JPH11188043A - Orthopedic instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To form a desired screw groove and a screw hole easily by providing an axis body with a drilling edge which drills a hole by rotation on its tip, by covering a cylinder to fix with the axis body and by providing a functioning width controller with the tip of the cylinder touching the subject in order to control the functioning width of the drilling edge. SOLUTION: A double cylindrical structured attachment is installed in an orthopedic tap on sale in order to adjust the functioning width of a drilling edge. This attachment comprises the first cylinder 10 and the second cylinder 20 which is narrower than the first cylinder 10. Taking the second cylinder 20 in and out toward the first cylinder 10 can adjust the functioning width of the drilling edge. When forming a female screw in an orthopedic subject such as a bone, a prepared hole is made by a drill at a fixed place and then the tip of orthopedic tap screw 202 is inserted in the prepared hole. Next, the screw 202 is rotated clockwise by holding grip 203 to form a requested-sized female screw in a bone. A screw groove is formed by shaving a bone with the edge corresponding to the rotation of the screw 202.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an orthopedic tool such as an orthopedic tap or a drill used in a surgical operation for a rigid object such as a bone, and more particularly, to an orthopedic tool by a rotating operation. The present invention relates to a technique for adjusting the working width of a piercing blade for piercing a workpiece.

[0002]

2. Description of the Related Art In general, in orthopedic surgery, there is an operation in which an internal thread must be formed in a bone body. For example, when reconstructing a tendon or ligament, it may be necessary to first form a female screw in the bone to fix the artificial or harvested tendon or ligament to the bone. In forming such internal threads in a bone, first, a hole is drilled in the bone using an orthopedic surgical drill, and then an internal thread is formed in the formed hole with an orthopedic tap. It is performed in the process.

FIG. 7 shows a conventional example of this tap for orthopedic surgery. As shown in this figure, a conventional orthopedic tap 2
00 is a shaft body 201, and blade portions 204 provided at the tip of the shaft body 201, which pierce the shaping target object by a rotating operation,.
And a grip portion 203 provided at the base of the shaft body 201.

[0004]

In forming an affected part screw groove using the tap having the above-described structure, in most cases, a desired screw groove is formed on the basis of an eye measurement of a doctor or the like. , Especially where the affected area is difficult to see,
When blood adheres to the tool, it is extremely difficult to accurately form a desired thread groove.

The accuracy of the operation depends on whether or not the screw groove can be formed accurately. In other words, if the formation region of the thread groove extends to a deep portion and the formation area becomes much larger than a desired amount, the excess tissue may be damaged. on the other hand,
If the formed thread groove is much smaller than the desired area, the screw cannot be sufficiently fitted. That is, it is desirable to perform tapping so that the formation area of the screw groove is as close to a desired value as possible.

[0006] The above is a problem in tapping, but also occurs in so-called drilling in which a screw hole is formed in a bone with an orthopedic drill. That is, if the screw hole is too deep, there is a problem that the excess tissue is damaged, and if the formed screw hole is too shallower than the desired depth, the screw cannot be fully fitted.

Accordingly, the present invention has been made in view of the above problems, and has been made to provide an orthopedic tool such as a tap or a drill capable of forming a desired screw groove or screw hole. It is.

[0008]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a shaft having a drilling blade at the tip for punching a shaping object by a rotating operation, and slidably fitted on the shaft. A cylindrical body, and a fixture for fixing the cylindrical body on the shaft body, wherein the cylindrical body has a working width regulating portion that abuts the shaping target object at the tip to regulate the working width of the drilling blade. An orthopedic tool is provided.

Thus, a desired screw groove or screw hole can be formed in tapping or drilling.

[0010] The fixing tool may be constituted by a ratchet groove formed in the shaft and a ratchet claw provided in the cylinder.

Also, a scale is formed along one axis of the shaft body or the cylindrical body along the axial direction, and an indicator for indicating a reading position for the scale is formed on the other side. The working width of the drilling blade can be displayed.

Here, the scale is formed on the shaft, and when the indicating portion is aligned with the shaft end, which is the base end of the tube, the tube base indicates the reference point of the scale. It is also possible to adopt a configuration in which the scale is formed with a size corresponding to the amount of movement of the cylinder in the backward direction.

Further, the working width regulating portion may be an end face formed at the tip of the cylindrical body and substantially perpendicular to the axial direction.

