RU2500360C2 - Surgical apparatus for application of staples with reusable components - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, and can be used for application of surgical staples into tissues and contains reusable components. Apparatus for staple application has additional unit for pushing out staples and case with distal end, proximal end and longitudinal axis between them. Proximal end has a handle. Distal end has holder for cartridge with staples and rest plate located in opposite side. Executive unit includes, at least, one longitudinally moving element for successive supply of staples in direction of rest plate. Components of apparatus case can be dismounted, processed and reassembled for application during other operative interventions.

EFFECT: executive module can be easily removed and replaced inside apparatus case.

6 cl, 29 dwg

Description

FIELD OF THE INVENTION

The invention relates to surgical instruments for stitching tissues, and more particularly to a surgical apparatus for applying brackets, which can be disassembled, and its parts are subjected to processing and sterilization for reuse in subsequent surgical interventions, which contains a removable trigger module and which can be reused complete with several cartridges during one surgical intervention.

BACKGROUND OF THE INVENTION

Prior to the introduction of surgical brace instruments, the process of tissue stitching in patients took surgeons a lot of time. This operation was the longest stage of any surgical intervention. The use of surgical devices for applying brackets significantly reduced the time spent on tissue stitching. Such surgical bracing devices are described in the following US patents, incorporated herein by reference: No. 4633861 issued by Chow et al .; No. 4,633,874 to Chow et al .; No. 5129570 issued by Schulze et al.

One of the difficulties in using surgical apparatus for braces is the need to ensure their sterility during surgery. The apparatus for reusable brackets, as a rule, is a rather complicated instrument, the sterilization of which is difficult after use. Thus, repeatedly expressed wishes for the creation of surgical devices for imposing brackets for single use. Since during surgery a need may arise for more than one surgical apparatus for applying brackets, for reasons of economy, devices for applying brackets with rechargeable cartridges have been developed. The design of such rechargeable cartridges provides for the presence of surgical braces and a mechanism that pushes them out of the cartridge. Typically, the actuator also has a cutting tool. Thus, each time the cartridge is reloaded, the actuator and knife are replaced. As a rule, during one surgical intervention, several cartridges are used for a patient, as a result of which a series of replacements of knives and an actuator is necessary for the same patient. Since the knife usually does not have time to wear out during the use of one cartridge, the knife and actuator can be reused when working with other cartridges when operating one patient. Reuse of the actuator in the same patient does not require additional sterilization and will reduce the costs associated with surgical intervention. Also, wishes were expressed for the development of an apparatus for applying brackets, parts of which can be reused, that is, an apparatus for applying brackets, consisting of parts that can be used both once and repeatedly. Reuse of parts of the apparatus for applying brackets reduces the cost of surgical intervention, as well as reduce the consumption of surgical materials.

Thus, in order to reduce the cost of surgical interventions, there is a need to develop a collapsible surgical apparatus for applying brackets, parts of which can be processed for further use. In particular, there is a need for a surgical apparatus for applying brackets, which allows you to reuse the actuator and cutting mechanisms in combination with the ability to use multiple cartridges during surgery on the same patient, in order to reduce the cost of suture materials used in such an apparatus for overlay brackets. There is also a need for a surgical apparatus for applying brackets that can be easily disassembled and assembled for processing and reuse of its parts. In addition, there is a need for an apparatus for applying brackets containing parts suitable for reusable use, which includes a disposable actuator that allows for quick replacement in the intervals between surgical interventions for more complex cutting and stapling components. In addition, there is a need for an apparatus for applying brackets containing parts suitable for reusable use, in which such parts have a simple integral design that facilitates their efficient processing in between operations. In the framework of the present invention, there is provided an apparatus for applying brackets with parts suitable for reusable use that meets these requirements.

SUMMARY OF THE INVENTION

In accordance with the provisions of the present invention, an apparatus for applying brackets with parts suitable for reusable use, designed to install surgical braces in tissues. The apparatus for applying brackets is a body having a distal end, a proximal end and a longitudinal axis located along the body. At the proximal end is the handle of the apparatus for applying brackets, and at the distal end is a cartridge with brackets and an opposing thrust plate. The apparatus for applying brackets also has a trigger module designed to set brackets. The launch module consists of at least one longitudinally directed element designed for sequential supply of brackets in the direction of the thrust plate. The launcher module can easily be disconnected from the body of the apparatus for imposing brackets and replaced by another.

In another embodiment, within the framework of the present invention, there is provided a bracketing apparatus with reusable components having an upper jaw with a lever at the proximal end and a stop at the distal end. The lower jaw having a proximal gutter-shaped frame and a distal cartridge gutter is aligned with the upper jaw. The trigger module, including at least one longitudinally moving element for successively pushing the brackets in the direction of the thrust plate, can be easily detached from the lower jaw and replaced with another. A cartridge containing a plurality of surgical braces is freely positioned inside the groove for the cartridge of the bracemaker. The mechanism connecting the upper and lower jaws together is located in an intermediate position along the longitudinal axis of the apparatus for applying brackets. The mechanism can move relative to the upper and lower jaws, fixing the apparatus for imposing brackets in various positions. Various fixed positions of the apparatus for applying brackets also include a position for attaching and detaching the mechanism from the jaws, as well as a closed fixed position in which the mechanism is connected to the jaws.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 is an isometric view of a model of a surgical apparatus for applying brackets in a closed, fixed position.

In FIG. 2 shows a front view of the apparatus for applying brackets in the initial open position.

In FIG. 3 is an isometric view of an apparatus for applying brackets in the initial open position.

In FIG. 4 is an isometric view of a bottom view of a reusable upper lip of the apparatus for applying brackets.

In FIG. 5 is an isometric view of a top view of the upper lip of the apparatus for applying brackets.

In FIG. 6 is an isometric view of a lower reusable sponge apparatus for applying brackets, including a cartridge groove with brackets.

