DE202005009080U1 - Tendon implant tensile test unit has spring loaded slide moved by screw and hand crank in body with attachment holes - Google Patents

Abstract

A tendon implant (10) tensile test unit has implant attachment holes (26, 28) in a body (18) and slide (30) moved against internal (40) spring (32) force by a screw (36) and hand crank (34).

Description

The The present invention relates to a tensile testing device for tendon implants, especially for Implants for the replacement of the anterior cruciate ligament.

at partial or complete Rupture of the cruciate ligament becomes common an autologous or allogenic patellar bone patellar tendon-tibial bone block composite as cruciate ligament replacement in the knee joint implanted of bone material in association with ligament or tendon structures human or of animal origin. Before the implantation of such Tendon implant requires its quality and in particular its Check tensile strength.

One Another purpose of Zugprüfvorrichtung is the elimination of collagen tendon implants after processing and sterilization occurring shrinkage of the collagen fibers. By holding the rehydrated tendon implant under load with e.g. 75 N for the duration of a few minutes restores the original state. To carry out this bias before implantation is the device accordingly executed. This can be an extension the tendon is avoided after implantation.

It The object of the present invention is a tensile tester for tendon implants too create, which is simple and reliable, reproducible review of the Tensile strength allowed.

The solution This object is achieved by the features of claim 1 and in particular in that a base frame is provided with a carriage, the movable against the force of a spring on the base frame is. Further, on the base frame and on the carriage respectively a receptacle for attachment of the tendon implant provided.

With the device according to the invention can Tendon implants are easily checked for tensile strength, by placing the tendon implant at each of its two ends into one the recordings is used. By moving the carriage against the force of the spring is exerted on the tendon implant a tensile force by the travel of the carriage is measurable and adjustable. To Achieve the desired Traction, the slide can be moved back and the tendon implant can be removed from the device.

advantageous embodiments The invention are in the description, the drawings and the dependent claims described.

To a first advantageous embodiment can be a manual actuator, in particular a hand crank, be provided, with which the carriage is movable against the force of the spring. With such a hand-operated element can be repeated in a particularly simple manner and reproducible the desired tensile forces on the implant, which, for example, when actuated by hydraulic or pneumatic actuators are not always the case is.

A very precise Setting the desired Traction can be achieved by the carriage by means of a threaded spindle against the force of the spring is movable.

To a further advantageous embodiment is based the spring on the one hand on the carriage and on the other hand on a sliders provided on the carriage. This way you can the stroke of the slidable on the carriage against the force of the spring Sliding element as display for the applied tensile force can be used. When the sliding element when moving the carriage against the force of the spring a position has reached, which corresponds to a predetermined maximum tensile force, This can be done, for example, by means of a marker or the like be recognized, so that the carriage moves back to its original position can be.

Especially It is advantageous if the carriage has a cavity, in which the spring and / or the sliding element is / are arranged. In this way, a compact arrangement is achieved, at the same time Spring and sliding element are housed protected in the cavity. If in this case, the cavity has a passage opening for the sliding element, can the passage of the sliding member through the passage opening as Display for it be used when a predetermined tensile force is reached.

To A further advantageous embodiment is a damping element provided, against which the carriage on the base frame movable is. With such a damping element is the pulling device and in particular the carriage from damage protected, if at an implant during the tensile test a tendon tear occurs.

It is particularly advantageous if the receptacles for the tendon implant are U-shaped, since in this case the tendon implant inserted only between the legs of the U-shaped receptacles who has to, in addition, a fixation of the implant ends can be done in the recordings. For this purpose, according to a further advantageous embodiment in each case a coaxial hole pair may be provided, through which a pin can be inserted therethrough after insertion of the implant, which fixes the implant ends. Such a pin can be inserted either through a hole at the implant end. Alternatively, it is possible to use the pin as a stop for the implant end.

Especially for tendon implants with cuboid bone blocks can each recording according to a further advantageous embodiment a Pair of coplanar slotted holes which are arranged substantially vertically and preferably across from the vertical slightly with its bottom toward each other recording are inclined. In this embodiment, metal pins serve through the long holes be plugged as a clamp attachment for the implant end.