The above object can also be achieved by the following attachment. That is, an attachment used by attaching to the shaft body of an orthopedic tool having a drilling blade at the tip of the shaft body for punching a shaping target object by rotating the shaft body, and being capable of being inserted into and removed from the shaft body. A first cylindrical body to be extrapolated,
A second end which is inserted into and retractable from the first cylindrical body, has an inner diameter slidable on the shaft, and has a cylindrical end for defining the working width of the drilling blade when attaching the attachment to the shaft. Two cylinders, a first fixture that fixes the first cylinder at a predetermined position on the shaft, and a second fixture that fixes the second cylinder to the shaft or the first cylinder, A scale is formed on one of the first and second cylinders along the axial direction, and an indicator for indicating a reading position of the scale is provided on the other, and the first cylinder is attached when the attachment is attached to the shaft. By fixing the body at a predetermined position, the working width of the drilling blade can be adjusted from the value indicated by the indicating section.

[0015] Thus, a desired screw groove or screw hole can be formed in tapping or drilling simply by aligning and attaching the attachment to a commercially available orthopedic tool.

Here, a long window is opened in the axial direction in the first cylindrical body, and a pin projecting into the window is provided in the second cylindrical body,
A configuration in which the amount of retreat of the second cylinder with respect to the first cylinder is defined by the amount of movement of the pin in the window.

Further, the pin can be used in combination as a second fixing member for fixing the second cylindrical body to the shaft.

Further, the scale is formed on the surface of the second cylindrical body, the indicating portion is set at the distal end of the cylindrical body of the first cylindrical body, and the reference point of the scale is set in the state where the second cylindrical body protrudes by the maximum amount. It can also be set to a part that matches the instruction part of the part.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The orthopedic tool of the present invention includes a tap for forming a screw groove in an affected part such as a robust bone and a drill for forming a screw hole. Will be specifically described with reference to the drawings.

[Embodiment 1] FIG. 1 (a) shows a commercially available orthopedic tap fitted with an attachment 1 having a double cylindrical tube structure for adjusting the working width of a drilling blade according to the present invention (covered). FIG. 1B is a front view of the tap when the tap is fitted, and FIG.
Is a sectional view taken along line XX. In addition, since the tap for attaching the attachment 1 is the same as the above-described configuration, the numbers indicating the respective parts are the same as those in the drawing for convenience.

As shown in FIG. 1, the attachment 1 comprises a first cylindrical body 10 and a second cylindrical section 20 having a slightly smaller diameter.

The first cylindrical body 10 is separated from the upper end thereof by the second cylindrical body 2.
The inner diameter is formed so that 0 can be inserted. A guide window 1 running from the base end to the tip end of the body of the first cylindrical body 10.
The second cylindrical body 20 and the first cylindrical body 10 are connected by inserting the position regulating pins 10b into the guide windows 10a with the second cylindrical body 20 inserted therethrough. Thus, in a state in which the guide window 10a is not attached to the tap, the second cylindrical body 20 slides freely by moving back and forth with respect to the first cylindrical body 10 for the length of the guide window 10a.

In order to determine the amount of sliding of the second cylindrical body 20, the position regulating pin 10b is located at the uppermost end of the second cylindrical body 20 where it abuts against the wall surface of the guide window 10a. (FIGS. 1A and 1B), the first cylinder 1
With the position of the upper edge 10c (indicating portion) of 0 as a base point (zero), graduations M1 to be read at the upper edge 10c toward the distal end are formed at predetermined intervals (for example, intervals of 0.2 cm). The distal end portion of the second cylindrical body 20 has a tapered portion 2 having a smaller outer diameter in the distal end direction so as to reduce the resistance generated when the tap is inserted into the body and facilitate the insertion of the tap.
0b is formed.

When the upper edge 10c of the first cylindrical body is aligned with a position where the scale is zero (this position is referred to as a reference position), the upper edge 20 of the second cylindrical body 20 is attached.
The base end of the first cylindrical body 10 is fastened and fixed to the shaft body by the screw 11 so that a is flush with the distal end 202a of the screw portion 202. By attaching the attachment 1 to the tap in this manner, as shown in FIG. 2, the second cylinder 20 is retracted from the reference position by the amount retracted, that is, the upper edge 10 c which is the indicator of the first cylinder 10. The protrusion amount of the screw portion 202 from the upper end of the second cylindrical body can be changed by an amount corresponding to the indicated value (see FIGS. 2 (a) and 2 (b). (A) is a front view when the device is retracted, and (B) is a cross-sectional view taken along line YY.) If the working width of the changed screw portion 202 is increased by increasing the amount of tightening of the position restricting pin 10b, which is a fastener attached to the second cylindrical body 20, the screw comes in contact with the shaft body 201 and is fixed in that state. It is like that. In this specification, the amount of protrusion of the screw portion 202 from the upper end of the second cylindrical body is defined as the “working width” of the blade portion.