In FIG. 7 is an isometric view of a disposable cartridge for brackets.

In FIG. 8 is an isometric view of a bottom view of a disposable cartridge of a bracketing apparatus.

In FIG. 9 is an isometric view of a reusable locking mechanism.

In FIG. 10 is a front view of a reusable locking mechanism.

In FIG. 11 is a detailed isometric view of the distal end of the locking mechanism.

In FIG. 12 is a fragment of a front view of the apparatus for applying brackets, showing the locking mechanism in a ready-to-assemble form.

In FIG. 13 is a fragment of a front view of the apparatus for applying brackets, showing the locking mechanism in a partially assembled position.

In FIG. 14 is a fragment of a front view of the apparatus for applying brackets, showing the locking mechanism in a rotated and partially closed fixed position.

In FIG. 15 is a fragment of a front view of the apparatus for applying brackets, showing the relative position of the locking mechanism and the upper jaw in the position preceding the closed fixed position.

In FIG. 16 is a fragment of a front view of the apparatus for applying brackets, showing the relative position of the locking mechanism and the upper jaw in its original open position during use.

In FIG. 17 is an isometric view of a disposable launcher.

In FIG. 18 is another perspective view of a disposable launch module, front view, in the direction from the proximal to the distal end.

In FIG. 19 is an isometric view of a tray of a launch module.

In FIG. 20 is a detailed isometric view of the proximal end of the launch module.

In FIG. 21 is a top view of a launch module.

In FIG. 22 is an isometric view of the trigger handle.

In FIG. 23 is an isometric view of a guide block.

In FIG. 24 is an isometric view of an actuator.

In FIG. 25 is an isometric view of a knife support bar.

In FIG. 26 is an approximate isometric view of the distal end of the launch module, showing a safety nozzle.

In FIG. 27 is a front view of a launch module.

In FIG. 28 is a cross-sectional view of the proximal end of the launch module, showing the relative position of the launch handle and the lock spring in the rearmost position.

In FIG. 29 is a sectional view of the proximal end of the launch module, showing the position of the trigger handle extended forward in the process of ejecting the bracket.

DETAILED DESCRIPTION OF THE INVENTION

We now turn to the accompanying drawings, in which similar elements have similar numeric designations. In FIG. 1-3, a first example of a surgical apparatus for applying brackets 20, developed in accordance with the present invention, is schematically depicted. The body of the apparatus for applying brackets 20 includes an upper jaw 22, a lower jaw 24 and a locking mechanism 30. The connecting mechanism 30 can rotate relative to the upper and lower jaws 22, 24, as shown in FIG. 2-3. The connecting mechanism 30 can be rotated, taking a series of positions in order to fix the apparatus for applying brackets in a closed fixed position or in various types of initial open positions, allowing you to change the position of the fabric inside the apparatus for applying brackets, to replace the cartridge or disassemble the apparatus for applying brackets. Upon completion of the surgery, the locking mechanism 30 can be rotated to the full opening position, allowing disassembly of the apparatus for applying brackets 20 to prepare it for re-sterilization and reuse of parts.

As shown in FIG. 4 and 5, the upper jaw 22 is made in the form of an integral structure with a groove and opposite side walls 32a, 32b, interconnected by means of the upper wall 36. On the outer surface of the upper wall 36 is given a corresponding shape that facilitates comfortable grip by hand, and includes the upper the protrusion of the handle 40, facilitating the retention and operation of the surgeon with the apparatus for applying brackets. The distal end of the upper jaw 22 has a pair of inwardly directed flanges 42, forming a thrust plate 44 of the apparatus for applying brackets. The sides 42 are separated by a central longitudinal slot 46, which is located along the thrust plate 44. The inner surface of each of the sides 42 has two longitudinal rows of evenly distributed pockets 50, designed to form brackets. Pockets 50 are necessary to give the B-shape to the U-shaped brackets at the time of their pushing in the direction of the sides of the thrust plate when triggered. The abutment plate 44 has a tapered tip at the distal end, facilitating insertion of the brace apparatus into the hollow organs of the patient. A pair of fabric stoppers 52 are located on opposite sides of the stop plate 44 near the proximal end of the forming brackets of the pockets 50. The fabric stoppers 52 are located laterally in the same direction as the proximal end of the forming bracket of the pockets 50, which prevents the tissue from getting outside the stop plate 44 of the apparatus for applying brackets. Blocking tissue at the proximal end of the abutment plate 44 prevents pinching or cutting of unstitched tissue sections.

The cylindrical pins 54 extend from opposite sides of the upper jaw 22 beyond the fabric stoppers 52. The pins 54 enter the vertical slots located on the lower jaw 24 and are used to connect the upper and lower jaws. The upper jaw 22 also has a pair of curved grooves 60 located near the proximal end of the side walls of the groove 32a, 32b. The grooves 60 interact with the protrusions 62 on the lower jaw 24, as shown in FIG. 2, providing quick alignment of the jaws during operation of the apparatus for applying brackets. The upper jaw 22 should preferably be made from a single piece of biocompatible metal, for example, stainless steel. The use of a single piece of material for the manufacture of the upper jaw 22 increases the structural integrity of the apparatus for applying brackets. Alternatively, the upper jaw 22 may consist of two or three parts that are joined together during the manufacturing process using known joining methods, for example, by welding.

