CN108403160B - Surgical instrument with hollow trigger - Google Patents

Abstract

The invention discloses a surgical instrument with a hollow trigger, which comprises a distal working head, a proximal handle and an extension rod part extending between the distal working head and the proximal handle; the handle comprises a front handle, a rear handle and a handle rotating shaft connected with the front handle and the rear handle, and the front handle and the rear handle can rotate relative to the handle rotating shaft; the handle further comprises a lock mechanism; the lock mechanism comprises a cantilever connected with the rear handle into a whole, and the lock mechanism also comprises a trigger; the trigger is arranged in the front handle, part of the trigger is exposed out of the front handle, and the trigger comprises a trigger rotating shaft and a blind cavity structure with one side open; after the rear handle is folded towards the front handle, the cantilever can penetrate through the through hole of the front handle and enter the blind cavity structure; the trigger is rotatable about the trigger axis of rotation, and the blind cavity structure is shaped and dimensioned to: the trigger does not interfere with the cantilever arm when rotated, while the cantilever distal end of the cantilever arm is not exposed outside of the front handle and trigger.

Description

Surgical instrument with hollow trigger

Technical Field

The invention relates to a minimally invasive surgical instrument, in particular to a surgical instrument with a hollow trigger.

Background

Surgical instruments have been used for hundreds of years, and surgical instruments have been developed for hundreds of years by using different surgical instruments to perform tissue grasping, shearing, separation, coagulation, suture closure, and the like. Laparoscopic surgery has been developed clinically for over 30 years and is rapidly advancing. In brief, laparoscopic surgery, i.e., a surgeon uses an elongated laparoscopic hand-held instrument to access the patient's body via a natural orifice or a constructed puncture passageway to complete tissue grasping, shearing, separation, coagulation, suture closure, etc.

Laparoscopic surgery has the major advantage over traditional open-shell surgery in that it is less traumatic to the patient, can alleviate pain and speed recovery. The current endoscopic surgery generally comprises operations such as cholecyst surgery, laparoscopic inguinal hernia repair surgery, laparoscopic gastric fundus folding surgery, laparoscopic splenectomy surgery, laparoscopic appendectomy surgery and the like, the overall operation difficulty of the endoscopic surgery is high, the time required for the endoscopic surgery is long, and the operation time of a surgeon is 1-3 hours in continuous operation. Because of the limitation of the operation space, the operator often needs to operate the instrument in a difficult posture for a long time, and the operator is easy to fatigue, even induce arthritis, scapulohumeral periarthritis and other risks. The laparoscopic hand-held instrument should conform to ergonomic principles, support multiple grasping procedures, reduce extreme operating gestures and relieve fatigue.

When the same instrument is operated, the surgical instruments are held by different surgeons, or the same surgeon is in different operations, or the surgeon has different methods in a specific operation process in the same operation. Studies have shown that finger grip (or precision grip) as shown in fig. 2 and palm grip (or force grip) as shown in fig. 3 are the two most commonly used techniques in endoscopic surgery.

In the existing endoscopic hand-held instrument, such as endoscopic scissors, endoscopic separating forceps, endoscopic grasping forceps and the like, as shown in fig. 1, a scissor-type handle is generally adopted, so that various holding methods can be supported. In order to continuously clamp an organ or tissue, a corresponding locking mechanism is added to the existing surgical hand-held instrument adopting a scissor-type handle, for example, a locking device with a belt-like switching function and a surgical instrument are disclosed in China patent No. CN2014108503121, however, the existing patent realizes the clamping and unlocking use of the tissue or the organ, but the following problems are mainly to be solved due to individual differences of operators and complexity of surgical environments:

On the one hand, the hand sizes of different surgeons are different, the surgical handedness of different surgeons is also different, the existing surgical instruments can generally meet the requirement that the fingers of most surgeons can normally operate during operation, but how to make the fingers of the surgeons operate comfortably is rarely considered, not to mention the requirement of few surgeons with special requirements, such as: the left-handed surgeon performs matching of the finger action areas according to different force habits of the surgeon's fingers;

on the other hand, in the continuous operation process, the surgeon can conveniently switch between different modes by using the same hand, such as the switching between a finger holding mode and a palm holding mode, or the switching between different modes under different modes, so that the surgeon can conveniently use the optimal hand-held posture to perform various accurate operations, and the fatigue of long-time operation is reduced;

further, how to require a rapid switching operation between a continuous clamping and unclamping operation for a tissue or organ and a rapid pulling and peeling operation without participation of a locking mechanism, and the like.

The prior art mainly adopts surgical instruments with different functions to be combined for use by adding a surgical channel, or adopts modes of multi-person assistance and the like: for example, a hand-held instrument with a locking mechanism is adopted in one operation channel, and a common hand-held instrument is adopted in the other operation channel; or the surgical instruments with different functions are switched into and out of the abdomen in the same surgical channel. Even so, the realization requirements of surgeons can be met only partially, but the pain of the patient is increased, and the operation time and various operation risks caused by the pain are increased.

Disclosure of Invention

Accordingly, in one aspect of the present invention, a surgical instrument including a hollow trigger is provided comprising a distal working head, a proximal handle and an extension bar extending therebetween; the handle comprises a front handle, a rear handle and a handle rotating shaft connected with the front handle and the rear handle, and the front handle and the rear handle can rotate relative to the handle rotating shaft; the working head part comprises a pair of clamp heads and a driving mechanism connected with the clamp heads; the lengthening bar part comprises a rotating wheel, an outer bar part and an inner pull rod, wherein the outer bar part and the rotating wheel are fixed together and are arranged in a front handle, one end of the inner pull rod is connected with the driving mechanism, the other end of the inner pull rod is connected with a rear handle, and the handle further comprises a lock mechanism; the lock mechanism comprises a cantilever connected with the rear handle into a whole, and the lock mechanism also comprises a trigger; the trigger is arranged in the front handle, part of the trigger is exposed out of the front handle, and the trigger comprises a trigger rotating shaft and a blind cavity structure with one side open; after the rear handle is folded towards the front handle, the cantilever can penetrate through the through hole of the front handle and enter the blind cavity structure; the trigger is rotatable about the trigger axis of rotation, and the blind cavity structure is shaped and dimensioned to: the trigger does not interfere with the cantilever arm when rotated, while the cantilever distal end of the cantilever arm is not exposed outside of the front handle and trigger.

An alternative solution is provided, wherein the lock mechanism further comprises a locking tab, a button and an elastic element; the lock mechanism includes an active mode and an inactive mode; the locking plate comprises a locking hole matched with the appearance and the size of the cantilever, and the cantilever penetrates through the locking hole; the trigger also includes a first cam surface, a second cam surface and a finger catch, the button interacting with the first cam surface to drive the trigger to rotate about a trigger axis of rotation to effect switching of the lock mechanism between the active mode and the inactive mode.

An alternative technical solution, wherein when the lock mechanism is in an active mode, the elastic element drives the locking plate to be tightly matched with the toothless cantilever, so that the rear handle is allowed to be folded towards the front handle and the rear handle is limited to be opened away from the front handle, namely, the locking function is achieved; the second cam surface can be selectively contacted with the locking plate, external force is applied to drive the finger button to enable the trigger to rotate around the trigger rotating shaft, the second cam surface drives the locking plate to move and enable the locking plate to be in clearance fit with the toothless cantilever, and the rear handle is allowed to be opened away from the front handle, namely the unlocking function.