The material of the attachment 1 is a material equivalent to that used for the orthopedic tap (stainless steel or a material that can be sterilized (sterilized by EO, γ-ray, electron beam, etc.)). Good. Therefore, it is preferable to use a material that does not hinder the processing of the bone body or a material that can repeatedly withstand the temperature and pressure caused by autoclave sterilization.

Next, the usage of the orthopedic tap 1 having the above-described configuration will be described with reference to FIG. FIG.
FIG. 4 is a diagram showing a state where the orthopedic tap 1 forms a female screw in the bone body B. First, a pilot hole h is drilled at a position where a female screw of a bone body is to be formed. next,
The tip of the screw portion 202 of the orthopedic tap 1 is inserted into the prepared hole h.

When the tip of the screw portion 202 is inserted into the prepared hole h, the screw portion 202 is rotated by rotating the grip portion 203 clockwise to form a female screw in the bone B. The blades 204, 204,... Move spirally by this rotation to cut the bone B to form thread grooves.

The screw groove is formed by such an operation, and when the screw portion 202 is advanced to a depth corresponding to a desired working width of the screw portion 202 set as described above, the rotation of the handle 203 is stopped. The determination as to whether or not the screw portion 202 has reached the desired depth is made based on whether or not the upper end edge 20a of the second cylindrical body 20 provided near the screw portion 202 has reached the entrance of the pilot hole h. This can be known from whether or not the torque for rotating the screw portion 202 has increased since the upper end edge 20a contacts the affected part.

After the above steps, the grip portion 203 is rotated counterclockwise so that the screw portion 202 is detached from the formed internal thread, and the screw portion 202 is detached from the prepared hole h, whereby the bone B The formation of the female screw on the is completed.

As described above, according to the orthopedic tap to which the attachment 1 is mounted, the working width of the screw portion can be set to a desired value. An internal thread can be formed.

[Embodiment 2] In Embodiment 1 described above, a double-cylindrical tubular body is mounted on a shaft having a perforated blade.
The working width of the screw portion is adjusted by sliding one cylindrical tube of the double cylindrical tube. However, the embodiment described below can be cited as one embodiment of the retracting mechanism of the drilling blade.
The orthopedic drill according to the present embodiment is provided with a ratchet mechanism so that the working width of the drilling blade can be adjusted.

FIG. 4 is an assembly view of the orthopedic drill 100 according to the present embodiment.

As shown in this figure, this orthopedic drill 1
00 is located at the tip of the shaft 101,
A plurality of blade portions 104, 104,... Are formed by spirally forming a cutting portion 102, a handle 103 provided at the base of the shaft body 101, and a cylindrical body 110 inserted through the shaft body 101. Further, a ratchet mechanism is provided as a fixing tool for moving the cylindrical body at regular intervals and fixing the cylindrical body to the shaft body.

The cylindrical body 110 has a small cylindrical part 110 having an outer diameter corresponding to a screw head of a screw used for a surgical operation, having a circumferentially formed chasing blade 111 on the end surface.
a, a tapered portion 110b having a gradually decreasing outer diameter in the distal direction is formed on the proximal end thereof, and a large-diameter cylindrical portion 110c having a slightly larger diameter is further formed on the proximal end thereof so that a user can easily grip the tapered portion. . The large-diameter cylindrical portion 110c can be inserted into the body portion 101a of the shaft body, and does not rotate with respect to the shaft body 101 when fitted on the shaft body 101.
The inner peripheral surface of the cylindrical body 110 is machined to a cross-sectional shape similar to the cross-sectional shape of.

FIG. 5 is a sectional view taken along the line ZZ including the waist of the cylindrical body in a state where the cylindrical body in FIG. 4 is mounted, and FIG.
FIG. 5 is a cross-sectional view taken along the line Z′-Z ′ in a state where the tubular body in FIG. 4 is mounted.

As shown in FIG. 6, the ratchet mechanism includes ratchet grooves 120, 120,... Formed at regular intervals in the body 101a of the shaft body 101, and a central portion of the cylindrical body 110 near the base end thereof. It is constituted by a ratchet claw 130 provided to be urged. That is, since the ratchet claw 130 is urged by the spring 131 and attached to the cylinder 110, the ratchet claw 130 is engaged with the ratchet groove 120 in this urged state, and the ratchet claw 130 is moved rearward (in the proximal direction). While restricting the slide, when the engagement between the ratchet claw 130 and the ratchet groove 120 is released, the ratchet slides backward. When the user presses down the pressing plate 132 connected to the ratchet pawl 130, the urging force of the spring 131 is released, and the ratchet pawl 130 is released as shown in FIG.
Is retracted from the ratchet groove 120, whereby the engagement between the ratchet claw 130 and the ratchet groove 120 is easily released. Although the pressing plate 132 in the biased state is projected from the surface of the cylindrical body 110 in FIG. 6, the pressing plate 132 is set in a cylindrical shape so that the user does not press it by mistake during the operation. It may be buried from the surface of the body 110.