As shown in FIG. 6, the lower lip 24 is made of a single piece of material in the form of an elongated U-shaped frame having a pair of side walls 64a and 64b connected by a lower wall 66. At the distal end of the lower lip 24, the side walls 64a and 64b are reduced and form a groove for cartridge 70, designed to accommodate a disposable cartridge in the apparatus for applying brackets. The grooves 72 are located on the side walls 64a and 64b near the distal end of the groove for the cartridge 70. The grooves 72 interact with the side protrusions on the cartridge, which is necessary to hold the cartridge inside the groove. Slots for vertical alignment 56 are located proximally from the groove for the cartridge 70 at the upper edge of the side walls 64a and 64b. As mentioned earlier, the pins 54 on the upper jaw 22 interact with the slots for alignment 56 to achieve mutual alignment and connection of the clamps of the apparatus for applying brackets. The distance between the side walls 32a and 32b of the upper lip is slightly larger than the distance between the side walls 64a and 64b of the lower lip, which allows the upper lip to be placed on top of the lower when the pins 54 are inserted into the alignment slots 56 and the protrusions 62 into the grooves 60. Cutouts 74 located on the outer surface of the side walls 64a and 64b distal to the alignment slots 56. The cutouts 74 facilitate the attachment of the actuator to the lower jaw 24, as described in detail below.

A gap 76 is formed in the lower wall 66 in the middle of the lower jaw 24. The side walls 64a and 64b are extended downward on opposite sides of the lumen 76 to form distal protrusions 80. The side walls 64a and 64b directed along the distal edge protrusions 80 form a rectangular a cutout 82 having a rounded end 88. The diameter of the rounded end 88 is slightly greater than the width of the slot 82. Proposed to the positioning device 80 on the outer surfaces of the side walls 64a and 64b the locking element. As shown in FIG. 6, such a device may include several locking protrusions 84 or other irregularities deposited on the surface of the side walls 64a and 64b by machine. Despite the fact that in FIG. 6 shows only the device located on the front side of the lower jaw 24, it must be understood that the back side of the lower jaw has a similar profile, so the locking element 30 can be fixed in several positions using both sides of the lower jaw, as described below. A retaining element 86 is located at the proximal end of the lower lip 24 at the junction of the side walls 64a and 64b and the lower wall 66. The retaining element 86 may include sections of the interiorly extending side walls 64a and 64b that assist in locking the actuator module during assembly of the overlay apparatus brackets 20.

In FIG. 7 and 8 show an example of a removable cartridge 90 used in a brace apparatus 20 designed in accordance with the provisions of the present invention. The cartridge 90 is adapted to accommodate surgical brackets grouped in at least two longitudinal rows placed next to each other. The cartridge 90 has a housing that has opposing side walls 92a, 92b, and also has a configuration that allows it to slide along the groove of the lower jaw 70. The cartridge 90 is longitudinally divided by a central longitudinal slot 94, which is located from the proximal end of the cartridge to the distal end. The holes 96 in the cartridge case are distributed along the longitudinal slot 94. In the shown embodiment, the holes for the brackets are made in the form of two adjacent alternating rows in which each pair of rows is placed on the sides opposite from the central longitudinal slot 94. The holes for the brackets in the adjacent rows are interspersed, which provides more efficient stitching of fabrics during operation of the apparatus for applying brackets. As shown in FIG. 8, the cartridge 90 has a pair of longitudinal slots 100 located on opposite sides of the central longitudinal slot 94, between alternating rows of holes 96. Each of the longitudinal slots 100 is located in the direction from the proximal end of the cartridge 90 to the distal end. Bracket guides (not shown) are inserted into the bracket holes 96 to eject the brackets charged into the cartridge 90. Each bracket guide is designed to eject two brackets located in adjacent rows of the cartridge 90. Thus, the first set guides for brackets is designed to push brackets out of alternating rows located on one side of the central longitudinal slot 94, and a second set of guides for brackets is designed to push brackets a pair of adjacent rows located on the other side of central longitudinal slot.

At the distal end of the cartridge 90 there is a conical tip facilitating the insertion of the lower jaw 24 of the apparatus for applying brackets into the hollow tubular organs of the patient. A pair of protruding outward portions 102 is located proximal to the conical tip in the cartridge 90. A pair of spaced parallel flanges 104 extends in the rear direction from the opposite sides of the cartridge 90. The legs 110 are a continuation of the flanges 104 extending downward at the proximal end of the cartridge of the bracketing apparatus. Each of the legs 110 has a rounded groove 112 located on its outer side down. When the cartridge 90 is inserted into the lower jaw 24, the protruding parts 102 freely enter the grooves 72 of the side walls of the lower jaw, and the legs 110 pass through the slots 76 in the lower wall of the lower jaw 66 of the apparatus for applying brackets. The grooves of the legs 112 interact with the pins on the locking mechanism 30, as described below, to hold the cartridge in the groove of the lower jaw 70. A pair of flaps 114 is located upward and outward relative to the side walls 92a and 92b at the proximal end of the cartridge 90. The flaps 114 serve to capture the apparatus for applying brackets by hand, facilitating manual installation of the cartridge 90 and its removal from the lower jaw 24. Using the shutters 114, the cartridge 90 can be removed from the lumen 76 and grooves 72 and removed from the lower jaw 24 of the apparatus for applying brackets after use. In addition, the flaps 114 interact with the side walls of the lower jaw 64a and 64b at the proximal end of the groove for the cartridge 70, as shown in FIG. 3, for fixing the cartridge on the lower jaw 24. A short extended portion 116 is located behind the cartridge 90, between the rear protruding legs 110. The central slot for the knife 94 is longitudinally passing through the extended portion 116, and can be provided on opposite sides with inwardly inclined guides surfaces at the proximal end of the slot. The locking pin 106 is connected at one end to the expanded portion 116 and can rotate around the connection point. Initially, when the cartridge 90 is installed in the apparatus for applying brackets 20, the locking pin 106 is located across the Central slot for the knife 94.

