KR20140103680A - biopsy apparatus - Google Patents

Abstract

The present invention relates to a biopsy apparatus including a probe assembly (170) that is provided with a probe (170a) which moves forward to collect human tissues; and a cutter cannula assembly (180) that is provided with a cutter cannula (180a) which cuts and collects human tissues while rotating and moving forward from an outer circumferential edge of the probe (170a) with the probe (170a) of the probe assembly (170) inserted inside. According to the present invention, human tissue samples can be collected through rotation, and thus the sample tissue collection amount can be maximized. Also, a pain caused by the collection can be minimized while the sample tissues can be collected smoothly and accurately.

Description

{Biopsy apparatus}

The present invention relates to a bi-observing apparatus, and more particularly, to a bi-observing apparatus capable of collecting tissue samples easily and safely, but minimizing pain and obtaining a maximum amount of tissue samples.

A biopsy may be done to the patient to help determine if the cell at the site where the biopsy (biopsy or biopsy) is performed is cancerous.

One type of vacuum assisted bi-ops device includes a hand-held driver assembly having a vacuum source and a disposable bi-ops probe assembly configured to be detachably attachable to the driver assembly .

Exemplary biopsy techniques used to examine breast tissue include, for example, inserting a biopsy probe into the site to collect one or more tissue samples from a breast tissue region of interest .

A bi-ops probe typically includes a biopsy cannula with a cylindrical side wall defining a lumen and a side sample notch disposed proximate the distal end extending through the sidewall to the lumen, For example, a needle.

A cutting cannula is positioned coaxially with the bi-optic cannula to selectively open and close the sample notch.

Vacuum is applied to the lumen and thus the sample notch to accommodate the tissue being sampled when the sample notch is open, and then the sample notch is closed by the cutting cannula to cut the tissue, And collected from the lumen.

Such a conventional biaxis is also disclosed in Patent Publication No. 2012-100957.

However, this biaxial not only causes pain to a great extent because it pressurizes in a straight line and cuts a tissue sample, but also has a problem in that cutting amount of the tissue due to pressurization is reduced and cutting of tissue is not smooth.

Accordingly, the main object of the present invention is to provide a bi-optic device capable of obtaining a maximum amount of sample tissue by rotating the tissue sample of the human body while rotating the sample, and minimizing the pain caused by the sampling and obtaining smooth and accurate sample tissue .

In order to attain the above object, the present invention provides a bi-optic device comprising: a probe assembly having a probe which advances forward and holds a human tissue; and a probe, which is inserted into the probe assembly, And a cutter cannula assembly having a cutter cannula for cutting and picking up a human body tissue.

Therefore, the biopsy device of the present invention allows the probe to be advanced forward at the tissue sampling position of the human body, naturally allowing the human tissue to be collected into the space of the sample notch formed in the sample basket to flow naturally, and rotating the cutter cannula forward So that a maximum amount of sample tissue can be obtained while at the same time minimizing the pain caused by the sampling and obtaining a sample tissue smoothly and accurately.

1 is a perspective view of a bi-vision device according to the present invention;
2 is a side view of a bi-view device according to the present invention;
FIG. 3 is a perspective view of a bi-view device according to the present invention in exploded view; FIG.
4 is a perspective view showing a slide frame and a cutter cannula of a bi-view device according to the present invention.
5 is a partially enlarged view showing a state before and after locking the bi-observing device according to the present invention.
6 is a cross-sectional view showing an initial state of the bi-observing apparatus according to the present invention.
7 is a cross-sectional view showing a probe advancing state of the bi-optic device according to the present invention.
8 is a sectional view showing a cutter cannula in a forward state of the bi-opsystem according to the present invention.
FIG. 9 is a cross-sectional view showing a state in which a biopsy device according to the present invention is collected.
10 is a cross-sectional view showing a state in which a biopsy device according to the present invention is removed.
11 is a cross-sectional view showing an initial state of the bi-opsystem according to the present invention when the lever is adjusted.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 11, the bi-vision device 100 of the present invention includes a housing 110 formed in a pair of left and right sides, and an operation hole 121 coupled to a front end of the housing 110, A control assembly 140 installed on the upper and lower sides of the housing 110 and a control assembly 140 installed on the outer periphery of the housing 110. [ A slide frame 160 which is inserted into the housing 110 to move back and forth and a slide frame 160 which is elastically provided at the rear of the slide frame 160 to move back and forth, And a cutter cannula assembly 180 having a cutter cannula 180a for allowing the probe 170a to pass therethrough so as to move forward and backward while being elastically installed inside the slide frame 160. The cutter cannula assembly 180 ) And the rear end of the cutter cannula assembly 180 And a rotary member 190 for rotating the cutter cannula assembly 180 when the cutter cannula assembly 180 moves back and forth.