In order to during a tendon tear during the load time the fingers of the operator are not squeezed or can be clamped, can according to another embodiment invention of the rear end portion of the carriage from one to Surround the protective frame attached to the base frame. Especially It is advantageous if this protective cover is a viewing window has, in order to allow a view of the passage opening, there in this case, the escape of the sliding member through the passage opening of Outside can be observed.

following The present invention is purely exemplary by way of an advantageous embodiment and with reference to the accompanying drawings.

The Figure shows a longitudinal section partially sectioned side view of a tensile testing device for tendon implants.

The figure shows a tensile testing device for a tendon implant 10 holding a patellar bone block 12 and a tibial bone block 14 that is through a tendon 16 connected to each other.

The Zugprüfvorrichtung has a base frame 18 formed as a bent to a DIN rail stainless steel part and with a base plate 20 is screwed. The underside of the base plate 20 is fully bonded with an approximately 4 mm thick silicone rubber to prevent slippage of the device during the tensile test.

At the left in the figure, the end of the base frame 18 is a receptionist 24 on the base frame 18 welded, on the top of a recording 26 for one end of the tendon implant 10 is welded. A second shot 28 that have the same structure as the first shot 26 own is on a sled 30 screwed on the base frame 18 against the force of a spring 32 can be moved from the initial position shown in the figure in the arrow direction. The sled 30 is designed as a square tube made of stainless steel. For a guided tour of the sled 30 on the base frame 18 are on the base frame 18 not shown longitudinal slots provided in which also slide guide elements not shown, which are bolted to the underside of the carriage. In this way, a linear guide of the carriage is ensured along the base frame.

For a movement of the sled 30 against the force of the spring 32 is a winch 34 provided with a threaded spindle 36 rotatably connected. The left end of the threaded spindle in the figure 36 is in a sliding element 38 screwed into a cavity 40 of the sled 30 taken and slidable in the cavity. At the right end of the carriage in the figure 30 is a stop 42 with a passage opening 44 provided with the sled 30 is screwed. Here, the spring is supported 32 at its left end in the figure on the slider 38 and at its right end to the stop 42 from. By pressing the hand crank 34 becomes the threaded spindle 36 set in rotation, whereupon the sliding element 38 in the direction of the arrow against the force of the spring 32 moved to the right. This will be on the slide 30 a force applied to the tendon implant 12 that in the two shots 26 and 28 is fixed, tense.

As the figure shows, the slider has 38 at its right end in the figure, an extension 46 which is chamfered at its front end. The outer diameter of the extension 46 is chosen so that the extension 46 through the passage opening 44 of the stop 42 can pass through. Here is the force of the spring 32 chosen so that the desired tensile force (for example, 150 N) is reached exactly when the chamfer of the extension 46 through the passage opening 44 has passed through.

The figure also shows that the threaded spindle 36 at its in the figure right end in one with a sliding bushing 48 provided bearing element 50 is stored, with the base frame 18 is welded. Between the right in the figure end of the carriage 30 and the bearing element 50 is on the threaded spindle 36 a damping ring 52 , For example, made of rubber, put on, which prevents that in a Sehnenabriss the slide 30 due to the bias of the spring hard against the bearing element 50 strikes. Further, in the figure, a protective cover 54 to recognize that designed as a DIN rail bent stainless steel part and with the base frame 18 is screwed. The protective cover 54 covers the area in which the right in the figure, the end of the carriage in the direction of the bearing element 50 emotional. In this way, an operator is prevented from pinching between the rear end of the carriage and the bearing element when a tendon tear occurs. Further, at the top of the protective cover 54 a viewing opening 56 provided in the form of a slot through which can be observed when the chamfered end of the extension 46 through the passage opening 44 of the stop 42 passes.

Each of the two shots 26 and 28 is designed as a U-shaped stainless steel part, the bone blocks 12 and 14 from the top between the legs of each recording can be inserted. As the figure shows, the two shots point 26 and 28 a plurality of longitudinally spaced apart coaxial bore pairs 60 on, through which a metal pin for fixing the bone blocks 12 and 14 can be plugged. In particular, in the case of cylindrical bone blocks, such a metal pin can be inserted through the two holes of the coaxial bore pair and through a provided in the bone block transverse bore. In the case of an implant with essentially cuboid bone blocks 12 and 14 As shown in the figure, the metal pins can be made by coplanar slots 62 be plugged, each in the two thighs each recording 26 and 28 are provided. As the figure shows, the slots are 62 arranged substantially vertically and slightly inclined relative to the vertical, that the lower ends of the elongated holes are offset relative to the upper ends in the direction of the respective opposite receptacle to the front. In this way, a metal pin inserted through the elongated holes becomes 64 against the bone blocks 12 and 14 clamped when the sled 30 is moved in the direction of the arrow.