As mentioned above, the apparatus for applying brackets 20 has a locking mechanism 30, designed to connect the upper and lower jaws in the middle part of the length of the apparatus for applying brackets. Preferably, the jaws 22 and 24 are connected at a point adjacent to the proximal end of the thrust plate 44 and the cartridge 90 of the apparatus for applying brackets. In the preferred embodiment depicted in FIG. 9, the locking mechanism 30 is an integral structure. The gutter-shaped frame has opposing side walls 124a and 124b connected by an upper wall 130. The connecting mechanism 30 also includes a locking pin 122 for articulating the mechanism with the lower jaw 24. It is preferred that the locking mechanism consist of a single piece of stainless steel or other biocompatible metal. The distance between the opposite side walls 124a and 124b of the locking mechanism exceeds the distance between the side walls 64a and 64b of the lower lip 24 of the bracketing apparatus. The side walls 124a and 124b have outwardly extending protrusions 132 designed to grip and rotate the handle of the locking mechanism 120 to switch positions of the apparatus. The outer surface of the handle of the locking mechanism 120 has an expanded portion 134. When connected to the lower lip 24, the extended portion 134 is attached to the upper lip 40 to form a handle allowing the surgeon to manipulate the brace apparatus.

Each of the side walls 124a and 124b of the locking mechanism 30 includes a distally elongated C-shaped hook 140 having a forward-facing notch 142 for engaging with the pin of the upper jaw 54. As shown in FIG. 9 and 10, the hooks 140 have an inner surface 144 that is directed backward from the tip of the hook to the slot 142. When the locking mechanism 30 is moved to the closed fixed position, the slots 142 interact with the pins of the upper jaw 54, which ensures that the locking mechanism is held in the closed fixed position . Below the slots 142, each of the hooks 140 is located distally downward beyond the upper wall 130. The bolt pin 122 is located between the lower bent ends of the hooks 140, as shown in FIG. 11, transverse to the end of the locking mechanism 30. The closure pin 122 is cylindrical in shape with flat surfaces 152 adjacent to each other. The diameter of the bolt pin 122 is larger than the diameter of the narrow hole of the slot of the lower jaw 82. The bolt element 30 is freely connected to the lower jaw 24 by the pin 122 inserted into the slot of the lower jaw 82. The bolt pin 122 is inserted into the slot 82 by orienting the locking mechanism 30 so that the flat ends 152 become parallel to the straight sides of the slot. In this position, the bolt pin 122 can be inserted into the slot 82 even though the diameter of the pin exceeds the width of the slot. When aligning the flat ends 152 with respect to the linear sides of the slot 82, the locking pin 122 is inserted into the slot, as shown in FIG. 12 until the pin is positioned at the rounded end of the slot 88, as shown in FIG. 13.

The apparatus for applying brackets 20 also has other means of retaining the locking mechanism when changing its positions. As shown in FIG. 9 and 10, other means include a spring lever 150 located from the upper edge of each of the side walls of the arms of the locking mechanism 124a and 124b. The spring lever 150 bends upward in the distal direction, repeating the upper profile of the hook 140, and has a bulb-shaped end. With the locking pin 122 mounted in the slot 82 and distally deflected by the locking mechanism 30, as shown in FIG. 13, the apparatus for applying brackets 20 is in its original open position. In order to close the apparatus for applying brackets 20, the latching locking mechanism 30 rotates in the direction of the proximal end of the apparatus for applying brackets to bring the shutter element to the position closest to the body of the lower jaw 24. When the flat end 152 deviates from the alignment line with the sides of the slot 82, the gap the width between the pin 122 and the slot 82 prevents the pin from slipping out of the slot 88. Thus, the pin 122 is fixed in the slot 88 by attaching the latching locking mechanism 30 to the lower jaw 24.

When the latching locking mechanism 30 is rotated, the hooks 140 are positioned along the sides of the lower jaw 24. When the hooks 140 are moved along the side walls of the lower jaw 64a and 64b, the ends of the spring arms 150 come in contact with the locking tabs 84 on the side walls. To advance the spring arms 150 between the locking protrusions, an additional force is applied to the latching locking mechanism, which causes the spring arms to bend in the direction of the hooks 140 so that the ends of the spring arms can advance past the protrusions. When the spring arms 150 are located between the locking tabs 84, as shown in FIG. 14, the latching locking mechanism 30 is in a partially closed fixed position. In a partially closed fixed position, the mechanism 30 is attached to the lower jaw 24, and the alignment slots 56 are located at a distance from the ends of the hooks 140. The pins of the upper jaw 54 can be freely inserted or removed from the slots 56 of the lower jaw, allowing the upper or lower to be connected or disconnected, respectively. jaws of the apparatus for imposing brackets.

If the bolt pin 122 continues to rotate in the slot 88, bringing the latching locking mechanism 30 closer to the lower jaw 24, the inner surfaces of the hooks 144 rotate, blocking the clearance of the alignment slots 56, blocking the slots and pins of the upper jaw 54 inside the slots. The spring arms 150 also move along the locking protrusions 84 in contact with the concave outer edge of the upper protrusion. In such a pre-closed position shown in FIG. 15, the locking mechanism 30 and the upper and lower jaws 22 and 24 are connected, forming the body of the apparatus for applying brackets 20, while the pins of the upper jaw 54 can slide inside the slots 56, between the bottom of the slot and the inclined surface 144, allowing the jaws to move relative to each other. The snap-on locking mechanism 30 supports the jaws in a loosely closed position, providing mutual movement of the cartridge and the thrust plate. The relative displacements of the distal ends of the jaws 22 and 24 make it possible to adjust the apparatus when gripping the fabric without the need to disconnect the jaws from each other.

