comprise at least one distal rod connected to the articulator and fixed to the distal bone by means of distal endosseous pins.
[027] These distal endosseous pins can be supported by at least one distal clamp associated with the distal stem, which can advantageously allow three degrees of freedom between the stem and the pin (typically due to the stem's ability to slide axially in its housing, the pin's ability to slide axially in its housing and the possibility of angular adjustment between the coupling elements locking the rod and the pin).
[028] Alternatively, the distal endosseous pins can be directly supported by the distal stem and held in position by means of locks fixed to the distal stem through fixation means (for example, fixation screws). The distal stem and latches may have opposite cavities that work together to define the housings of the distal endosseous pins.
[029] This solution has the advantage of a clear structural cost reduction, in the price, however, of a lower operational flexibility, since the degree of rotational freedom characteristic of the coupling elements that form a clamp must be abandoned.
[030] In order to recover this degree of rotational freedom, in a particularly advantageous embodiment, the distal endosseous pins are supported by at least one swiveling overlapping insert on a base that is integral with the distal stem, a lock intended to maintain said endosseous pins in position being arranged above said insertion, said lock being lockable at the distal base through the fixing means (in particular a fixing screw).
[031] Said fixing devices can advantageously also allow the relative movement between said base and said insertion to be blocked.
[032] It is clear that the solutions described above, with specific reference to the distal and proximal anchorage of the external orthopedic fixator, must be taken as general advantageous solutions, so that it is certainly possible to apply one of the distal solutions to the proximal anchorage and vice versa .
[033] The articulator identified above may comprise an integral proximal junction part with the anchoring device and a distal junction part integral with the distal anchoring devices.
[034] The centering window can have a cylindrical geometry and define an articulation pin between the proximal junction part and the distal junction part.
[035] In particular, one of said distal or proximal junction parts can then comprise at least one pivot ring that is swivelable in an outer cylindrical periphery of that centering window, said centering window being integral with the other part of the junction.
[036] The solution described above performs a hinge in a low cost and effective way, ensuring the radiolucency of the central element that must be aligned with the elbow joint.
[037] The articulator can advantageously comprise joint locking devices arranged to block the relative rotation between the proximal joint part and the distal joint part. In particular, these devices may take the form of a hinge locking screw.
[038] The articulator can also comprise the articulation distraction devices arranged to allow a translation of the distal anchoring devices in relation to the proximal anchoring devices.
[039] These devices are extremely advantageous in recovering from joint stiffness in particular through distraction.
[040] The aforementioned translation preferably takes place along a geometric axis of distraction that is inclined by an angle of distraction with respect to the longitudinal geometric axis of the distal bone, said angle of distraction being comprised between 60 ° and 75 ° (preferably 66 °).
[041] The distal junction part defined above may comprise a coupling element articulated with respect to the proximal junction part and a distal connector integral with the distal anchoring devices, that distal connector being movable in a sliding way with respect to said element of coupling. In this case, the hinge distraction device can be arranged to create a translation of the distal connector with respect to the coupling element.
[042] The distal connector can comprise a sliding arm that is slidably inserted into a sliding housing of the coupling element, said articulation distraction device then having the shape of a screw for distraction control, comprising an associated swivel head with the sliding housing and one leg engaged in the sliding arm.
[043] The distal connector may comprise a distal connecting arm intended for longitudinally securing a distal rod of the distal anchoring device, the implied angle between the sliding arm and the distal connecting arm being between 105 ° and 120 ° ( preferably 114 °), in order to achieve the distraction angle defined above.
[044] The fixator may further comprise distraction blocking devices arranged to block the relative translation between the distal anchoring devices and the proximal anchoring devices. Such devices preferably take the form of a distraction lock screw intended to secure the two opposite edges that define the sliding housing of said sliding arm.
[045] The external orthopedic fixator according to the present invention can further advantageously comprise an auxiliary device that can be coupled to the articulator and which allows the relative rotation between the proximal and distal junction parts to be adjusted in a micrometric manner.
[046] The auXiliar device may comprise a box-shaped body, a rotating part (preferably of the plate type) that is rotatable associated with said box-shaped body and fixing devices intended to secure the box-shaped body and the fixation part with the proximal junction part and the distal junction part, respectively, or vice versa. This box-shaped body comprises a mechanical reduction gear wheel intended to transmit a rotational movement from a control component to a rotating part.
[047] In particular, the mechanical reduction gear wheel may comprise a gear wheel and an endless screw.
[048] Furthermore, this auxiliary device can be advantageously configurable according to two alternative configurations: a first configuration in which said rotating part is coupled to said control component by means of said mechanical reduction gear wheel; and a second configuration in which said rotating part is idle with respect to said control component.
[049] In particular, a drum can make said rotating part integral with said sprocket, the group formed by said rotating part, the drum and the sprocket being moved axially between: a position that corresponds to the first configuration of the auxiliary device , in which the toothed wheel engages the endless screw, and a position corresponding to the second configuration of the auxiliary device, in which the toothed wheel does not engage the endless screw.