To perform a tensile test, the implant 10 as shown in the figure with its two blocks of bone 12 and 14 between the legs of each recording 26 and 28 inserted and the metal pins 64 are inserted through the slots as shown. Subsequently, by turning the handwheel 34 the sled 30 to be moved in the direction of the arrow, passing through the spring 32 on the sled 30 applied force increases and thereby the implant is subjected to train. At the same time, the sliding element moves 38 within the carriage also in the direction of the arrow until the chamfer of the extension 46 through the passage opening 44 of the stop 42 exit. When the operator does this through the viewing port 46 has been seen, the tensile test is completed because the pre-set tensile force has been reached. Subsequently, the handwheel can be rotated in the opposite direction, so that the carriage 30 moved back against the direction of the arrow, whereupon the implant from the recordings 26 and 28 can be removed.

It should be noted that all housing components and product-contacting surfaces of the tensile tester according to the invention are made of stainless steel. The sliding element 38 is made to achieve low friction losses of brass and / or sintered bronze. The entire device is also autoclavable.

10

tendon implant

12 14

bone blocks

16

tendon

18

body

20

baseplate

22

silicone rubber

24

up cup

26 28

admission

30

carriage

32

feather

34

handwheel

36

screw

38

Slide

40

cavity

42

attack

44

Through opening

46

extension

48

bush

50

bearing element

52

damping element

54

protective cover

56

view port

60

drilling

62

slots

64

metal pins

Claims (12)

Tensile testing device for tendon implants ( 10 ), comprising: a base frame ( 18 ), and a sledge ( 30 ), which is against the force of a spring ( 32 ) on the base frame ( 18 ) is movable, wherein on the base frame ( 18 ) and on the carriage ( 30 ) one recording each ( 26 . 28 ) for attaching a tendon implant ( 10 ) is provided. Tensile testing device according to claim 1, characterized in that a hand-operated element, in particular a hand crank ( 34 ), with which the carriage ( 30 ) against the force of the spring ( 32 ) is movable. Tensile testing device according to claim 1 or 2, characterized in that the carriage ( 30 ) by means of a threaded spindle ( 36 ) against the power of Feather ( 32 ) is movable. Tensile testing device according to at least one of the preceding claims, characterized in that the spring ( 32 ) on the sledge ( 30 ) is arranged. Tensile testing device according to at least one of the preceding claims, characterized in that the spring ( 32 ) on the one hand on the carriage ( 30 ) and on the other hand on a slide provided on the slide ( 38 ) is supported. Tensile testing device according to at least one of the preceding claims, characterized in that the carriage ( 30 ) a cavity ( 40 ), in which the spring ( 32 ) and / or a sliding element ( 38 ) is arranged. Tensile testing device according to claim 6, characterized in that the cavity ( 40 ) a passage opening ( 44 ) for the sliding element ( 38 ) having. Tensile testing device according to at least one of the preceding claims, characterized in that a damping element ( 52 ) is provided against which the carriage ( 30 ) on the base frame ( 18 ) is movable. Tensile testing device according to at least one of the preceding claims, characterized in that the recordings ( 26 . 28 ) Are U-shaped. Tensile testing device according to at least one of the preceding claims, characterized in that the recordings ( 26 . 28 ) at least one coaxial bore pair ( 60 ) exhibit. Tensile testing device according to at least one of the preceding claims, characterized in that the recordings ( 26 . 28 ) at least one pair of coplanar slots ( 62 ), which are arranged substantially vertically and are preferably slightly inclined relative to the vertical. Tensile testing device according to at least one of the preceding claims, characterized in that an end region of the carriage ( 30 ) from one to the base frame ( 18 ) attached protective cover ( 54 ), in particular a viewing aperture ( 56 ) having.