An alternative technical solution, wherein the button comprises a first button and a second button, and the first button and the second button are respectively arranged on two side surfaces of the front handle; the front handle comprises an elongated chute penetrating through two side surfaces of the front handle, and the first button and the second button can slide in the elongated chute; wherein the direction of the long and narrow chute is basically parallel to the extension bar part.

An optional technical scheme, wherein, long and narrow spout sets up in the rear side of runner, and satisfies following requirement: when the left hand or the right hand adopts a finger holding method to operate the handle, the index finger of the operated hand can conveniently stir one button; when the left hand or the right hand adopts the hand holding method to operate the handle, the thumb of the operated hand can conveniently stir one of the buttons.

An alternative solution is provided, wherein the lock mechanism further comprises a lock bolt, a button and a resilient element; the lock mechanism includes an active mode and an inactive mode; the cantilever includes a plurality of serrations and the latch includes a locking tooth that mates with the serrations; the trigger also includes a first cam surface, a second cam surface and a finger catch, the button interacting with the first cam surface to drive the trigger to rotate about a trigger axis of rotation to effect switching of the lock mechanism between the active mode and the inactive mode.

An alternative technical solution, wherein when the lock mechanism is in an active mode, the elastic element drives the lock bolt to enable the lock teeth and the saw teeth to be meshed with each other, so that the rear handle is allowed to be folded towards the front handle and limited to be opened away from the front handle, namely, a locking function is achieved; the second cam surface can be selectively contacted with the lock plunger, external force is applied to drive the finger button to enable the trigger to rotate around the trigger rotating shaft, the second cam surface drives the lock plunger to move, the lock teeth and the saw teeth are separated from each other, and the rear handle is allowed to open away from the front handle, namely the unlocking function;

An alternative technical solution, wherein the button comprises a first button and a second button, and the first button and the second button are respectively arranged on two side surfaces of the front handle; the front handle comprises an elongated chute penetrating through two side surfaces of the front handle, and the first button and the second button can slide in the elongated chute; the elongated chute is oriented substantially parallel to the extension bar.

An optional technical scheme, wherein, long and narrow spout sets up in the rear side of runner, and satisfies following requirement: when the left hand or the right hand adopts a finger holding method to operate the handle, the index finger of the operated hand can conveniently stir one button; when the left hand or the right hand adopts the hand holding method to operate the handle, the thumb of the operated hand can conveniently stir one of the buttons.

Drawings

For a fuller understanding of the nature of the present invention, reference should be made to the following detailed description taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic representation of a prior art surgical instrument;

FIG. 2 is a schematic view of the finger grip of FIG. 1;

FIG. 3 is a schematic diagram of the hand grip of FIG. 2;

FIG. 4 is a schematic perspective view of a surgical instrument of the present invention;

FIG. 5 is a schematic view of the finger control zones of the surgical instrument of FIG. 4;

FIG. 6 is a schematic diagram showing the switching of the active mode to the inactive mode when the right hand is used for finger grip in FIG. 4;

FIG. 7 is a schematic diagram showing the switching from the inactive mode to the active mode when the right hand is used for finger grip in FIG. 4;

FIG. 8 is a schematic view of the active mode switching to the inactive mode when the hand grip is performed by the right hand in FIG. 4;

FIG. 9 is a schematic diagram of the active mode switching to the inactive mode of FIG. 7 using the right hand for hand grip;

FIG. 10 is an exploded view of the surgical instrument of FIG. 4;

FIG. 11 is a perspective view of the button slider shown in FIG. 10;

FIG. 12 is a further perspective view of the button slider of FIG. 11;

FIG. 13 is a perspective view of the trigger of FIG. 10;

FIG. 14 is a schematic view of the locking tab of FIG. 10;

FIG. 15 is a schematic view of the interior of the front handle of FIG. 10;

FIG. 16 is an interior schematic view of the front handle cover shown in FIG. 10;

FIG. 17 is a cut-away view of the present invention in a deactivated mode;

FIG. 18 is an enlarged view of a portion of FIG. 18-18 shown in FIG. 17;

FIG. 19 is a cut-away view of a locked state in an active mode of the present invention;

FIG. 20 is an enlarged view of a portion of 20-20 of FIG. 19;

FIG. 21 is a cut-away view of an unlocked state of the present invention;

FIG. 22 is an enlarged view of a portion of 22-22 of FIG. 21;

FIG. 23 is an exploded view of another embodiment surgical instrument;

FIG. 24 is an enlarged view of a portion of 24-24 of FIG. 23;

throughout the drawings, like reference numerals designate identical parts or elements.

Detailed Description

Embodiments of the present invention are disclosed herein, however, it is to be understood that the disclosed embodiments are merely exemplary of the invention, which may be embodied in various forms. Therefore, the disclosure herein is not to be interpreted as limiting, but merely as a basis for the claims and as a basis for teaching one skilled in the art how to employ the invention.

Referring to fig. 1-4, for convenience of description, the party closer to the operator is defined as proximal and the party farther from the operator is defined as distal.

As shown in fig. 1-3, in conjunction with the foregoing background, various minimally invasive surgical instruments, such as surgical hand-held instrument 10, may be inserted into a body cavity through a passageway formed by a cannula assembly (not shown) while the cannula assembly is inserted in place during a surgical procedure, particularly during a laparoscopic procedure. One or more cannula assemblies may need to be used simultaneously during a procedure, and the surgical hand-held instrument 10 may also be configured for one or more simultaneous operations depending on the surgical needs. FIG. 1 is a typical surgical hand-held instrument 10 of the prior art, including a distal working head 106, a proximal handle 11 and an extension 105 extending therebetween; the handle comprises a front handle 101, a rear handle 102 and a handle rotating shaft 103 connected with the front handle 101 and the rear handle 102, and the front handle 101 and the rear handle 102 can rotate relative to the handle rotating shaft 103; the front handle 101 includes a front finger loop 110, the rear handle 102 includes a thumb loop 120, and a support arm 112 is disposed at the bottom of the front finger loop 111. An unlocking trigger 115 is provided on the upper side of the front finger ring 111 for locking and unlocking the front handle 101 and the rear handle 102.

Current laparoscopic procedures generally include gallbladder surgery, laparoscopic inguinal hernia repair, laparoscopic fundoplication, laparoscopic splenectomy, laparoscopic appendectomy, and the like. The overall operation difficulty of the endoscopic surgery is high, the time required for the endoscopic surgery is long, and the duration of the operation of the surgeon is 1-3 hours. In order to reduce the growing time of the traditional Chinese medicine in the operation and operate the instrument in a difficult posture, the prior surgical handheld instrument considers the ergonomics principle to a certain extent, and can generally support a plurality of holding methods, reduce the extreme operation posture to a certain extent and relieve the fatigue. The finger grip method shown in fig. 2 and the hand grip method shown in fig. 3 are the two most commonly used methods.

Fig. 1 and 2 illustrate the use of a typical surgical handpiece 10 by a surgeon in a finger grip to pull an organ or grasp tissue: the ring finger of one hand of the surgeon passes through the front finger ring 111, wherein the finger is attached to the unlocking trigger 115 on the upper side of the front finger ring 111, and the inner side surface of the little finger is pressed on the supporting arm 112; movement of the thumb through the thumb loop 120 causes the rear grip 102 to rotate back and forth about the handle axis of rotation 103 and translates movement of the rear grip 102 into movement of the distal working head 106 by the stem 105.