[050] The auxiliary device further comprises the device for selectively limiting the permitted angular path between the box-shaped body and the rotating part. The term “selectively limit” means that this limitation is not inevitably due to the morphological aspects of the device, but it can be changed accordingly according to the user's needs.
[051] The device for selectively limiting the permissible angular path between the box-shaped body and the rotating part can be configured to define both a lower and an upper limit for said angular travel.
[052] In particular, said device for selectively limiting the permitted angular path between the box-shaped body and the rotating part may comprise a plurality of limiting holes in the rotating part and intended to house the limiting pins that interact with the limit stops of the box-shaped body.
[053] The auxiliary device described above gives several advantages to the external orthopedic fixator according to the present invention.
[054] In fact, this makes it possible to perform a controlled micrometric joint movement, to limit the joint to the desired angle of movement according to preference and even to apply a constant torsional load in time to be applied in any joint position .
[055] The external orthopedic fixator according to the present invention can be provided within a kit further comprising at least one distraction device to perform a joint deviation before implanting the fixative.
[056] This distraction device comprises a distal clamp equipped with a fixed part that can be associated with the patient's distal bone in the elbow joint and a movable part that can be associated with the anchoring device, said moving part being moved telescopically with respect to said fixed part.
[057] The distraction device is advantageously modeled in order to create a centering window that frames the articulation when the distraction device itself is positioned.
[058] In particular, this centering window of the bypass device can advantageously be realized by opposite cavities of the fixed part and the movable part of the distal clamp.
[059] Additional achievements and advantages will be apparent from the following detailed description of a series of preferred, but not exclusive, embodiments of the present invention, with reference to the accompanying drawings, given by way of non-limiting examples. BRIEF DESCRIPTION OF THE DRAWINGS
[060] Figure 1 is an axonometric view of an external orthopedic fixator according to the invention associated with an elbow joint; Figure 2 is an axonometric view, according to a different perspective, of the external orthopedic fixator of Figure 1; Figure 3 is an axonometric view, according to an additional different perspective, of the external orthopedic fixator of Figure 1; Figure 4 is an axonometric view of a detail of the external orthopedic fixator of Figure 1; Figure 5 is a sectional view of an element of the detail of Figure 4; Figure 6 is a view of the element of Figure 5 sectioned along the plane VI-VI defined herein; Figure 7 is an axonometric view of a detail of the external orthopedic fixator of Figure 1; Figure 8 is an axonometric view of a detail of an external orthopedic fixator according to a different embodiment; Figure 9 is an axonometric view of a detail of an external orthopedic fixator according to an additional different embodiment; Figure 10 is an exploded view of the detail in Figure 9; Figure 11 is an axonometric view of a detail of an external orthopedic fixator according to a different embodiment; Figure 12 is an axonometric view according to a different perspective from the detail of Figure 11; Figure 13 is a sectional view of an element of the external orthopedic fixator according to the invention; Figure 14 is an axonometric view of the element of Figure 13; Figure 15 is an exploded view of the element of Figure 13; Figure 16 is an axonometric view of an auxiliary device for the external orthopedic fixator according to the invention; Figure 17 is a plan view of the auxiliary device of Figure 16; Figure 18 is a view of the device of Figure 16 sectioned along the plane A-A defined in Figure 17; Figure 19 is a view of the device of Figure 16 sectioned along the plane B-B defined in Figure 17; Figure 20 is an exploded view of the device of Figure 16; Figure 21 is a view of a distraction device associated with an elbow joint. DESCRIPTION OF ACCOMPLISHMENTS OF THE INVENTION
[061] With reference to the attached drawings, and particularly to Figures 1 to 3, an external orthopedic fixator for elbow joints was identified with reference number 1.
[062] The device, as stated above, can be used for the treatment of trauma as well as joint stiffness in relation to that joint.
[063] The eXterno orthopedic ﬁ xator 1 comprises proximal anchoring devices 2 intended to be integrally associated with the patient's humerus 100 and the distal anchoring device 3 intended to be integrally associated with ulna 101.
[064] The external orthopedic fixator 1 still comprises an articulator 4 that articulates the proximal connector 2 to the distal connector 3 along a geometric axis of articulation x; when attached to the patient, said articulator 4 is arranged in correspondence with the elbow joint 102, theoretically with the geometric axis of articulation x coinciding with the geometric axis of the rotation of said joint.
[065] It should be noted that the external orthopedic fixator 1 according to the preferred embodiment described here is of the monolateral type, that is, the structure of the device, composed of proximal and distal anchoring devices 2, 3 and the articulator 4 that the joins, only develops on one side of the sagittal plane that passes through the elbow joint.
[066] The proximal anchoring device 2 comprises a proximal rod 29 coupled to the articulator 4 at one of its ends and a proximal clamp 20 intended to anchor, by means of proximal end pins 70, the proximal rod 29 to the patient's humerus 100.
[067] The proximal clamp 20, which can be seen in detail in Figures 4 to 6, comprises a first coupling element 21 for locking proximal end pins 50, and a second coupling element 22 for locking proximal stem 29 instead of.
[068] The two coupling elements are connected together by means of a pivot pin 23, with a head 23a associated with the first coupling element 21 and a leg 23b associated with the second coupling element 22.
[069] The first coupling element 21 comprises a first jaw 21a and a second jaw 21b, which are coupled together to define three housings through to house as many proximal endosseous pins as possible 70.
[070] The second jaw 21b serves as a cap and has a pair of holes through which is at least partially threaded, for the passage of closing screws 28. The first jaw 21a comprises a corresponding pair of blind holes that are internally threaded to receive by screwing the ends of the two screws 28.