When the latching locking mechanism 30 is in the closed operating position (shown in FIG. 1), the mechanism wraps around the lower lip 24, with the pins 54 on the upper lip 22 located in the slots 142. The spring arms 150 extend distally along the sides of the lower lip 24, bypassing the locking tabs 84. In this position, the upper and lower jaws are closed, squeezing the fabric with the surfaces of the thrust plate and cartridge, and the apparatus for applying brackets is ready to stitch and cut the fabric. In a closed fixed position between the thrust plate and the surface of the cartridge, a minimum distance is maintained, which is achieved by the presence of a pin 160. To adjust the position of the fabric between the surfaces of the thrust plate and the cartridge, the locking mechanism 30 can be returned to the previously closed position, as shown in FIG. 16, in order to remove the pins 54 from the slots of the hook 142. When the shutter member 30 is rotated in the opposite direction, the spring arms 150 again come into contact with the locking tubercles 84 to hold the coupling mechanism in place. Returning to the position immediately preceding the closed fixed position of the bracketing apparatus weakens the connection of the hooks 140 and the pins 52, which allows the pins to slide inside the slots 56 without having to disconnect the jaws from each other.

To disassemble the apparatus for applying brackets 20, the connecting mechanism 30 is rotated in the direction opposite to the lower jaw 24, and the pins of the upper jaw 54 are removed from the slots of the hooks 142. The connecting mechanism 30 can be turned in the direction opposite to the upper and lower jaws 22 and 24 by pulling the ends the jaws of the locking mechanism 162. Since the force of the locking mechanism 120 continues to act against its rotation, the spring arms 150 pass through the locking protrusions 84, allowing the hooks 140 to deviate forward, moving between the side walls of the lower jaws 64a and 64b. The connecting mechanism 30 rotates in the direction of the cartridge 90 until the locking mechanism 30 is in the initial open position shown in FIG. 13. When the locking mechanism 30 is brought into open position, the flat ends 152 of the bolt pin 122 are again parallel to the straight edges of the slot 82, allowing the bolt to be removed through the slot 82 and disconnect the connecting mechanism from the lower lip 24. When the connecting mechanism 30 is disconnected, the bracketing apparatus 20 can be disassembled into three integral components: the upper jaw 22, the lower jaw 24 and the connecting mechanism 30. The integral design of these reusable components (with gutters) both It ensures, for easy handling and thorough sterilization of these components in the intervals between use.

Turning now to FIG. 17 and 18, depicting an actuator module 170 for stitching and cutting tissue sandwiched between the upper and lower jaws 22 and 24. The actuator module 170 includes a U-shaped elongated tray 172 that provides support for components of the actuator module. The pallet of the module 172 has a pair of side walls 174 connected by a lower wall 176 (Fig. 19). The distance between the walls 174 of the module pallet is less than the distance between the side walls 64a and 64b of the lower jaw of the apparatus, which allows the module pallet to enter and be fixed in the proximal groove of the lower jaw 24. As shown in FIG. 19 and 20, the proximal end of the pallet of the module 170 includes one or more locking protrusions 178 located on the outer surface of the side walls 174. When the actuating module 170 is distal in the groove of the lower jaw, the locking protrusions 178 interact with the holding elements 86 on the inner surface of the groove lower jaw 24. The interaction of the locking protrusions 178 with the holding elements 86 allows you to grab and hold the actuator module inside the lower jaw 24.

As shown in FIG. 21, several moving actuators are located inside the pallet of the launch module 172, which is designed to perform longitudinal movements inside the pallet with respect to the upper and lower jaws 22 and 24. The actuators include a pusher block 180 located inside the pallet of the module 172 and providing reciprocating movements along the pallet. The pusher block 180 is attached to the handle of the actuator 182 using a side flange 184. If the actuator module 170 is installed inside the lower jaw 24, as shown in FIG. 3, the flange 184 extends through an elongated guide groove 186 formed in the side wall 64 of the lower lip of the apparatus for applying brackets. The flange 184 allows you to place the handle of the actuator 182 on the outside of the jaws 22 and 24, making it easier for the surgeon to access it. In FIG. 3 shows that the handle 182 passes through a guide groove along the side wall 186 of the lower lip 64b. The guide groove may also be located on the opposite side wall of the lower jaw 64a, in which case the handle of the actuator 182 protrudes from the opposite side of the brace 20. When the surgeon moves the handle 182 on the outer surfaces of the jaws 22 and 24, the flange 184 passes through the guide groove 186 .

Turning to FIG. 21. The Executive module 170 also contains a pair of pushers 190 located along the length parallel to each other. The proximal ends of the pushers 190 are fixed in the lateral slots of the pusher 192 (as shown in Fig. 22), which allows them to move in the longitudinal direction together with the pusher block 180 inside the pallet of the module 172. The pushers 190 are located at a distance from the pusher block 180 and come into contact during movement into longitudinal grooves 194 located in the guide block 200, as shown in FIG. 23. As shown in FIG. 18, the guide block 200 is fixed to the distal end of the pallet of the module 172. The upper edges of the side walls of the pallet of the module 174 are bent inward. They hang over the lateral edges of the guide block 200, which holds the guide block inside the module tray. In addition, the hinges 202 extending from the guide block 200 on the sides through the holes 204 on the side walls of the module 174, secure the guide block in the pallet. The distal end of the guide block 200 is located outside the pallet of the module 172, between the rear flanges 104 of the cartridge 90 of the apparatus for applying brackets. The lateral slots 194 of the guide block 200 align the pushers 190 with the longitudinal slots 100 of the guides for the brackets of the cartridge bracket apparatus 90. The distal ends of the pushers 190 are in front of the guide grooves 194 and have a pointed beveled end 206, as shown in FIG. 24 forming an inclined surface for gripping the guides for the brackets inside the cartridge 90 during the movement of the pushers through the cartridge in the distal direction. The longitudinal movements of the ends of the pushers 206 drive the guides for the brackets and therefore cause the brackets to be ejected from the cartridge.