The surgeon uses a typical surgical hand-held instrument 10 to perform a holding of a retractor or grasp tissue with a palm grip as shown in fig. 1 and 3: the palm of one hand of the surgeon is attached to the side of the handle 11, the thumb of the surgeon presses the opposite side of the handle 11 to clamp the rear handle 102 in the palm, forming a U-shaped clamp, the little finger of the surgeon presses on the supporting arm 112 of the front handle 101, the ring finger passes through the front finger ring 110, the finger is attached to the unlocking trigger 115 on the upper side of the front finger ring 110, the front handle 101 is rotated back and forth around the handle rotating shaft 103 by the movement, and the movement of the rear handle 102 is converted into the movement of the distal working head by the rod 105.

In clinical applications, the finger grip and palm grip are equally important and often require frequent switching. For example, when tissue dissection is required to be performed in clinical operations to expose blood vessels, a doctor of a main knife holds an ultrasonic knife or a separating clamp with one hand and carefully performs tissue dissection, and the other hand usually has to hold a grasping clamp to operate organs or tissues to form a synergistic effect, so that the tissue dissection operation can be accurately completed. When the surgical site is not sufficiently exposed or when the span of the space for the tissue removal site to change is large in a short time, the operator usually uses a finger grip method to operate the instrument, and it is necessary to set the lock mechanism in an inactive state. It will be appreciated by those skilled in the art that the finger grip and the disabled locking mechanism are the most flexible for manipulating the instrument, and thus the instrument can be opened and closed rapidly to grasp, clamp, pull and move the organ or tissue flexibly to flexibly match the tissue dissection. However, with finger grip and no auxiliary locking, the surgeon's fingers are quite fatigued. When the surgical site is sufficiently exposed or the site where tissue dissection is performed is not moved for a short time, the surgeon often desires to quickly switch to the lock function-enabled state, and to pull or toggle the organ or tissue that is obstructing the view by tightly clamping the organ or tissue with the locking force of the instrument itself. In the lock function active state, the device is not operated to perform multiple quick opening and closing actions. When the grasped or pulled organ or tissue is large or heavy, the surgeon or surgical assistant often switches to palm grasping because hand grasping tends to apply force easily and pose is more free to relax, facilitating a vigorous operation or relieving fatigue.

The prior art surgical device 10 illustrated in fig. 1 has inconvenient switching between the active and inactive states of the lock mechanism, particularly when using a palm grip. In addition, since the middle finger force position is just the unlocking trigger 115 position on the upper side of the front finger ring 111, when the instrument is operated to perform organ grabbing, if the middle finger is slightly forced, the middle finger is easy to press the trigger 115 to enable the handle 11 to be in an unlocking state, namely, the lock mechanism is easy to trigger unlocking by mistake.

FIGS. 4-22 depict in detail a hollow trigger-containing surgical instrument 20 according to an embodiment of the present invention, including a distal working head 23, a proximal scissor handle 21, and an extension 22 extending therebetween; the handle 21 comprises a front handle 206, a rear handle 202 and a handle rotating shaft 261 connected with the front handle 206 and the rear handle 202 can rotate relative to the handle rotating shaft 261; the handle rotation shaft 261 is integrally injection molded with the front handle 206 and movably connects the front handle 206 and the rear handle 202 through the rotation shaft hole 222. The handle pivot 261 may also be provided as a separate piece for articulating the front handle 206 and the rear handle 202. The extension bar 22 includes a rotating wheel 214, an outer bar 213, and an inner bar 215, the outer bar 213 and the rotating wheel 214 being fixed together and installed in the front handle 206, and the inner bar 215 having one end connected to the driving mechanism 211 and the other end connected to the rear handle 202 and being fixed in a fixing hole 221 of the rear handle 202 by a fixing shaft 218.

The working head 23 comprises a pair of jaws 210 and a driving mechanism connected thereto, the driving mechanism comprising a first connection block 217, a second connection block 216, a slider 212, a driving arm 211, and a pin 219. The first connecting block 217 and the second connecting block 216 are respectively and vertically symmetrically connected with the pair of clamp heads 210 and are assembled into the driving arm 211 together with the sliding block 212 to be fixed by pins 219. The distal end of the inner pull rod 215 is connected with the slide block 212, the inner pull rod 215 is driven to move to drive the slide block 212 to move, the first connecting block 217 is connected with the slide block 212 in a matched manner, and the second connecting block 216 drives the pair of clamp heads 210 to open and close. Those skilled in the art will readily appreciate that other disclosed linkages, slide mechanisms, or simple adaptations based on the prior art may be used to perform the same or similar functions in place of the working head 23 of the present invention. The hand-held device 20 may be classified into a surgical scissors with a scissors head, a grasper with a fine-toothed straight grasping head, a dissecting forceps with a bent grasping head, and the like, depending on the configuration of the working head 23. With the development of surgical hand-held instruments, more and more different types of working heads are within the scope of the present invention, not listed here.

In one embodiment, the front handle 206 includes a front finger loop 262 and the rear handle 202 includes a thumb loop 224. The front handle 206 and the rear handle 202 are operated to rotate relative to the handle rotating shaft 261 to be converted into linear motion of the inner pull rod 215, and the driving mechanism 211 drives the clamp head 210 to be closed or opened. The handle 21 also includes a lock mechanism 24, the lock mechanism 24 including an active mode and an inactive mode. In the inactive mode, the front handle 206 and the rear handle 202 can perform a rotary motion relative to the handle rotation shaft 261 to open and close the working head 23; in the active mode, the front handle 206 and the rear handle 202 can rotate relative to the handle rotation shaft 261, so that the rear handle 202 is allowed to be folded towards the front handle 206 and the rear handle 202 is limited to be opened away from the front handle 206, namely, the locking function is achieved; when an external force is applied to drive the trigger shaft to rotate, the rear handle 202 is allowed to open away from the front handle, namely, the unlocking function.

It will be appreciated by those skilled in the art that in laparoscopic surgery, due to the limitations of the surgical space, the surgeon often needs to operate the instruments in a difficult posture for a long time, and the surgeon is prone to fatigue and even induce the risk of arthritis, scapulohumeral periarthritis, etc. Therefore, laparoscopic hand-held devices, which are ergonomic or called human Ergonomics (Ergonomics), support a variety of grasping procedures, reduce extreme operating gestures and relieve fatigue, and are particularly important. Much research has been published about the human efficacy associated with laparoscopic surgery: representative studies include a review of the ergonomic issues in the laparoscopic operating rom, published in 2012, volume 3, 4, pages 587-603 of Journal of Healthcare Engineering, detailing the human efficacy risk of laparoscopic surgical instruments, and other references mention of the human efficacy defect of laparoscopic instruments and their risk, but no solution is given. Technical report, new ergonomic design criteria for handles of laparoscopic dissection forceps, volume 11, 2001, journal of laparoendoscopic & advanced surgical techniques, lists some ergonomic evaluation measures, however, the evaluation measures are limited to handle length dimensions based on anthropometric statistics, finger ring size design recommendations, and roughly give a way to evaluate different holding experiences of existing handles, however no design recommendation or suggestion for functional performance is given.

Ergonomics is a very complex discipline, and is defined by the International Ergonomic Association (IEA), which is a "various factors in the anatomy, physiology, and psychology of a researcher in a certain work environment; research on interactions of people and machines and environments; the study on how to uniformly consider the working efficiency, health, safety and comfort of the person in work, family life and holiday is the subject. However, so far little of the disclosed patent technology has been disclosed with respect to ergonomic applications or related studies of laparoscopic hand instruments. The invention adopts the principle of ergonomics, and utilizes the comprehensive disciplines of anthropometry, biomechanics, time, working research and the like for test and statistical research to provide a laparoscopic handheld instrument which accords with the ergonomics and a design method and a use method thereof.