[071] In particular, the housings through to house the proximal endosseous pins 70 are defined by six non-conductive inserts 21c defined in the body of the two jaws, and particularly arranged in opposite pairs on the flat boundary surfaces 21 d that belong to the first 21a and the second jaw 21b, respectively. The inserts 21c define a concave semi-cylindrical surface, so that the surfaces of the opposite inserts define the three housings through the circular section intended to house the cylindrical leg of the proximal endosseous pins 70. The three housings are aligned, parallel and equidistant.
[072] The first coupling element 21 extends between two parallel planar faces and has an elongated part, through which the housings pass through, and a projecting part 21a intended to house the head 23a of the pivot pin 23.
[073] In particular, the elongated part of the first coupling element 21 is defined concomitantly by the first jaw 21a and the second jaw 21b; the part that protrudes 21 and is defined instead by the first jaw 21a, developing opposite the boundary surface 21 d thereof.
[074] The head 23a of the pivot pin 23 is then housed in a housing of the projecting part 21 and, while the pin itself extends itself away from the boundary surface 21 d. The head 23a has an orifice through perpendicularly to the planar faces of the mandible; through this orifice through a fixing cam 24a inserted in a bushing 24b. Said eccentric 24a has on the two opposite sides accessible from the outside of a respective hollow socket head 18 for receiving a spanner. The simple rotation of the cam 24a promotes traction of the pivot pin 23 towards the first coupling element 21 of the proximal clamp 20.
[075] The second coupling element 22 comprises an upper jaw 22a which a lower jaw 22b [mismatch in original]. The upper and lower jaws define a section C intended to receive the proximal stem 29, however through its center passes the leg 23b of the articulation pin 23, which is then inserted into the holes through the surfaces of the two opposite jaws.
[076] The free end of the leg 23 of the pivot pin 23 is threaded, and a nut 25 is mounted on it, arranged to compress the second coupling element 22 against the first element 21, at the same time fixing the jaws of the second element coupling 22.
[077] An adapter 26 is conveniently interposed between the first coupling element 21 and the second coupling element 22, comprising a convex surface intended to slide on the outer semicylindrical surface of the first coupling element 21 and a desired flat opposite surface to limit against the outer surface of the upper jaw 22a of the second coupling element 22.
[078] A helical compression spring 27 is interposed between the adapter 26 and the upper jaw 22a of the second coupling element 22, surrounding the leg 23b of the pivot pin 23; this spring, combating the fastening action of the nut 25, is housed in opposite impressions on the upper jaw 22a of the second coupling element 22 and on the adapter 26 against which it is limited.
[079] It should be noted that the proximal clamp 20 described above may alternatively have a clearance and lock configuration. In the clearance configuration, there is a play between the coupling elements that make up the clamp so that: the second coupling element 22 is rotatable with respect to the first element 21 around the geometric axis of the leg 23b of the articulation pin 23, that works like a hinge; and the pivot pin 23 is free to rotate with respect to the first coupling element 21 around the geometric axis of the fixing cam 24a, which functions by a hinge between the two elements. Starting from this configuration, first by manually turning the nut 25, the first coupling element 21 and the second coupling element 22 are brought closer against the force of the helical compression spring 27, then by turning the clamping cam 24a an approach additional elements are obtained in which the proximal clamp 20 is placed in the locked configuration. In the locked configuration, the relative orientations between the first coupling element 21, the second coupling element 22 and the hinge pin 23 are blocked, so that the clamp becomes a monolithic assembly.
[080] The distal anchoring device 3 comprises a distal rod 39, 39 ”which is coupled to the articulator 4 and intended to be anchored, via distal endosseous pins 60, to the patient's ulna 101.
[081] It should be noted that the point at which the distal endosseous pins 60 are attached to the ulna 101 is of crucial importance for several reasons.
[082] First, it is necessary that these pins are not inserted in a position that is too distal, as this could interfere with the line of movement of the radio when the patient's pulse rotates.
[083] Second, pin insertion should be easy, so it is preferable to implant in specific locations on the ulna that offer a flat surface for the drill.
[084] Finally, it is best to avoid inserting the pins into the ulna from behind, which could complicate the patient's support of his elbow on a surface.
[085] In order to meet the aforementioned requirements, different alternative embodiments for anchoring distal endosseous pins 60 to distal stem 39, 39 ”, that is, different types of distal anchoring devices 3, are suggested here.
[086] The first two achievements, which are particularly advantageous, as they allow the pins to be arranged independently, provide the use of two distal endosseous pins 60 anchored in the distal stem 39 by means of two independent distal clamps 30, 30 ' each other.
[087] In the first embodiment shown in Figure 7, the distal clamps 30 comprise a first coupling element 31 and a second coupling element 32 adequately connected by means of a fixing screw driven by a handle 33 and a locking cam ( not visible in the figures) integrated in the handle itself.
[088] The first coupling element 31 consists of two rigid parts that can be fixed together by means of the fixing screw; these rigid parts have side jaws that define two C-shaped side housings for receiving the pins. By bringing the two rigid parts closer together by means of the fixing screw, the jaws are secured around the leg of a distal endosseous pin 60 potentially positioned in one of the C-shaped housings.
[089] The second coupling element 32 comprises a main part which laterally defines a housing for housing the distal stem 39; and a secondary part that covers the main part and that locks the rod inside the housing.
[090] The first and second coupling elements 31, 32 are pivotally mounted on the connection screw when the latter is released; when the screw is fixed, the two coupling elements are compressed and held against each other and relatively locked by projections that are respectively present on the two contact surfaces.