Turning to FIG. 23. The guide unit 200 includes a central section 210 extending through a hole 76 downward in the lower wall of the lower lip 66. The central section 210 includes a straight slit 212 inclined from the distal end and having a rounded end 218. When the bracketing apparatus 20 is assembled, the slot of the guide block 212 is aligned in length with a slot 82 in the side walls 64a and 64b of the lower lip of the apparatus for applying brackets, which allows the locking pin 122 to interact with both the lower lip 24 and the guide block 200, if the locking mechanism 30 anovlen the apparatus for stapling. When the gate pin 122 is inserted into the slot 82 and the end of the slot 88, the pin also passes through the slot of the guide block 212 and is placed in the slot of the rounded end 218, fixing the actuator module 170 and the lower lip 24 with each other.

As shown in FIG. 18 and 21, the actuator module 170 also includes a knife support plate 214 located between the pushers 190. The knife support plate 214 and the pushers 190 should preferably be made of sheet metal. The proximal end of the knife support plate 214 is fixed inside the central slot 216 of the pusher unit 180 (FIG. 22) to attach the knife support plate to the pusher unit in order to enable the actuator 182 to be moved by the handle. At the distal end of the pusher unit 180, the knife support plate 214 enters the central slot 220 of the guide block 200 (as shown in FIG. 23) to align the knife support bar with the longitudinal central slot of the cartridge 94. As shown in FIG. 25, the inclined blade of the knife 222 having a tapered cutting edge is located at the front end of the knife support plate 214. The beveled cutting edge of the knife blade 222 is oriented at an angle to the jaws 22 and 24 and inserted into the central longitudinal slot 220 of the guide block 200. At the proximal end of the blade knife 222 the support plate of the knife 214 has a cutout for fixing it on the cartridge 228, as well as a section of the fuse 224, which is part of a protective locking mechanism, as described below. The proximal end of the knife support plate 214 has a step section shown at number 226. A step section of the knife 226 is formed by cutting a portion of the knife support plate 214 at the proximal end to form protruding points 230 and 232 of the support plate.

As shown in FIG. 26 and 27, the safety nozzle 234 covers the distal end of the guide block 200. The central section 236 of the nozzle 234 surrounds the blade of the knife 222 and the tapered ends 206 of the pushers 190. The inwardly directed edge 240 is located along the lower edge of the nozzle. During assembly, to fix the distal end of the actuator module inside the trough of the lower jaw, it is necessary to press on the safety nozzle 234. When pressing on the safety nozzle 234, the edge 240 enters the recesses 74 on the outer surface of the lower jaw 24.

The leaf spring 250 shown in FIG. 19 is a part of the bottom wall of the pallet of module 176 and is located below the guide block 200. The spring 250 is part of a safety mechanism that prevents the staples from being ejected from the used cartridge, which is achieved by raising the fuse of the knife support bar 224 against the guide block 200. The second spring 252 is part of the bottom wall of the pallet module 176 and is located near the proximal end of the pallet. The second spring 252 is a locking spring that interacts with a cutout on the actuator block 180 and prevents the handle of the actuator module 182 from moving during transportation, as well as enabling the ear and tactile detection of the moment when the trigger handle returns to the most proximal position inside the pan after the bracket is pushed out. In FIG. 28 and 29 illustrate in more detail the operation of the locking spring 252. In FIG. 28, a spring 252 is shown in cooperation with a cutout 254 on the actuator 180 to prevent unwanted movement of the actuator in the distal direction. In FIG. 29 shows a locking spring 252 that emerges from the cutout 254 after applying a directed force to the handle of the actuating unit 182. The pushers 190 and the support plate of the knife 214 advance distally after applying the force to the starting handle 182 sufficient to overcome the resistance of the spring 252 exerted on the cutout 254. After disconnecting the spring 252 from the cutout 254, the actuating unit 180 can move in the distal direction along the pallet 172, first pushing the pushers 190, and then the support plate of the knife 214 from the guide block and 200 to the cartridge 90.

In the initial actuation position shown in FIG. 28, the downward-facing edge of the actuating unit 180 comes into contact with the support bar of the knife 214 at the proximal end point 232 of the stepped cutout 226. The trigger handle 182 is pulled to the extreme position of the guide groove 186, thereby placing the pushers 190 and the knife blade 222 in the slots 194 and 220 in the guide block 200. At the moment of applying distally directed force to the handle of the trigger 182, the spring 252 is disconnected from the notch 254, allowing the trigger block 180 to move along the pallet of the module 172. When moving ADDITIONAL block 180, it moves the pushers 190 in the distal direction, causing the wedge pushrods ends enter into the longitudinal slot 100 for guiding cartridge brackets. During the initial movements of the actuator block 180, the distal edge of the block advances through the stepped cutout of the support plate of the knife 226, as shown in FIG. 29, and there is no direct contact with the backing plate itself. Thus, the support bar of the knife 214 remains stationary during the initial distal advancement of the pushers 190 and block 180.

After the actuating unit 180 has passed the stepped cutout of the knife support plate 226, the distal edge of the unit comes into contact with the distal end point 230 of the knife support plate 214. Such contact between the actuator unit 180 and the knife support plate 214 causes the knife support plate to move with the actuator unit and pushers 190 as the handle 182 advances. As the knife support plate 214 moves, the blade of the knife 222 is guided along the central slot 220 and the rear expanded portion of the cartridge 116 to the central longitudinal slot 94 of the cartridge 90 and central longitudinal slot 46 of the swashplate 44. As we move knife blade 222 through the enlarged portion 116 of the cartridge deflects the blade locking pin 106, clearing the way for moving the knife support rail. The blade of the knife 222 and the ends of the pushers 206 simultaneously move through the cartridge of the apparatus for applying brackets 90, pushing the brackets out of the holes 96 and cutting the fabric. The blade of the knife 222 advances into the cartridge 90, located somewhat behind the pushers 190, and the brackets penetrate into the fabric sandwiched between the thrust plate and the cartridge before the blade of the knife comes closer and cuts the fabric between the rows of brackets.