Briefly, the present invention generally partitions a surgical instrument 20 as shown in FIG. 5: defining the length D from the handle rotation shaft 261 to the center position of the thumb ring 224 of the rear handle 202, the extension rod portion 22 comprises a first axis 1000, a second axis 2000 is arranged in the direction perpendicular to the first axis 1000 through the handle rotation shaft 261, the first axis 1000 and the second axis 2000 are intersected at an intersection point 1001, the intersection point 1001 is arranged in a square area with the length D along the proximal end of the first axis 1000 in the distal direction and along the direction from the intersection point to the handle rotation shaft along the second axis 2000, the square area is divided into two equal parts (D/2) along the first axis 1000, and three equal parts (D/3) along the second axis 2000 are arranged into an A1 area, an A2 area, an A3 area, a B1 area, a B2 area and a B3 area. It should be further noted that the specific value of D is not constant, and the value varies in a small interval, as the aforementioned "length from the handle rotation axis 261 to the center of the thumb ring 224 of the rear grip 202 is D". Experimental research and statistics are carried out based on anthropometry and biomechanics principles to obtain an optimal D value interval of which D is more than or equal to 60 and less than or equal to 70 (unit: millimeter).

In order to give consideration to the hand types of different people and different holding methods, in an alternative scheme, a first button 237 for controlling the switching state of the active mode and the inactive mode is arranged in an area A1, a trigger 205 is arranged in an area A2, a middle finger pressing area is arranged in an area A3, and a rotating wheel 214 is arranged in an area B1. In still another preferred embodiment, the first button 237 is disposed in the corresponding area A1 of the handle 21, the second button 237a is disposed at a symmetrical position A1-1 of the area A1 along the plane formed by the second axis 2000 and the first axis 1000, and the operation of the first button 237 or the second button 237a can control the handle 21 to switch between the active mode and the inactive mode.

The operating principle of the button, trigger and wheel position design is described in more detail below. When the finger holding method is adopted, as shown in fig. 6-8, taking the right hand operation of an operator as an example, the ring finger passes through the front finger ring 262, the middle finger is attached to the area A3 on the upper side of the front finger ring 262, and the index finger can flexibly control the area A1, the area A2 or the area B1. The index finger acts primarily to push the first button 237 proximally and distally in the area A1, primarily to depress the control trigger 205 in the area A2, and primarily to toggle the rotating wheel 214 back and forth in the direction of rotation of the wheel 214 in the area B1.

Further, when the finger holding method is adopted, the index finger reaches the B1 area and is basically in a straightened state. In the B1 region, the index finger in the straightened state is not convenient to apply force and exert force by pressing or pushing back and forth along the direction of the first axis 1000, so that the state button is not suitable to be arranged. The index finger can comfortably rotate and stir along the rotating direction of the rotating wheel 214 in the region B1. When the index finger is in the A1 area and the A2 area, the finger is in a bending state, so that the pressing or pushing action can be comfortably performed. The first button 237 is arranged in the A1 area, the trigger 205 is arranged in the A2 area, and the rotating wheel 214 is arranged in the B1 area, so that the index finger can conveniently stir and rotate the rotating wheel 214, meanwhile, the first button 237 can be conveniently pushed to realize the switching between the effective mode and the ineffective mode, and meanwhile, the trigger 205 can be conveniently pressed or pulled to realize the switching between the locking state and the unlocking state. It will be appreciated by those skilled in the art that in the surgical arts, and in particular in the endoscopic surgery arts, the surgeon's index finger is often referred to as index finger, and is not typically a choice of the output operating force operating handle, and is typically used to control instrument orientation or switch status buttons, etc. The above-described various states, switching or manipulation of functions is quite frequent, and in laparoscopic surgery, convenience of switching and manipulation of various states is very important because the eyes of the surgeon are often closely focused on the front horizontal monitor, and the operator's hand or patient area is not available to look at the operator at low head.

As shown in fig. 9, when the right hand of the surgeon is changed from finger grip to hand grip, the palm of the surgeon is pressed against the side of the scissor handle 21, and the thumb presses the opposite side of the scissor handle 21 to clamp the rear grip 202 in the palm, forming a U-shaped grip. At this time, the index finger can still conveniently stir and rotate the rotating wheel 214, and simultaneously can conveniently press or pull the trigger 205 to realize the switching of the locking state and the unlocking state; at this time, the first button 237 in the switch state in the A1 region cannot be operated by the index finger due to the blocking of the grip of the palm, however, at this time, the thumb of the surgeon just presses the A1-1 region, so that the second button 237a can be conveniently pushed to realize the switch between the active mode and the inactive mode.

In a preferred embodiment of the present invention, the first button 237 and the second button 237a are generally symmetrical about a plane formed along the second axis 2000 and the first axis 1000, and those skilled in the art will readily appreciate that such symmetrical relationship allows a surgeon to operate the surgical device 20 with a left-hand finger grip or a palm grip, and is substantially identical to a right-hand operation using the surgical device 20 of the present invention, and therefore will not be described in detail.

In summary, the first button, the second button, the trigger and the rotating wheel are arranged in a position relation, so that the rotating wheel can be conveniently rotated by the index finger when the right hand (left hand) finger is held, the effective mode and the ineffective mode are switched, and the locking state and the unlocking state are switched. The hand-held device can also meet the requirements that when a right hand (left hand) holds a hand-held method, the index finger conveniently completes the rotation of the rotating wheel, the locking state and the unlocking state are switched, and the thumb completes the switching of the effective mode and the ineffective mode. Moreover, the arrangement of the position relationship can also meet the requirement of convenient switching between the finger holding method and the finger holding method. The beneficial effects of the method can be simply and generally described as follows: the method can conveniently and rapidly change the finger holding method and the palm holding method by only relying on the tactile feedback of an operator, and conveniently and rapidly operate the rotating wheel to rotate, switch between an effective mode and an ineffective mode and switch between a locking state and an unlocking state.

Research has shown that no patent technology or literature has disclosed the laparoscopic instrument and its design method and method of use described in the present invention so far. Nor does it disclose, or produce, or sell any laparoscopic instruments described herein by an enterprise, community or individual. In the disclosed prior art, a common laparoscopic surgical instrument has its lock mechanism state switching button disposed in the B1 region (e.g., the structure disclosed in U.S. patent No. 5626608), has been mass-produced similarly to this patent technology, and has been used as a laparoscopic surgical instrument (e.g., a laparoscopic grasper series sold under the Auto procedure brand), has its lock mechanism state switching button disposed in the B1 region, has insufficient comfort in switching between an active mode and an inactive mode when such an instrument is operated by a finger grip method, and has inconvenience in supporting switching between an active mode and an inactive mode under the hand grip method. Another common laparoscopic surgical instrument has its locking/unlocking trigger disposed in the B2 region and includes only two states, a locked state and an inactive state (e.g., the structure disclosed in U.S. patent No. 6117158), and laparoscopic surgical instruments (e.g., the series of laparoscopic graspers sold under the brand name ENDOPATH) similar to this patent technique have been mass produced and used, and has its locking/unlocking button disposed in the B2 region, which is inconvenient for the relevant switching of the locking function when operated with either a finger grip or a palm grip. Another common laparoscopic surgical instrument has a lock/unlock trigger disposed in the A3 region and an active/inactive mode switching button disposed in the A2 region (e.g., the structure disclosed in U.S. patent No. 8551077, U.S. patent application No. 20060004406), which is similar to this patent technique, has been mass produced and used laparoscopic surgical instruments (e.g., the laparoscopic grasper series sold under the CLICKline brand), a lock/unlock trigger disposed in the A3 region and an active/inactive mode switching button disposed in the A2 region. This design typically requires a middle finger operated trigger to lock/unlock the switch and a middle or index finger operated button to switch the active/inactive modes, making the operation and switching uncomfortable. It should be particularly pointed out that locating the trigger in the A3 region may cause a number of inconveniences. The most common problems mainly include that when the instrument is in a locked state, no matter a surgeon grasps the instrument with fingers or holds the instrument with hands, when the operator clamps an organ or tissue with the instrument (a grasping forceps) and pulls the organ or tissue, the middle finger is almost required to be used for auxiliary force application, and the trigger is extremely easy to touch in the state, so that the trigger is triggered by mistake, the instrument is accidentally switched from the locked state to the unlocked state, the organ or tissue is slipped off, clinical use inconvenience is caused, and even medical accidents are induced.