[091] It should be noted that, before fixing the screw, the endosseous pins applied to the distal clamps 30 have three degrees of freedom with respect to the distal stem 39: the first as a result of the fact that the clamps are free to slide over along the wear, the second as a result of the relative rotation between the two coupling elements that make up the clamp, the third as a result of the axial sliding of the pin into its housing.
[092] A second way of fixing the distal endosseous pins 60 on the distal stem 39 involves using the distal clamps 30 'in a different way, which can be seen in Figure 11.
[093] The distal clamps according to this embodiment comprise a first coupling element 31 'and a second coupling element 32' connected opportunely by means of a fixing screw 34 '.
[094] The first coupling element 31 'consists of two opposite arms connected together by a flexible bridge, defining laterally a C-shaped housing to tighten a distal endosseous pin 60. Through these arms, the fixing screw 34', one end of which is screwed into the outermost arm of the device. The other arm, instead, is in contact with the second coupling element 32 '.
[095] The second coupling element 32 'comprises a fixed part 32a' that defines a C-shaped side housing for the distal stem 39, and a movable jaw 32b 'hinged at the end of the outermost arm of the C-shaped housing The fixation of the fixing screw 34 'acts on the movable jaw 32b' in order to lock the distal rod 39 in position potentially in the C-shaped housing.
[096] In this case too, the first and second coupling elements 31 ’, 32’ are swiveled with respect to each other on the connecting screw 34 ’when the latter is unscrewed; when the screw is tightened, the two coupling elements are compressed and held against each other and relatively locked by projections arranged respectively on the two contact surfaces.
[097] It should be noted that before tightening the screw, the endosseous pin applied to the distal clamps 30 'has three degrees of freedom with respect to the distal stem 39: the first as a result of the fact that the clamps are free to slide over along the rod, the second as a result of the relative rotation between the two coupling elements that make up the clamp, the third as a result of the axial sliding of the pin into its housing.
[098] As an alternative to the embodiments described above which comprise distal clamps 30, 30 ', it is possible to anchor the distal endosseous pins 60 according to the following embodiments.
[099] In a third embodiment, which can be seen in Figure 8, the distal stem 39 ”has a plurality of planar impressions, with two semi-cylindrical cavities 39a” that open in each one. A blind threaded hole 39b ”is made between the two semi-cylindrical cavities 39a” of each planar impression. Latches 38 ”, which have a flat locking surface intended to limit against the print profile, can be positioned above planar prints. The locking surface comprises two semi-cylindrical cavities that are positioned against the cavities of the impressions that define the housings for the distal endosseous pins 60. The locks 38 ”have a hole into which a fixing screw 37” is inserted, the ends of which engage into the threaded blind hole 39b ”of the print below. By tightening the fixing screw 37 ”, the distal end pins 60 potentially positioned in said housings are then locked.
[0100] A fourth realization is similar to the previous one, however, it does not provide semicylindrical cavities to be performed directly on the distal stem 39 ”.
[0101] In this fourth embodiment, shown in figures 9 and 10, the distal rod comprises 35 ”bases (integral or added) that support an insert 36” made preferably of steel. A lock 38 "is provided above the insert 36", which is held in position by means of a fixing screw 37 "in a similar manner as described in the third previous embodiment. The fixing screw 37 ”also passes through the lock 38” and engages in a blind threaded hole in the base 35 ”. The insert 36 ", which has cylindrical cavities 36a" which are morphologically similar to those of the previous embodiment, is rotatable in relation to the base 35 "around the geometric axis of the fixing screw 37", which functions as a hinge. When the screw is tightened, the relative movement between the 35 ”base and the 36” insert is blocked.
[0102] This fourth embodiment has the advantage of superior flexibility over the previous one, as a result of the additional degree of freedom created by the rotating assembly of the 36 ”inserts.
[0103] The articulator 4, which can be seen in detail in the attached figures 12 to 15, consists of a proximal junction part 4a, intended to fix the proximal stem 29, and a distal junction part 4b, intended to fix the distal stem 39, 39 ”. The two junction parts 4a, 4b are pivotally mounted with respect to each other along the hinge axes x; when the external orthopedic fixator 1 is implanted, the surgeon should ideally allow this geometric axis to coincide with the geometric axis of rotation of the elbow joint 102.
[0104] The proximal junction part 4a comprises a centering window 40 and a proximal connector 41 associated with it integrally.
[0105] The centering window 40 is a cylindrical element that defines, according to the embodiments in which they will now be illustrated, the geometric axis of articulation between the proximal junction parts 4a and distal 4b.
[0106] The centralization window 40 is also intended to facilitate the centralization of the geometric axis of articulation x with the elbow joint 102, which is the most critical part of the intervention of implantation of the external orthopedic fixator 1.
[0107] In order to achieve this objective, the centralization window 40 is made of a radiolucent material and its dimensions allow it to frame the elbow joint 102 during the positioning of the external orthopedic fixator 1.
[0108] The centering window 40 comprises a central tube 40a oriented along the geometric axis of articulation x, to allow the potential insertion of a reference cable.
[0109] In order to facilitate additional centralization, the radiopaque references 40b are arranged on the radiolucent circular surface of the centralization window 40, in particular lines of sight that are orthogonal to the geometric axis of articulation x.
[0110] The centering window 40 has a cylindrical side surface with a shoulder edge 40c at its end; the opposite end instead provides four holes perpendicular to the cylindrical surface for the insertion of the elastic fixing pins 40d.