The ratchet grooves 120, 120,.
Is formed by providing an inclined surface so as to gradually become shallower from the base end side as shown in FIG. 6, so that the user does not push down the pressing plate 132 to retreat the ratchet claw 130 from the ratchet groove 120. In both cases, the cylinder 110 freely slides forward. This is because, with the forward pressing force applied to the cylindrical body 110, a force is generated by which the side wall forming the ratchet groove 120 pushes up the ratchet claw 130, and the ratchet claw 120 is moved from the ratchet groove 120 by the pushing force. This is because the retraction and the engagement between the ratchet groove 120 and the ratchet claw 130 are released only by the force.

When the upper end edge 112 of the cylindrical body is flush with the front end 102a of the cutting portion, the position of the base end 113 (indicating portion) of the cylindrical body is set to the reference point of the scale. As (zero), the scale M2 is formed with a dimension (for example, 0.2 cm interval) corresponding to the amount of movement of the cylinder 110 in the retreating direction (corresponding to the formation interval of the ratchet groove). Although not attached, the corresponding numerical value is actually attached.)

In this manner, by setting the scale, the working width of the cutting portion (blade portion) can be defined by the value specified by the cylindrical base edge 113.

This orthopedic drill 100 is used to make a pilot hole h in the affected part prior to using the above-mentioned orthopedic tap 1. The mode of use is the same as that of a general mode. Although detailed description is omitted, the cylinder 110
, Is a cylindrical body having overtaking blades 111, 111,...
The drill is buried in the diseased part further than the tip edge of the cylindrical body 110, and the drill hole h is formed due to the resistance felt when the distal circumferential surface of the tapered part 110b comes into contact with the diseased part. Will end. Therefore, the cylindrical portion 110a
A hole with a diameter equivalent to the head of the screw will be opened in the area where the head is buried, and when screwing the screw into the affected part, the head can be buried in the affected part without exposing the head from, for example, the bone surface of the affected part it can.

[Other Matters] Needless to say, the present invention is not limited to the above-described embodiment, and the following modified examples can be considered without departing from the gist of the invention.

(1) Comparing the first embodiment with the second embodiment, it is more convenient for the user to adjust the working width of the blade using the attachment of the first embodiment. That is, if the working width of the blade portion is adjusted by attaching an attachment to a commercially available tap as in Embodiment 1, it is unnecessary to form a ratchet groove or attach a scale to the shaft body. This is because the user can use the tap already used.

(2) Although the second cylinder in the attachment 1 of the first embodiment is fixed to the shaft, it may be fixed to the first cylinder. In this case, the second cylinder is fixed by tightening a screw from the side of the first cylinder and abutting against the second cylinder. Therefore, the position restricting pin does not have a function as a fixing tool for fixing the second cylindrical body to the first cylindrical body, and the fixing tool and the position restricting pin are formed separately.

(3) In the second embodiment, the scale is provided on the shaft and the indicator is provided on the cylinder, but the scale may be provided on the cylinder and the indicator may be provided on the shaft.

(4) Although the ratchet mechanism is provided in the second embodiment, the present invention is not limited to this, and a simpler structure such as screwing and fixing the cylindrical body to the shaft body can be adopted. Is provided, it is possible to reliably maintain the working width set value of the blade portion against the force acting in the proximal direction at the time of work.

(5) The attachment 1 mounted in the first embodiment for adjusting the working width of the blade portion is:
The present invention can be applied not only to an orthopedic tap but also to an orthopedic drill, and the ratchet mechanism in the second embodiment can be similarly applied to a tap.

[0047]

As described above, the orthopedic tool according to the present invention has a shaft body having a drilling blade at its tip for drilling a shaping object by a rotating operation, and is slidably fitted on the shaft body. And a fixing tool for fixing the cylinder on the shaft, wherein the cylinder has a working width regulating portion at its tip which abuts on the shaping target object to define the working width of the drilling blade. It is characterized by.

Thus, a desired screw groove or screw hole can be formed in tapping or drilling.