The composition and structure of the lock mechanism 24 is depicted in fig. 10-16. As shown in FIG. 10, the lock mechanism 24 includes a trigger 205, a locking tab 208, and a toothless cantilever 226 integral with the rear handle 202. The toothless cantilever 226 includes a toothless cantilever body 223 projecting outwardly from the rear handle 202 and a cantilever distal end 227. The toothless cantilever body 223 is provided with an arc structure and comprises a cantilever inner wall 229 and a cantilever outer wall 228, wherein the cantilever inner wall 229 and the cantilever outer wall 228 are shaped to extend from the joint of the handle 202 along the handle rotation axis 261 as the center of a circle to form the toothless cantilever body 223 forming a concentric arc. The toothless cantilever 223 material comprises a plastic material integrally molded with the rear handle 202, but may be made of other semi-rigid or rigid materials or even flexible materials. The lock mechanism 24 further comprises a push button assembly 25 and a resilient member 250, the trigger 205, the resilient member 250 and the push button assembly 25 being mounted together in the front handle 206. The resilient member 250 drives the trigger 205 to return after being pressed. The trigger 205 controls the locking tab 208 to cooperate with the toothless cantilever 226 to effect locking and unlocking. Toothed locking belts are commonly used in the prior art, and locking teeth of the locking belts are easily exposed out of a handle, so that fingers or gloves of an operator can be scratched. Meanwhile, when the toothed locking belt is used, the space between each locking tooth is determined by the density degree of the locking teeth, and then the degree of clamping tissue and organs by the working head of the surgical instrument is determined. It should be understood by those skilled in the art that, during the operation of high-force pulling, in order to maintain continuous clamping pulling, if the force is insufficient, the state of the device cannot be maintained during high-force pulling, so that the sliding of tissues and organs is easy to occur, the operation progress is affected, and even the operation fails; on the other hand, if the working head is excessively clamped, damage to tissues and organs can be caused, and recovery of a patient is not facilitated. The locking belt can adjust the clamping degree of the working head through the encryption locking teeth, but the locking teeth are too small, so that the locking mechanism is unreliable, the locking mechanism is in slip failure, and the clamping force is not enough or is too large because a certain locking tooth spacing is maintained. The toothless cantilever body 223 is matched with the locking plate 208, so that the locking of any position can be realized, the clamping force can meet the clamping requirements of different operations and different tissue organ positions, the stepless change is realized, and the surgical instrument 20 can keep proper clamping force positions and clamping forces.

As shown in fig. 10-12, the button assembly 25 includes a button slider 203 and a first button 237 and a second button 237a. The button block 203 includes a slider body 230 with a limit slot 231, the slider body 230 including slider sidewalls 234 (235) and a limit stop 233. The slider side walls 234 (235) and the limit stop 233 together define a limit slot 231. The sliding block side wall 234 (235) extends outwards to form a button mounting column 232 which is matched and fixed with the first button 237 and the second button 237a, and pushing the first button 237 or the second button 237a can be used for driving the button sliding block 203 to slide from the distal end to the proximal end or from the proximal end to the distal end, so that the trigger 205 is pushed to rotate, and the effective mode and the ineffective mode are switched. The first button 237 includes a friction bar 238 with a curved surface to facilitate finger force.

As shown in FIG. 13, the trigger 205 includes a trigger pivot aperture 258, a first cam surface 251, a second cam surface 255, and a finger grip 259. The trigger 205 includes a generally crescent shaped trigger body 254, the trigger body 254 may be other shapes, the first cam surface 251 being disposed on one side of the trigger body 254 and the finger knob 259 being disposed on the other side of the trigger body 254. The trigger body 254 is provided with an aperture 257 adjacent to the first cam surface 251 for mounting the resilient member 250. The trigger pivot hole 258 is provided through the trigger body 254 between the first cam surface 251 and the finger grip 259. The first cam surface 251 includes a cam arc segment 253 and a cam straight surface 252. When the push button assembly 25 is pushed to move from the proximal end to the distal end, the limit stop 233 of the push button assembly 25 is in contact engagement with the cam arc 253 and the cam linear surface 252 of the first cam surface 251, respectively, thereby pushing the trigger 205 to rotate to switch from the active mode to the inactive mode. A second cam surface 255 extends outwardly along the side of the trigger body 254, the second cam surface 255 rotating with the trigger 205 to urge the locking tab 208 into and out of engagement with the toothless cantilever 226. The finger buckle 259 is provided with a blind cavity structure 207 facing away from the direction, and the blind cavity structure 207 comprises a blind cavity opening 271 and a blind cavity 272. The cantilever 226 may penetrate the front handle 206 and enter the blind cavity structure 207 through a blind cavity opening 271. In the prior art, the trigger is usually provided in a solid form, for example, one of the prior art is provided with a clearance area in an A2 area and a trigger position in an A3 area, and the arrangement mode can prevent the finger from making the finger inconveniently exert force on one hand, and the trigger position is just the middle finger force application area position on the other hand, so that misoperation of the trigger is very easy to be caused. The blind cavity 272 of the present invention is larger in shape and size than the cantilever 226, and in any state, the cantilever 226 does not interfere with the blind cavity 272, and the blind cavity 272 keeps the cantilever distal end 227 from being exposed outside the front handle and trigger. The trigger 205 can just hold the cantilever 226 in the closed state by arranging the hollow blind cavity structure 207, so that the cantilever 226 is prevented from being additionally arranged on the front handle 206, parts of the front handle 206 are effectively simplified, the front handle 206 is more concise, meanwhile, the trigger 205 can be arranged in the A2 area because of no limitation of the arranged clearance area, the shape of the front handle 206 can be better matched with the force condition of fingers, and the convex clearance area is prevented from blocking the force of the fingers.