[0111] The proximal connector 41 comprises a proximal connecting arm 41b, at one end of which two proximal joint rings 41a extend which are essentially the same and parallel, whose function will be illustrated hereinafter. Instead, the opposite end of the proximal connecting arm 41b has an insertion housing 41c for the proximal stem 29, consisting of a hole defined between two fork-like appendages of the proximal connecting arm 41b. The two appendages can be brought closer to each other using a 41 d proximal connection screw. The end of the proximal rod 29, inserted in the insertion housing 41c, is limited against a projection 41 e and is locked in position by fixing the proximal connection screw 41 d.
[0112] The proximal connector 41 shows, in correspondence with the connection of the proximal connection arm 41b with the two proximal articulation rings 41a, a proximal connection hole 41 g whose function will be described hereinafter.
[0113] Two slots are provided integral with the proximal articulation rings 41a instead, which are intended to receive a 41 f articulation locking screw. Fixing the screw will allow the two slots and the proximal articulation rings 41a integral with these to be brought closer.
[0114] The distal junction part 4b comprises a coupling element 42 and a distal connector 43 associated with it.
[0115] The coupling element 42 has a distal hinge ring 42a with an internal diameter and an external diameter equal to those of the proximal hinge rings described above 41a. A protuberance defining a sliding housing 42b for distal connector 43 extends integrally with distal hinge ring 42a, which has a geometric axis that is substantially tangential to distal hinge ring 42a. The sliding housing 42b has two side edges that can be secured by means of a bypass locking screw 42c.
[0116] The coupling element 42 shows, in correspondence with the union of the distal articulation ring 42a with the protuberance defining the sliding housing 42b, a distal connection hole 42g whose function will be described hereinafter.
[0117] The distal connector 43 comprises a sliding arm 43a attached to an L-shaped connection on a distal connecting arm 43b. The two arms form an angle of about 114 °.
[0118] The sliding arm 43a slides in the sliding housing 42b, in which its axial movement is limited by a boundary surface. Through this boundary surface, however, a bypass control screw 43f passes, the head of which emerges from the coupling element 42. The threaded leg of the bypass control screw 43f is instead engaged in a longitudinal hole in the arm sliding 43a, so that the rotation of said screw promotes the translation of the arm along the sliding housing 42b.
[0119] The operation of the offset control screw 43f then determines a translation of the distal anchoring means 3 with respect to the hinge axis x, in particular, along a hinge axis y inclined by a distraction angle α with respect to the longitudinal geometric axis of the distal bone 101. Considering the 114 ° inclination between the two arms of the distal connector, the distraction angle α is approximately equal to 66 °. The distraction control screw 43f then defines the appropriate hinge distraction device 102.
[0120] A mechanical pin is provided to allow the distraction control screw 43f to be locked in position.
[0121] The free end of the distal connecting arm 43b instead has an insertion housing 43c for the distal stem 39, 39 ”, consisting of a hole through defined by the two edges of the distal connecting arm 43b side by side. The two edges can be brought closer to each other by means of a connection screw 43d. The distal stem 39, 39 ”, once inserted in the insertion housing 43c, is locked in position by fixing the distal connection screw 43d.
[0122] The hinge that allows the two junction parts 4a, 4b to be swiveled is defined by the centering window 40 and the three hinge rings 41a, 42a.
[0123] The two proximal pivot rings 41a are integrally mounted with the peripheral cylindrical surface of the centering window 40. The shoulder edge 40c of the centering window 40 is limited against a counterform impression on one of the two rings, while the other ring is fixed by means of four elastic fixing pins 40d at the opposite end of the cylindrical surface.
[0124] The distal articulation ring 42a is inserted between the two proximal articulation rings 41a, slightly rotating around the peripheral cylindrical surface of the centering window 40 and which advantageously has a thickness that is equal to the distance between the interaxial centers of the two proximal joint rings 41a.
[0125] Given this structure, it is possible to rotate the distal junction part 4b with respect to the proximal part 4a by sliding the distal cylindrical ring 42a along the peripheral cylindrical surface of the centering window.
[0126] It should be noted that tightening the articulation locking screw 41 f allows the relative position of the two junction parts 4a, 4b and, consequently, of the anchoring devices 2, 3 associated with them, to be fixed.
[0127] Furthermore, by means of said distraction control screw 43f, it is possible to adjust the distance from the geometric axis of the distal stem 39, 39 ”with respect to the geometric axis of articulation x, thus performing the distraction of the joint. This adjustment can be conveniently locked by tightening said distraction lock screw 42c.
[0128] The articulator 4 described above has several advantages, firstly the fact that it reproduces the movement of the elbow joint 102, thus ensuring sufficient stability to the joint itself and protecting it from overload.
[0129] The articulator 4 also considerably facilitates the delicate operation of the centralization of the orthopedic device, thanks to the radiolucent centralization window 40 with the central tube 40a and radiopaque references 40b.
[0130] Furthermore, as described above, the articulator can perform a joint distraction along the anatomical geometric axis of the humerus access to the joint itself, with an angle of 114 °.
[0131] Thanks to the orientation of the distal connector 43, the orthopedic device is connected to the ulna, and therefore not restricted by the position of the joint at that time. Any possibility of error on the part of the surgeon during implantation is removed.
[0132] Articulator 4 is also ambidextrous, requiring only one person to insert the screws and fix the closing nuts on the desired side.
[0133] Finally, the articulator 4 can be advantageously connected to an auxiliary device 5 which can be seen in Figures 16 to 20.
[0134] The auxiliary device 5 is structured as a cylindrical box-shaped body 50 in which a rotating part of the plate type 51 (called simply as a rotating plate) is engaged in a rotating manner. The box-like body 50 has a perforated eye 50a intended to receive a fixing screw for the articulator 4. Similarly, the swivel plate 51 comprises a protuberance that exceeds and swings over the box-like body 50 below and which supports a fixing pin 52 to attach to the articulator. The screw and fixing pin 52 engage with the connection holes identified above 41 g, 42 g of the articulator 4.