After using the handle 182, the knife and pushers have been advanced to the stop (or to the desired position), the actuating unit 180 is retracted in the pallet of the module 172 to its original position by moving the actuator handle back in the proximal direction through the guide groove of the lower jaw 186. Initially, while the actuator unit 180 and the pushers 190 are pulled in the proximal direction, the support bar of the knife 214, due to the presence of a stepped cutout 226 of the support bar, remains stationary in the distal position. As soon as the distal edge of the actuator block comes into contact with the proximal end point 232 of the stepped notch, the support bar of the knife 214 begins to return in the proximal position along with the actuator and pushers. As the backward movement of the support plate of the knife 214 in the guide block 200, it rises up using a leaf spring 250, coming into contact with the guide block until the fuse 224 captures the Central support 256 (Fig. 23) of the guide block. As soon as the fuse 224 captures the central support of the guide block 256, the support bar of the knife 214 can no longer move relative to the actuator unit 180. In a preferred embodiment, the support bar of the knife 214 grips the fuse 224 when the actuator unit 180 and the pushers 190 reach the extreme proximal position.

After the handle of the actuator 182 is fully returned to its original position, as shown in FIG. 28, the locking mechanism 30 rotates relative to the jaws 22 and 24, disengaging them as described above. After releasing the handles, the cartridge 90 can be removed and a new one inserted. The used cartridge is removed by pulling the wings of the cartridge 114 and removing the legs of the cartridge 110 from the lumen of the lower jaw 76. When removing the proximal end of the cartridge from the lumen of the lower jaw 76, the cutouts of the legs of the cartridge 112 (Fig. 7) come out of contact with the shutter pin 122. After removing the proximal the end of the cartridge 90, you can remove its distal end from the groove for the cartridge 70 and discard the cartridge.

The new cartridge 90 can be loaded into the lower jaw 24 by pushing the distal end of the cartridge with protrusions in the distal direction of the groove of the lower jaw 70, as well as by pushing the lower legs 110 through the lumen of the lower jaw 76 and pressing on the wings 114. The legs of the cartridge 110 are pushed through the lumen of the lower jaws 76 until the cutouts of the legs 112 snap into place, engaging with the bolt pin 122. When pressing on the proximal end of the cartridge 90, the locking pin 106 on the cartridge presses on the support plate of the knife 214 in the area of the locking the cutters 228, counteracting the force of the leaf spring 250. The force exerted on the blocking pin 106 pushes the cutout of the support plate of the knife 224 downward, disrupting its adhesion to the central support of the guide block 256. When pressed against the support plate of the knife 214, it again aligns with the central slot of the guide block 220, which allows the support bar to move in the distal direction through the slot and into the new cartridge. Thus, in the process of reloading a new cartridge, the safety mechanism returns to its original position. After loading a new cartridge, the bracketing apparatus can be reassembled, with the upper jaw 22 being placed above the lower jaw 24, and the pins of the upper jaw 54 are returned to the alignment slots 56. The locking hooks 140 are pulled back over the slots 56 until the pins 54 will enter the slots 142. When the pins 54 are locked in the slots of the hooks 142 and the locking mechanism 30 is turned to a position near the lower lip 24, the bracketing apparatus is in the closed fixed position and is ready to push the brackets out of the new card idzha.

The upper and lower jaws and the reusable locking mechanism described above are supplied in non-sterile packaging. Before assembling the brackets 20, these components must be cleaned with enzymatic cleaners with a neutral pH and then steam sterilized in an autoclave. Such processing should also be carried out before each subsequent use of the apparatus for imposing brackets. The Executive module 170, due to the presence of a large number of moving parts, is intended for single use in one patient in order to prevent a complex cleaning procedure of the module. The actuator module is supplied in sterile packaging that must be opened under sterile conditions. Cartridge 90 also comes in sterile packaging that must be opened under sterile conditions.

To assemble the apparatus for applying brackets 20, the actuator module 170 is removed from the package and its proximal end is first inserted into the proximal groove of the lower jaw 24. The actuator module 170 is fixed by the interaction of the proximal locking protrusions 178 with the holding elements 86 of the lower jaw. Then, the distal end of the actuator module is rotated downward and enters the frame of the lower jaw 24 having the shape of a trough. As soon as the actuator module 170 is in the trough of the lower jaw, the safety nozzle 234 forces its edges 240 into the slot 74 on the side walls of the lower jaw 64a and 64b. Pressure on the safety nozzle 234 pushes the center section of the guide block 212 through the gap 76 of the lower lip, aligning the slot of the guide block 212 with the slot of the lower lip 82 and blocking the actuator module inside the lower lip 24. When the actuator module 170 is inserted into the lower lip 24, the locking mechanism 30 attaches to lower jaw due to the insertion of the locking pin 122 into the slots 82 and 212, as described above. The connecting mechanism 30 rotates relative to the lower lip 24 to a partially closed fixed position, as shown in FIG. 14. In this position, the locking mechanism 30 is attached to the lower jaw 24, but the upper jaw 22 is separate from the bottom. The safety nozzle 234 is removed from the actuator module 170 by movement in the distal direction shown by the arrow on the nozzle, as shown in the figures.