As shown in fig. 14, the locking tab 208 includes a locking hole 284 that matches the shape and size of the toothless cantilever 226, and the toothless cantilever 226 penetrates the locking hole 284. The locking tab 208 includes a first tab 281, a second tab 283, and a transition 282 connecting the two, the first tab 281, the second tab 283, and the transition constituting a generally "Z" shaped locking tab 208. The proximal end surface of the second plate 283 is provided with a locking plate spring 204. The second tab 283 and the locking plate spring 204 may be connected by welding, or by a loose axle definition, or the like. The lock hole 284 of the first sheet 281 includes a first lock hole wall 285 and a second lock hole wall 286, the first lock hole wall 285 and the second lock hole wall 286 substantially match the cantilever inner wall 229 and the cantilever outer wall 228 of the toothless cantilever 226, and a distance between the first lock hole wall 285 and the second lock hole wall 286 is greater than a distance between the cantilever inner wall 229 and the cantilever outer wall 228. The locking tab 208 material comprises a rigid material, such as a metallic material, a thermosetting plastic material, or may comprise a semi-rigid type. When the second cam surface 255 of trigger 205 is selectively in contact with the locking tab 208, application of an external force actuates the finger knob 259 such that the trigger 205 rotates about the trigger axis 161, and the second cam surface 255 actuates the locking tab 208 to move into clearance engagement with the toothless cantilever 226, allowing the rear handle 206 to expand away from the front handle 202; alternatively, when the first sheet 281 is substantially perpendicular to the toothless cantilever 226, the first locking hole wall 285 is in clearance fit with the cantilever inner wall 229, the second locking hole wall 286 is in clearance fit with the cantilever outer wall 228, the toothless cantilever 226 rotates around the handle rotation axis 261, and the toothless cantilever 226 can freely pass through the locking hole 284, which corresponds to an unlocked state or an inactive mode. When the first blade 281 is in oblique contact with the toothless cantilever 226, the locking blade spring 204 drives the locking blade 208 to tightly fit with the toothless cantilever 226, the first locking hole wall 285 is in compressive contact with the cantilever inner wall 229, the second locking hole wall 286 is in compressive contact with the cantilever outer wall 228, and the toothless cantilever 226 rotates about the handle pivot 261, allowing the rear handle 202 to fold toward the front handle 206 and limiting the rear handle 202 from opening away from the front handle 206, which is a locking function.

As shown in fig. 5, 6 and 15-16, a front handle 206 is depicted to which the securing lock mechanism 24 is mounted. The front handle 206 also includes a front handle cover 209 that mates therewith. The front handle 206 has a generally symmetrical configuration with the front handle cover 209 except for the front finger loop 262. In the general area A1-1 and the area A1, the front handle cover 209 and the front handle 206 are symmetrically provided with a first chute 297 and a second chute 267, respectively, and the first chute 297 and the second chute 267 define the button slider 203 to move back and forth along the chute direction. In this embodiment, the first runner 297 and the second runner 267 are elongated runners, and the elongated runners are oriented substantially parallel to the extension bar 22, and those skilled in the art will appreciate that the first runner 297 and the second runner 267 may be configured as arcuate runners or channels.

In the general areas A1-1 and A1, the front handle 206 includes a handle shaft 261 and a trigger shaft 269 fixed thereto, and the handle shaft 261 and the trigger shaft 269 may be provided as separate parts fixed to the front handle 206, or the front handle 206 may be injection-molded as one part. The front handle cover 209 is provided with a fixing column 291 (299) at a position corresponding to the handle rotation shaft 261 and the trigger rotation shaft 269. An alternative solution is to provide the trigger 205 with a trigger shaft 269, wherein the trigger shaft 269 is integrally formed with the trigger shaft hole 269 of the trigger 205, and the front handle cover 209 is provided with a shaft hole corresponding to the front handle 206. In the general region B1 and its symmetrical region, the front handle 206 further includes a distally located wheel mounting slot 265 and the front handle cover 209 includes a wheel mounting slot 295. The wheel mounting slots 265 (295) together define a wheel for rotational movement within the slots. In the general area A2 and its symmetry, the front handle 206 and front handle cover 209 include a cantilever slot 263 (293) for receiving the rear handle 202 through the toothless cantilever 226, the cantilever slot 263 (293) forming a complete cantilever opening that is larger in size than the toothless cantilever 226 and the toothless cantilever 226 does not contact the cantilever slot 263 (293) when rotated about the handle axis of rotation. The front handle 206 and front handle cover 209 also include a trigger channel 266 (296) for receiving the mounting trigger 205, and the cantilever groove 263 (293) and trigger channel 266 (296) form a throughgoing bore through the front handle 206. The trigger channel 266 (296) may receive the toothless cantilever 226 when the surgical device 20 is closed. The front handle 206 and front handle cover 209 also include support slots 264 (294) that define the leverage of the locking tab 208, the support slots 264 (294) being defined by two side projecting ribs 260 (290). Ribs 260 (290) of support slots 264 (294) act as rotational support points during rotational movement of locking tab 208. The front handle 206 and front handle cover 209 also include a spring slot 268 (298) for defining a locking tab spring 204, with one end of the locking tab spring 204 being connected to the locking tab 208 and the other end being defined in the spring slot 268 (298) in a compressed state.

The switching of the lock mechanism 24 between the active mode and the inactive mode is illustrated in detail in fig. 5 and 17-20. When the finger grip is used, the right hand operation of the surgeon is exemplified, the ring finger passes through the front finger ring 262, wherein the finger is attached to the A3 area on the upper side of the front finger ring 262, and the index finger can flexibly control the A1 area, the A2 area or the B1 area. When the surgical device 20 requires a quick closing and opening operation, such as is typical for vascular dissection during gallbladder surgery, it is necessary to switch the surgical device 20 from an active mode to an inactive mode. The index finger is moved in the area A1 by a first button 237 pushing the button assembly 25 distally along the proximal end, the first button 237 moving the button block 203 along the first runner 297 and the second runner 267. The positive stop 233 of the button block 203 interacts with the first cam surface 251 to drive the trigger 205 to rotate clockwise about the trigger axis 269, during which time the second cam surface 255 of the trigger 205 rotates clockwise with the trigger 205 to urge the second tab 283 of the locking tab 208 to rotate counterclockwise, the first tab 281 rotating cocked to engage the locking aperture 284 in clearance engagement with the toothless cantilever 226. When the limit stop 233 moves to the cam straight surface 252 of the first cam surface 251, the trigger 205 and the button block 203 form self-locking, and the elastic member 250 cannot be reset. At this point, the lock mechanism 24 is switched from the active mode to the inactive mode, and those skilled in the art will appreciate that in the inactive mode, the front grip 206 and the rear grip 202 of the handle 21 can be conveniently closed and opened to meet the needs of the tissue to be peeled and sheared during the finger grip, since the lock hole 284 is always in a clearance fit with the toothless cantilever 226. When the surgeon uses the right hand to grasp the hand by the finger grip switch to pull the organ or tissue with great force and effect the bite, the surgical instrument 20 needs to be switched from the inactive mode to the active mode. The surgeon's palm is held against the side of the scissor handle 21 and the thumb holds the opposite side of the scissor handle 21 to clamp the rear grip 202 in the palm, forming a U-shaped grip. Because the clamping of the palm is blocked, the index finger cannot control the first button 237 in the switch state in the A1 area, and the thumb presses the first button 237 in the A1-1 area, the second button 237a can be conveniently pushed to push and move along the far end and the near end by the thumb, and the second button 237a drives the button block 203 to move along the first chute 297 and the second chute 267. The limit stop 233 of the button block 203 interacts with the first cam surface 251 to drive the trigger 205 to rotate anticlockwise around the trigger rotation shaft 269, during this process, the trigger 205 is reset under the action of the elastic element 250, the second cam surface 255 rotates anticlockwise along with the trigger 205 to drive the second sheet 283 and drive the first sheet 281 of the locking plate to rotate clockwise for reset, the first sheet 281 is in inclined contact with the toothless cantilever 226, the locking plate spring 204 drives the locking plate 208 to tightly fit with the toothless cantilever 226, the first locking hole wall 285 is in pressing contact with the cantilever inner wall 229, the second locking hole wall 286 is in pressing contact with the cantilever outer wall 228, and the toothless cantilever 226 rotates around the handle rotation shaft 261 to allow the rear handle 202 to fold towards the front handle 206 to limit the rear handle 202 from opening away from the front handle 206. At this time, the surgeon can realize the engagement and locking of the working head 23 through the pressing friction between the locking plate 208 and the toothless cantilever 226, so as to avoid the fatigue of the palm caused by long-time clamping force. It will be appreciated by those skilled in the art that the above-described active and inactive modes are switched between each other, and can be freely operated in one hand, either by finger gripping or palm gripping. During the above operation, when the rear handle 202 is folded with the front handle 206, the cantilever 226 can penetrate the through hole of the front handle 206 and enter the blind cavity structure 207; the blind cavity structure 207 just accommodates the cantilever 226 without interference at any time, avoiding the additional provision of a raised clearance area on the front handle 206 to accommodate the cantilever 226.