[0135] Within an internal cavity 57 of the box-like body 50 a gear wheel 53 is arranged which is integrally connected to the turntable 51, by means of a drum 54 which passes through a guiding hole on an upper surface of the box-shaped body 50.
[0136] The group consisting of the gear wheel 53, the drum 54, and the rotating plate 51 is then rotatable in relation to the box-shaped body 50. This group can be placed in two alternative positions, which determine the two different operational configurations of the auxiliary device 5. In a first configuration, the rotating plate 51 is limited against the upper surface of the box-shaped body; in a second configuration, this pivot plate 51 is instead raised with respect to that same surface.
[0137] The sprocket 53 integral with the swivel plate 51 is then in two separate auxiliary positions within the internal cavity 57 when the operational configuration of the auxiliary device 5 changes. In the first operational configuration, the periphery of said gearwheel 53 engages with an endless screw 55 which passes through the box-shaped body 50 at the base of the eye 50a. In the second operational configuration, the sprocket 53 is in a plane distant with respect to the plane of the worm 55 and idle with respect to the latter.
[0138] The pressure elements 56 are conveniently arranged inside the box-shaped body 50 and radially compressed against a peripheral groove shared 54a of the two that are present in the drum 54, in order to engage respectively in both the first and the second configuration of the auxiliary device 5.
[0139] An adhesion handle 51a is also properly arranged on the outer surface of the turntable 51, which allows the operating configuration of the auxiliary device 5 to be easily changed. As an alternative to said adhesion loop 51a it is possible to form a peripheral adhesion profile on the rotating plate.
[0140] The two opposite ends of the auger 55 take the form of control heads 55a that emerge from the box-shaped body 50; when manipulating these control heads 55a, it is possible to turn the screw 55. In this way, it is possible, in the first operational configuration of the auxiliary device 5, to simultaneously promote the rotation of the gear wheel 53 and the relative movement of the rotary plate 51 with relative to the box-shaped body 50. If the auxiliary device 5 is attached to the articulator 4 in one of the ways described above, this relative movement results in a relative rotation of the two junction parts 4a, 4b and consequently, a change in the angle between the proximal nail 29 and a distal nail 39, 39 ”
[0141] Then, the worm 55, the sprocket 53 and the drum 54 define a mechanical reduction gear, whose input is represented by the control heads 55a and whose output is represented by the rotating plate 51. Advantageously, the reason for the gear of the mechanical reduction gear is extremely low, so that by acting on the control component defined by the control heads 55a when the auxiliary device 5 is in the first operational configuration, it is possible to perform a micrometric adjustment of the relative orientation of the anchoring devices 2, 3 of the external orthopedic fixator 1.
[0142] A plurality of holes through the stop 51b arranged in the shape of a half moon is present in the box-shaped body 50. By inserting a relevant stop pin 51c, which passes through a slot in the turntable 51, in a of the said orifices, thanks to the presence of relevant limit stops within the box-shaped body 50, it is possible to obtain a limitation of the angular movement allowed for the pivot plate 51 in relation to the box-shaped body 50. This limitation clearly results in a limiting the relative angle of the anchoring device 2, 3 of the external orthopedic fixator 1. Close to the limiting holes 51b, a graduated scale is advantageously included, so that the surgeon can insert the limiting pin 51c into the corresponding limiting hole 51b the desired angle of the joint limitation.
[0143] The limiting holes 51c are grouped in two series corresponding to the arms of the half moon arrangement; by inserting a stop pin 51c into one of the holes in the first series, the angular movement of the auxiliary device is limited on the underside, by inserting a stop pin 51c into one of the holes in the second series, the angle is instead limited on the upper side. Obviously, it is possible to insert a pin in both series to limit the angle on both the top and bottom sides.
[0144] The two enclosures intended to contain a series of stop pins 51c being used, are present in the body of the grip loop 51a.
[0145] The external orthopedic fixator 1, according to the present invention, can be advantageously implanted after having performed a joint distraction through a distraction device 6 which can be seen in Figure 21 and briefly described hereinafter.
[0146] The distraction device 6 comprises a proximal clamp 80 that engages the humerus by means of three endosseous pins 70 and a distal clamp 61 that engages in the ulna by means of two distal screws 60. The endosseous pins can be used, in the subsequent steps of the operation, in order to apply the external orthopedic fixator 1.
[0147] The distal clamp 61 comprises a fixed part 61b and a telescoping movable part 61a which moves relative to the first. The fixed part 61b can be anchored firmly to the patient's ulna 101 by means of two distal screws 60 which are inserted into two holes through the bilobate of the element. Said distal screws 60 are held in position within said holes by means of two locking screws 66.
[0148] The telescopic movement of the moving part 61a can be adjusted by means of a distraction screw 67.
[0149] The two parts of the distal clamp are both convex at their points of reciprocal connection, so that they define a centering window 65 that opens for the elbow joint and how much they are useful in the proper centering of the distraction device 6.
[0150] The proximal clamp 80 is associated, by means of a first ball joint 68, with a first connecting element 63 to which a pair of parallel rods 62 is fixed in an axially adjustable manner. The opposite end of the pair of rods 62 is fixed to a second connecting element 64, which is associated by means of a second ball joint 69 with a movable part 61a of the distal clamp.
[0151] The telescopic movement of the distal clamp 61 allows the desired distraction to be performed in the case of joint stiffness, along a fixed geometric axis that is inclined by an angle α (preferably 70 °) with respect to ulna 101.