[Brief description of the drawings]

FIG. 1A is a front view of a tap when an attachment 1 having a double cylindrical tube structure according to one embodiment is mounted on a commercially available tap. (B) is a sectional view taken along line XX in (a).

FIG. 2A is another front view of the tap when the attachment 1 having a double cylindrical tube structure according to one embodiment is mounted on a commercially available tap. FIG. 2B is a sectional view taken along line YY in FIG.

FIG. 3 is a schematic view for explaining a usage mode of the above-mentioned orthopedic tap.

FIG. 4 is an assembled view of an orthopedic tap according to another embodiment.

FIG. 5 is a sectional view taken along the line ZZ of the orthopedic tap after assembly.

FIG. 6 is a sectional view taken along the line Z′-Z ′ after the assembly of the orthopedic tap.

FIG. 7 is a front view showing a conventional orthopedic tap.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Attachment 10 1st cylinder 10a Guide window 10b Position control pin 10c Upper edge 20 Second cylinder 20a Upper edge 100 Orthopedic drill 101 Shaft 101a Trunk 102 Cutting part 102a Tip 103 Pattern 104 Blade part 110 Cylindrical body 110a Small cylindrical portion 110b Tapered portion 110c Large diameter cylindrical portion 111 Tracking blade 112 Upper edge of cylindrical body 113 Base edge of cylindrical body 120 Ratchet groove 130 Ratchet claw 131 Spring 132 Pressing plate

Claims (10)

[Claims] 1. A shaft having a drilling blade at its tip for punching an object to be shaped by a rotation operation, a cylinder slidably fitted on the shaft, and fixing the cylinder on the shaft. An orthopedic tool, characterized in that the cylindrical body has a working width restricting portion at its tip which comes into contact with the object to be shaped and regulates the working width of the drilling blade. 2. The orthopedic tool according to claim 1, wherein the fixing tool is a ratchet groove formed in the shaft and a ratchet claw provided in the cylindrical body. 3. A scale according to claim 2, wherein a scale is formed on one peripheral surface of the shaft body or the cylindrical body along the axial direction, and an indication unit for designating a reading position for the scale is formed on the other peripheral surface, The orthopedic tool according to claim 2, wherein the indicated value indicated by the indicating unit indicates the working width of the drilling blade. 4. A scale is formed on the shaft, the indicating portion is a base end of the cylinder, and when the front end of the cylinder is aligned with the front end of the shaft, the base end of the cylinder indicates a reference point of the scale. 4. The orthopedic tool according to claim 3, wherein the scale is formed with a dimension corresponding to the amount of movement of the cylinder in the retreating direction. 5. The orthopedic tool according to claim 1, wherein the working width regulating portion of the drilling blade is an end face formed at a tip end of the cylindrical body and substantially perpendicular to an axial direction. . 6. The cylindrical body according to claim 1, wherein a tip of the cylindrical body has a chasing blade for forming a hole having a diameter corresponding to a head of a screw to be used. The orthopedic tool as described. 7. An attachment which is used by attaching a drilling blade for drilling a shaping object to a shaping target object by a rotating operation of the shaft body at the shaft body of an orthopedic tool having an end of the shaft body. A first cylindrical body which is externally inserted and removed so as to be freely inserted and removed, and which has an inner diameter which can be inserted into and retracted from the first cylindrical body and which is slidable on the shaft, and which has a boring blade when the attachment is attached to the shaft. A second cylindrical body having a cylindrical body tip defining the working width of the first cylindrical member, a first fixing member for fixing the first cylindrical body at a predetermined position on the shaft, and a shaft or a first cylindrical body for the second cylindrical body A scale is formed along one of the first and second cylindrical bodies along the axial direction, and an indicator indicating a reading position of the scale is provided on the other of the first and second cylindrical bodies. By fixing the first cylinder at a predetermined position when attaching the attachment to the shaft, Attachment orthopedic tool, characterized in that to adjust the working width of the cutting head from the value indicated. 8. A window which is long in the axial direction in the first cylindrical body, and a pin is provided in the second cylindrical body so as to protrude into the window. 8. The attachment of an orthopedic tool according to claim 7, wherein is defined by the amount of movement of the pin in the window. 9. The orthopedic tool attachment according to claim 8, wherein the pin is a second fixing tool for fixing the second cylinder to the shaft. 10. The scale is formed on the surface of the second cylindrical body, the indicator is a tip end of the cylindrical body of the first cylindrical body, and the reference point of the scale is set to the maximum when the second cylindrical body is protruded by the maximum amount. The orthopedic tool attachment according to claim 9, wherein the attachment is set at a position corresponding to the indication portion of the one cylinder portion.