Then, a new cartridge 90 is inserted into the cartridge groove of the lower jaw 70 according to the instructions described above. After the cartridge is inserted, the upper jaw 22 is placed on top of the lower jaw 24, while the pins 54 are inserted into the alignment slots 56. The connecting mechanism 30 rotates relative to the upper and lower jaws 22 and 24, bringing the apparatus for applying brackets in a pre-closed position (as shown in Fig. 15), in which the inner surface of the hooks 144 overlaps the lumen of the alignment slots 56, blocking the pins 54 inside the slots. The fabric that needs to be cut off is placed between the thrust plate 44 and the cartridge 90 and is aligned to the desired position. Tissue stoppers 52 prevent excessively deep tissue from entering the mechanism of the bracketing apparatus. After properly adjusting the position of the fabric, the brackets are closed to prepare them for pushing out the brackets. The device is moved to the closed fixed position by turning the locking mechanism 30 and bringing it into contact with the lower jaw 24 to place the hooks 140 over the gaps of the slots 56, and also lock the pins 54 in the slots of the hooks 142. In this position, the fabric is clamped inside the device. If further adjustment of the position of the tissue is necessary, the bracketing apparatus can be returned to the pre-closed position, as shown in FIG. 16, in which the distal ends of the upper and lower jaws can move slightly relative to each other, which is usually sufficient to reposition the tissue. After the fabric is properly fixed between the lips of the apparatus for applying brackets, and the locking mechanism 30 is rotated to the operating closed position, the apparatus for applying brackets can be activated by pressing the handle of the actuator 182 and leading it forward along the guide groove 186 to the end. As the handle advances, the clamped fabric is stitched with staples and cut off. After the handle of the actuator 182 stops, reaching the extreme distal position, it is necessary to take it back, in the proximal direction, along the guide groove 186. At the proximal end of the path of movement of the handle, the interaction of the lock spring 252 with the cutout 254 on the actuator allows tactile and auditory determine the moment when the handle returns, signaling that the actuating components have left the cartridge 90 back to the pallet of the module 172.

In the case where additional stitching and cutting of the fabric is required to complete the procedure, the locking mechanism 30 is rotated back to a partially closed fixed position so that the upper jaw 22 can be removed. In this case, the used cartridge is removed and replaced with a new one. After installing a new cartridge, the locking mechanism 30 can be rotated back, and it is also necessary to go through a previously closed and closed fixed state in order to be able to place, clamp and staple the fabric again using a new cartridge. After the desired tissue section is cut off, the locking mechanism 30 is removed by turning it to its original open position (shown in Fig. 13) and removing the bolt pin 122 from the slots 82 and 212. Then, the actuator module 170 and the cartridge 90 can be removed from the lower jaw 24 and deleted. The remaining components (upper sponge, lower sponge and locking mechanism) can be individually cleaned and sterilized in preparation for reuse.

In accordance with the provisions of the present invention, the Executive module 170 is a separate component from the cartridge 90, which allows the replacement of used cartridges during surgery on one patient without replacing the Executive module. Accordingly, the actuator module can be used in one patient multiple times with several single-use cartridges. Using an integral module tray 172 as a structure supporting the components of the actuator module allows quick installation and disconnection of the actuator module from the groove of the lower jaw. The reusable bracketing machine components have a simple, one-piece construction that makes them easy to reuse and reuse. The collapsible design of the locking mechanism facilitates the assembly and disassembly of the reusable parts of the apparatus for applying brackets. In addition, after the apparatus for applying brackets has been assembled, the locking and holding functions of the locking mechanism and the lower jaw prevent the possibility of inadvertently disassembling the apparatus for applying brackets during surgery.

The following description of a preferred embodiment of the present invention is provided for illustrative and descriptive purposes. It is not intended to be exhaustive or to limit the invention to the specific forms set forth. In light of the foregoing, many obvious changes or modifications to the present invention are possible. This embodiment has been selected and described in order to best illustrate the principles of the present invention and its possible practical application, so as to enable a person skilled in the art to use the invention in the best possible way in various variants and various modifications that suit the particular required circumstances of its use . The scope of the present invention is defined by the following claims.

Claims (6)

1. A surgical apparatus for applying brackets, designed to install surgical braces in tissue, including:
but. a housing with a distal end, a proximal end and a longitudinal axis located along the length between them, with a handle at the proximal end and a lower lip located at the distal end containing a cartridge groove with brackets and the opposite upper lip containing a thrust plate, the upper lip contains biocompatible material; and
b. an actuator module for mounting brackets, wherein said actuator module comprises at least one longitudinally moving element for sequentially supplying brackets in the direction of the thrust plate; moreover, the specified Executive module can be easily disconnected from the body of the device and replaced by another;
wherein said housing comprises a locking mechanism for connecting said upper and lower jaws together in an intermediate position along the longitudinal axis of said apparatus,
moreover, the specified locking mechanism can move relative to the aforementioned upper and lower jaws and bring the device into various fixed positions, including the state of the assembly in which the specified locking mechanism can be attached to and disconnected from these jaws, as well as a closed fixed position in which the locking the mechanism is attached to the jaws;
moreover, the specified locking mechanism further comprises a bolt pin, while the specified bolt pin can be inserted and removed from the slot on the housing of the specified apparatus for attaching and disconnecting the locking mechanism with the apparatus for applying brackets. 2. The surgical apparatus for applying brackets according to claim 1, further comprising a cartridge containing a plurality of surgical braces, wherein said cartridge is located in the groove for the cartridge with brackets. 3. The surgical apparatus for applying brackets according to claim 2, in which the body of the specified apparatus contains the upper and lower jaws, each of which is made as a single component, the specified upper lip has a pair of fixed pins, and the lower lip contains a pair of leveling slots, into which the indicated pins of the upper jaw are inserted to align the jaws. 4. The surgical apparatus for applying brackets according to claim 1, in which the specified apparatus for applying brackets additionally has means of retention on the body of the apparatus for holding the specified locking mechanism in these various fixed positions relative to the specified upper and lower jaws. 5. The surgical apparatus for applying brackets according to claim 1, in which the locking mechanism is made in the form of a single component, and in which the upper jaw, lower jaw and locking mechanism can be detached from the specified device and individually subjected to individual processing for reuse during operations on different patients. 6. The surgical apparatus for applying brackets according to claim 4, in which the said holding means are designed to hold the specified locking mechanism in a previously closed fixed position, which prevents the release of these pins of the upper jaw from the specified slots of the lower jaw, but in which the specified cartridge with brackets can move relative to the specified thrust plate.

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