权利要求:
Claims (22)
[0001]
1. EXTERNAL ORTHOPEDIC FIXER (1) FOR ELBOW JOINTS, comprising: a proximal anchoring device (2) intended to be integrally associated with a proximal bone (100) of a patient's upper limb; a distal anchoring device (3) intended to be integrally associated with a distal bone (101) of a patient's upper limb; an articulation distraction device arranged to allow the distal anchoring device (3) to be moved with respect to the proximal anchoring device (2), an articulator (4) that articulates the proximal anchoring device (2) with the distal anchorage (3) along a geometric axis of articulation (x), intended to be positioned in correspondence with an elbow joint (102) connecting the proximal (100) and distal (101) bones, in which the articulator (4 ) comprises a radiolucent centering window (40) intended to frame the elbow joint (102) when the external orthopedic fixator (1) is positioned, the geometric axis of articulation (x) passing through the centering window (40), the The articulator (4) further comprises a proximal junction part (4a) which is associated with the proximal anchoring device (2) and a distal junction part (4b) which is associated with the distal anchoring device (3), characterized in that the distal junction part (4b) comprises a coupling element (42) articulated with the proximal junction part (4a) and a distal connector (43) integral with the distal junction part (4b) and movable slidingly with respect to the coupling element (42), the articulation distraction device being arranged to promote the translation of the distal connector (43) with respect to the coupling element (42) of the articulator (4), and in which the distal connector (43) comprises a sliding arm (43a) which is slidably inserted into a sliding housing (42b) of the coupling element (42), the articulation distraction device having the form of a distraction control screw ( 43f), comprising a head that is rotatably associated with the sliding housing (42b) and a leg engaged with the sliding arm (43a).
[0002]
2. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 1, characterized in that the centralization window (40) has radiopaque references (40b) arranged to guide the centralization of the elbow joint (102).
[0003]
EXTERNAL ORTHOPEDIC FIXER (1), according to any one of claims 1 to 2, characterized in that the centralization window (40) comprises a central tube (40a) oriented along the geometric axis of articulation (x), for insertion potential of a reference cable.
[0004]
EXTERNAL ORTHOPEDIC FIXER (1), according to any one of claims 1 to 3, characterized in that the proximal anchoring device (2) comprises at least one proximal rod (29) connected with the articulator (4) and fixed to the bone proximal (100) by means of proximal endosseous pins (70) supported by at least one proximal clamp (20), in which the proximal clamp (20) comprises a first coupling element (21), arranged to lock the proximal endosseous pins ( 70), and a second coupling element (22) arranged to lock the proximal rod (29), the first and second coupling elements (21, 22) being articulated with each other by means of a pivot pin (23) comprising a head (23a) associated with the first coupling element (21) and a leg (23b) associated with the second coupling element (22).
[0005]
5. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 4, characterized in that the head (23a) of the articulation pin (23) has an orifice through which a geometric axis (24a) passes that is transversal to the first coupling element (21), so that the articulation pin (23) is rotatable selectively with respect to the transverse geometric axis (24a).
[0006]
6. EXTERNAL ORTHOPEDIC FIXER (1), according to any one of claims 1 to 5, characterized in that the distal anchoring device (3) comprises at least one distal rod (39, 39 ”) connected to the articulator (4) and fixed to the distal bone (100) using distal endosseous pins (60).
[0007]
EXTERNAL ORTHOPEDIC FIXER (1), according to claim 6, characterized in that the distal endosseous pins (60) are supported by at least one distal clamp (30, 30 ') associated with the distal stem (39).
[0008]
8. EXTERNAL ORTHOPEDIC FIXER (1), according to any one of claims 6 to 7, characterized in that the distal endosseous pins (60) are directly supported by the distal rod (39 ") and held in position by means of locks (38") which can be fixed to the distal stem (39 ”) using fixation devices (37”), the distal stem (39 ”) and the latches (38”) have opposite cavities that come together to define the housings for the distal endosseous pins (60).
[0009]
9. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 1, characterized in that the centering window (40) has a cylindrical geometry and that defines a hinge pin between the proximal junction part (4a) and the distal junction part (4b).
[0010]
EXTERNAL ORTHOPEDIC FIXER (1), according to claim 9, characterized in that one of the proximal (4a) or distal (4b) junction parts comprises at least one swiveling articulating ring rotatable along an external cylindrical periphery of the window centering window (40), the centering window (40) being integral with the other joining part (4a, 4b).
[0011]
11. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 1, characterized in that the articulator (4) comprises joint locking devices (41f) arranged to block the relative rotation between the proximal junction part (4a) and the part of distal junction (4b).
[0012]
12. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 1, characterized by the translation occurring along a geometric axis of distraction (y) that is inclined by an angle of distraction (a) with respect to the longitudinal geometric axis (z ) of the distal bone (101), the distraction angle (a) being between 60 ° and 75 °.
[0013]
13. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 1, characterized in that the distal connector (43) comprises a distal connecting arm (43b) intended for longitudinally receiving a distal rod (39, 39 ”) from the distal anchoring device (3), the implied angle between the sliding arm (43a) and the distal connecting arm (43b) being between 105 ° and 120 °.
[0014]
14. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 1, characterized by further comprising the distraction locking device (42c) arranged to block the relative translation between the distal anchoring device (3) and the proximal anchoring device (4).
[0015]
15. EXTERNAL ORTHOPEDIC FIXER (1), according to any one of claims 1 to 14, characterized in that it also comprises an auxiliary device (5) that can be coupled with the articulator (4) and that allows the relative rotation between the parts of proximal (4a) and distal (4b) junctions to be adjusted micrometrically, in which the auxiliary device (5) comprises a box-shaped body (50), a rotating part (51) that is rotatably associated with the box-shaped body (50), and the fixing device (50a, 52) intended for fixing the box-shaped body (50) and the swiveling part (51) on the proximal junction part (4a) and the distal junction part (4b) respectively or vice versa; the box-shaped body (50) comprising a mechanical reduction gear (53, 54, 55) intended to transmit a rotational movement from a control component (55a) to the rotating part (51), the reduction gear mechanical (53, 54, 55) arranged inside the box-shaped body (50).
[0016]
16. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 15, characterized in that the mechanical reduction gear (53, 54, 55) comprises a gear wheel (53) and an endless screw (55).
[0017]
17. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 16, characterized in that the auxiliary device can be configured according to two alternative configurations, a first configuration in which the rotating part (51) is coupled to the control component (55a) by means of the mechanical reduction gear (53, 54, 55) and a second configuration in which the rotating part (51) is idle with respect to the control component (55a).
[0018]
18. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 17, characterized in that a drum (54) makes the rotating part (51) integral with the gear wheel (53), the group formed by the rotating part (51), the drum (54) and sprocket (53) being axially translatable between a position corresponding to the first configuration of the auxiliary device (5) in which the sprocket (53) engages the worm (55), and a position corresponding to the second auxiliary device configuration (5) in which the sprocket (53) does not engage the endless screw (55).
[0019]
19. EXTERNAL ORTHOPEDIC FIXER (1), according to any one of claims 15 to 18, characterized in that the auxiliary device (5) additionally comprises the devices (51b, 51c) to selectively limit the angular excursion allowed between the box-shaped body (50) and the rotating part (51), are arranged to define both a lower and an upper limit of the angular excursion.
[0020]
20. EXTERNAL ORTHOPEDIC FIXER (1), according to claim 19, characterized by the devices (51b, 51c) to selectively limit the angular excursion allowed between the box-shaped body (50) and the rotating part (51), comprise a plurality of restraining holes (51b) shown on the swiveling part (51) and intended to house the restraint pins (51c) which interact with boundary stops of the box-shaped body (50).
[0021]
21. KIT, comprising an external orthopedic fixator (1) according to any one of claims 1 to 20, characterized in that at least one distraction device (6) comprises a distal clamp (61) equipped with a fixed part (61b) which may be associated with the patient's distal bone (101) at the elbow joint (102) and a movable part (61a) which may be associated with the proximal anchoring device, the movable part (61a) being telescopically translatable with respect to the part fixed (61b).
[0022]
22. KIT according to claim 21, characterized in that the distal clamp (61) of the distraction device (6) is shaped in such a way that it creates a centering window (65) intended to frame the elbow joint (102) when if the distraction device (6) is positioned, the centering window (65) of the distraction device (6) is made by opposed hollows of the fixed part (61b) and the movable part (61a) of the distal clamp (61).