In addition, when the left-handed surgeon performs the switching operation between the effective mode and the ineffective mode, the whole operation process is similar, and the difference is that when the right hand performs the finger holding method, the index finger is used for holding the first button 237, and when the palm holding method is adopted, the thumb is used for holding the second button 237a; while the left hand is used for finger holding, the index finger is used for pushing the second button 237a, and the thumb is used for pushing the first button 237 when the palm holding is used. It will be appreciated by those skilled in the art that by providing the first button 237 and the second button 237a in the A1 region and the A1-1 region of the handle 21, on the one hand, the surgeon can conveniently switch between the active mode and the inactive mode in different surgical environments, such as a quick peeling operation for closing and opening or a long-time operation for a retractor, etc., using the same hand, without requiring another hand for cooperation or for cooperation by other people; on the other hand, the operation doctor who is either right-handed or left-handed can realize the mutual switching between the active mode and the inactive mode by one hand.

Fig. 5, 14 and 19-22 detail the switching of the lock mechanism 24 between the locking and unlocking functions in the active mode. It is first confirmed that the first button 237 or the second button 237a of the handle 21 is in the proximal position, i.e., the surgical device 20 is in the active mode. As shown in fig. 15 to 16, when it is necessary to perform a large force pulling of an organ for a long time, a brief description will be given by taking a hand-held method as an example by an operator. The palm of the surgeon is attached to the side of the scissor-type handle 21, the thumb of the surgeon presses the opposite side of the scissor-type handle 21 to clamp the rear handle 202 in the palm, a U-shaped clamping is formed, the rear handle 202 serves as a fixed handle, the little finger of the surgeon presses on the supporting arm 264 of the front handle 206, the ring finger passes through the front finger ring 262, the ring finger is attached to the upper side of the front finger ring 262, and the ring finger and the little finger exert force together to drive the front handle 206 to rotate so as to fold the handle 21, and further the working head 23 and the closed clamping are realized. In this process, the front handle 206 rotates clockwise from the distal end to the proximal end, the rear handle 202 rotates counterclockwise relative to the front handle 206, the toothless cantilever 226 rotates around the handle rotation shaft 261, the first blade 281 is pushed to move counterclockwise, the second blade 283 pushes the compressed locking plate spring 204, at this time, the first locking hole wall 285 contacts the cantilever inner wall 229, the second locking hole wall 286 contacts the cantilever outer wall 228, but the rear handle 202 is not influenced to fold toward the front handle 206, the cantilever 226 penetrates through the through hole of the front handle 206 and enters the blind cavity structure 207 of the trigger 205, and the cantilever distal end 227 is not interfered by the blind cavity structure 207 of the trigger 205. Once the closing movement is stopped, the first tab 281 is in angled contact with the toothless cantilever 226, the first latch wall 285 is in compressive contact with the cantilever inner wall 229, and the second latch wall 286 is in compressive contact with the cantilever outer wall 228, limiting the rear handle 202 from opening away from the front handle 206, due to the reaction force of the latch spring 204 after compression driving the latch 208 into tight engagement with the toothless cantilever 226. At this time, the surgeon can realize the engagement and locking of the working head 23 through the pressing friction between the locking plate 208 and the toothless cantilever 226, so as to avoid the fatigue of the palm caused by long-time clamping force.

As shown in fig. 14 and 21-22, when an unlocking operation is required, a brief description will be given by taking a hand-held method as an example by an operator. The palm of the surgeon is tightly attached to the side surface of the scissor-type handle 21, the thumb of the surgeon presses the opposite side surface of the scissor-type handle 21 to clamp the rear handle 202 in the palm, a U-shaped clamping is formed, the rear handle 202 serves as a fixed handle, the little finger of the surgeon presses on the supporting arm 264 of the front handle 206, the ring finger passes through the front finger ring 262, the ring finger is attached to the upper side position of the front finger ring 262, the finger button 259 is driven to rotate clockwise by applying external force through the pressing of the index finger to drive the second cam surface 255 to rotate along with the trigger 205, the second cam surface 255 of the trigger 205 rotates clockwise along with the trigger 205 to push the second sheet body 283 of the locking sheet 208 to rotate anticlockwise, and the first sheet body 281 rotates and is tilted up to be in clearance fit with the lock hole 284 and the toothless cantilever 226. The second tab 283 pushes against the compressed locking tab spring 204, at which time the first locking hole wall 285 is not in contact with the cantilever inner wall 229 and the second locking hole wall 286 is not in contact with the cantilever outer wall 228, allowing the rear handle 202 to be opened away from the front handle 206, i.e., an unlocking function. The handle 202 and the front handle 206 can be freely closed and opened while the index finger is kept pressing the trigger 205. When the index finger releases the finger button 259, the trigger 205 automatically resets under the action of the elastic member 250, the second cam surface 255 is separated from the second plate 283, the locking piece 208 automatically resets under the rebound action of the locking piece spring 204, and the locking piece 208 is pressed against the toothless cantilever 226.

It will be appreciated by those skilled in the art that the present invention employs the toothless cantilever 226 and the locking tab 208 to achieve the unlocking and locking functions of the surgical instrument 20, and can achieve locking at any position during the folding process of the handle 21, thereby meeting the clamping requirements of different operations and different tissue organ positions, achieving stepless variation, overcoming the drawbacks caused by toothed locking, and enabling the surgical instrument 20 to maintain a suitable clamping force position and clamping force.

23-24, surgical instrument 30 is substantially identical to surgical instrument 20, and is replaced with a toothless cantilever arm 226 and locking tab 208 for locking by lock mechanism 24, with a toothed cantilever arm 326 and locking tab 308 cooperatively performing a locking function and an unlocking function.