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同族专利:

公开号 | 公开日

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CN103370020B|2016-03-02|

JP6103773B2|2017-03-29|

AU2011358378B2|2015-04-09|

CA2823606A1|2012-08-16|

DK2672908T3|2015-02-09|

AR085159A1|2013-09-11|

MX2013008960A|2013-11-04|

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CA2823606C|2018-10-16|

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法律状态:
2018-12-26| B06F| Objections, documents and/or translations needed after an examination request according art. 34 industrial property law|

2019-08-27| B06U| Preliminary requirement: requests with searches performed by other patent offices: suspension of the patent application procedure|

2020-05-19| B09A| Decision: intention to grant|

2020-06-09| B09W| Decision of grant: rectification|Free format text: RETIFICACAO DA PUBLICACAO DE DEFERIMENTO POR TER SIDO EFETUADA COM INCORRECAO. TAL PUBLICACAO NAO IMPLICA NA ALTERACAO DA DATA DO DEFERIMENTO E NOS PRAZOS DECORRENTES DA MESMA. |

2020-11-17| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 09/09/2011, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

申请号 | 申请日 | 专利标题

US201161442018P| true| 2011-02-11|2011-02-11|

US61/442,018|2011-02-11|

PCT/EP2011/004551|WO2012107061A1|2011-02-11|2011-09-09|External orthopaedic fixator for the elbow joint|

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