The surgical instrument 30 includes a distal working head 23, a proximal scissor handle 31 and an extension 22 extending therebetween; the handle 31 includes a front grip 206, a rear grip 202, and a handle rotation shaft 261 connected thereto, and the front grip 206 and the rear grip 202 are rotatably movable with respect to the handle rotation shaft 261. The handle 31 includes a lock mechanism 34, and both the lock mechanism 34 and the lock mechanism 24 include an active mode and an inactive mode, which are switched in the same manner and are not described in detail herein. The lock mechanism 34 includes a cantilever 326 extending from the rear handle 202 that cooperates with the throw 308 to effect locking. The cantilever 326 includes a plurality of serrations 327 and the latch 308 includes a lock tooth 381 that mates with the serrations 327; when the lock mechanism 34 is in the active mode, the elastic member 250 drives the lock plunger 308 so that the lock teeth 381 and the saw teeth 327 mesh with each other, allowing the rear handle 202 to be folded toward the front handle 206 and restricting the rear handle from being opened away from the front handle 206, i.e., a locking function; the second cam surface 255 of the trigger 205 may be selectively in contact with the latch 308, an external force may be applied to actuate the finger knob 259 such that the trigger 205 rotates about the trigger axis 269, and the second cam surface 255 may actuate the latch 308 such that the lock teeth 381 and the serrations 327 disengage from one another, allowing the rear handle to be opened away from the front handle 206, i.e., an unlocking function. In this process, the hollow blind cavity structure 207 of the trigger 205 just can accommodate the cantilever 326 in the closed state, so that the cantilever 326 is prevented from being accommodated by additionally arranging a convex clearance area on the front handle 206, parts of the front handle 206 are effectively simplified, the front handle 206 is more concise, meanwhile, the trigger 205 can be arranged in the A2 area because no limitation of the clearance area is arranged, and the shape of the front handle 206 can be better matched with the force condition of fingers, so that the convex clearance area is prevented from blocking the force of fingers.

Many different embodiments and examples of the invention have been shown and described. One of ordinary skill in the art will be able to make adaptations to the method and apparatus by appropriate modifications without departing from the scope of the invention. Several modifications have been mentioned, and other modifications are conceivable to the person skilled in the art. The scope of the present invention should therefore be determined with reference to the appended claims, rather than with reference to the structures, materials, or acts illustrated and described in the specification and drawings.

Claims (6)

1. A hollow trigger-containing surgical instrument comprising a distal working head, a proximal handle and an extension rod extending therebetween; the handle comprises a front handle, a rear handle and a handle rotating shaft connected with the front handle and the rear handle, and the front handle and the rear handle can rotate relative to the handle rotating shaft; the working head part comprises a pair of clamp heads and a driving mechanism connected with the clamp heads; the lengthening bar part comprises a rotating wheel, an outer bar part and an inner pull rod, wherein the outer bar part and the rotating wheel are fixed together and are arranged in the front handle, one end of the inner pull rod is connected with the driving mechanism, and the other end of the inner pull rod is connected with the rear handle,

1) The handle further comprises a lock mechanism;

2) The lock mechanism comprises a cantilever connected with the rear handle into a whole, and the lock mechanism also comprises a trigger;

3) The trigger is arranged in the front handle, part of the trigger is exposed out of the front handle, and the trigger comprises a trigger rotating shaft and a blind cavity structure with one side open;

4) After the rear handle is folded towards the front handle, the cantilever can penetrate through the through hole of the front handle and enter the blind cavity structure; the trigger is rotatable about the trigger axis of rotation, and the blind cavity structure is shaped and dimensioned to: the trigger is rotated without interfering with the cantilever, and the cantilever distal end of the cantilever is not exposed outside the front handle and the trigger;

5) The lock mechanism further comprises a locking piece, a button and an elastic element; the lock mechanism includes an active mode and an inactive mode; the locking plate comprises a locking hole matched with the appearance and the size of the cantilever, and the cantilever penetrates through the locking hole; the trigger also comprises a first cam surface, a second cam surface and a finger button, wherein the button interacts with the first cam surface to drive the trigger to rotate around a trigger rotating shaft so as to realize the switching of the lock mechanism between an effective mode and an ineffective mode;

6) When the lock mechanism is in an effective mode, the elastic element drives the locking plate to be tightly matched with the toothless cantilever, and the rear handle is allowed to be folded towards the front handle to limit the rear handle to be opened away from the front handle, namely a locking function; the second cam surface can be selectively contacted with the locking plate, external force is applied to drive the finger button to enable the trigger to rotate around the trigger rotating shaft, the second cam surface drives the locking plate to move and enable the locking plate to be in clearance fit with the toothless cantilever, and the rear handle is allowed to be opened away from the front handle, namely the unlocking function.

2. The surgical instrument of claim 1, wherein the button comprises a first button and a second button, the first button and the second button being mounted on two sides of the front handle, respectively; the front handle comprises an elongated chute penetrating through two side surfaces of the front handle, and the first button and the second button can slide in the elongated chute; the elongated chute is oriented substantially parallel to the extension bar.

3. The surgical instrument of claim 2, wherein the elongated chute is disposed on a rear side of the wheel and meets the following requirements: when the left hand or the right hand adopts a finger holding method to operate the handle, the index finger of the operated hand can conveniently stir one button; when the left hand or the right hand adopts the hand holding method to operate the handle, the thumb of the operated hand can conveniently stir one of the buttons.

4. A hollow trigger-containing surgical instrument comprising a distal working head, a proximal handle and an extension rod extending therebetween; the handle comprises a front handle, a rear handle and a handle rotating shaft connected with the front handle and the rear handle, and the front handle and the rear handle can rotate relative to the handle rotating shaft; the working head part comprises a pair of clamp heads and a driving mechanism connected with the clamp heads; the lengthening bar part comprises a rotating wheel, an outer bar part and an inner pull rod, wherein the outer bar part and the rotating wheel are fixed together and are arranged in the front handle, one end of the inner pull rod is connected with the driving mechanism, and the other end of the inner pull rod is connected with the rear handle,

1) The handle further comprises a lock mechanism;

2) The lock mechanism comprises a cantilever connected with the rear handle into a whole, and the lock mechanism also comprises a trigger;

3) The trigger is arranged in the front handle, part of the trigger is exposed out of the front handle, and the trigger comprises a trigger rotating shaft and a blind cavity structure with one side open;

4) After the rear handle is folded towards the front handle, the cantilever can penetrate through the through hole of the front handle and enter the blind cavity structure; the trigger is rotatable about the trigger axis of rotation, and the blind cavity structure is shaped and dimensioned to: the trigger is rotated without interfering with the cantilever, and the cantilever distal end of the cantilever is not exposed outside the front handle and the trigger;

5) The lock mechanism further comprises a lock bolt, a button and an elastic element; the lock mechanism includes an active mode and an inactive mode; the cantilever includes a plurality of serrations and the latch includes a locking tooth that mates with the serrations; the trigger also comprises a first cam surface, a second cam surface and a finger button, wherein the button interacts with the first cam surface to drive the trigger to rotate around a trigger rotating shaft so as to realize the switching of the lock mechanism between an effective mode and an ineffective mode;

6) When the lock mechanism is in an effective mode, the elastic element drives the lock bolt to enable the lock teeth and the saw teeth to be meshed with each other, so that the rear handle is allowed to be folded towards the front handle and the rear handle is limited to be opened away from the front handle, namely a locking function; the second cam surface can be selectively contacted with the lock plunger, external force is applied to drive the finger button to enable the trigger to rotate around the trigger rotating shaft, the second cam surface drives the lock plunger to move, the lock teeth and the saw teeth are separated from each other, and the rear handle is allowed to open away from the front handle, namely the unlocking function.

5. The surgical instrument of claim 4, wherein the button comprises a first button and a second button, the first button and the second button being mounted on two sides of the front handle, respectively; the front handle comprises an elongated chute penetrating through two side surfaces of the front handle, and the first button and the second button can slide in the elongated chute; the elongated chute is oriented substantially parallel to the extension bar.

6. The surgical instrument of claim 5, wherein the elongated chute is disposed on a rear side of the wheel and meets the following requirements: when the left hand or the right hand adopts a finger holding method to operate the handle, the index finger of the operated hand can conveniently stir one button; when the left hand or the right hand adopts the hand holding method to operate the handle, the thumb of the operated hand can conveniently stir one of the buttons.