The housing 110 is formed in a cylindrical shape, and is separated into a pair of right and left, and guide pieces 113 are formed on the upper and lower sides to create a space under the upper portion.

Therefore, the control chamber 140 is formed by providing the operation chamber 117 at the center of the housing 110 to allow the slide frame 160 to be inserted therein, and the slide grooves 114 are formed at the upper and lower sides thereof, A locking hole 115 is formed in the rear side of the slide groove 114 and the front side of the lower side slide groove 114 to communicate the operation chamber 117 and the slide groove 114 with each other.

A screw 118 is formed on the outer periphery of the front side of the housing 110, and a guide piece 119 is formed on the rear portion of the housing 110.

A supporting protrusion 116 for axially coupling the lever 150 is downwardly protruded on the lower portion of the housing 110 and a first guide slot 111 and a lever 150 A second guide slot 112 for interrupting the sliding movement of the slide frame 160 is formed continuously in the longitudinal direction and an engaging groove 111a is formed upwardly at the front end of the first guide slot 111 to selectively slide the slide frame 160 .

The cap 120 is screwed to the front end of the housing 110 by forming a screw 122 on the inner peripheral edge and an operation hole 121 is formed at the center to penetrate the probe 170a and the cutter cannula 180a Move forward or backward.

The fixture 130 includes a fixing ring 131 and is fitted to the outer periphery of the guide piece 113 of the housing 110 so that the support plate 132 can be positioned at the rear end of the guide piece 113, do.

Here, holes 133 corresponding to the upper and lower slide grooves 114 of the housing 110 are drilled in the support plate 132, and the inner surface central protrusion 134 is projected forward.

The control assembly 140 attaches the locker 144 to the locking hole 115 of the upper and lower slide grooves 114 with the pin 145 and simultaneously fixes the locker 144 to the spring 146.

In addition, the operation bar 143 corresponding to the locker 144 is inserted into the upper and lower slide grooves 114, and the connecting hole 142 is formed at the rear end of the operation bar 143, And a push button 141 is coupled to the outer side of the connector 142 which is passed through.

The lever 150 is engaged with the lower portion of the housing 110 from the upper portion of the housing 110 to be coupled with the supporting protrusion 116 by the rotation shaft 151 so as to swing and form a guide slot 152 for connecting the slide frame 160, So that the frame 160 can be pulled backward.

The slide frame 160 includes a cutter cannula assembly 180 which forms an insertion hole 161 in front and behind and is placed inside the slide frame 160 and a cutter cannula 180a of the probe assembly 170 and a probe 170a Respectively, and slide long holes 162 are formed on the right and left sides.

The engaging pins 163 protrude from the left and right rear sides of the slide frame 160 to be engaged with the guide elongated holes 152 of the lever 150 through the second guide elongated holes 112 of the housing 110, 150 to move the slide frame 160 backward.

The probe assembly 170 includes a probe 170a formed as a bar to sharpen the tip portion and to form a sample basket 174 immediately behind the tip portion and to guide the sample tissue to the upper side of the sample basket 174, (175).

A support block 171 is coupled to a rear end of the probe 170a and a support 172 is protruded rearward from the back surface of the support block 171. A compression spring 173 is inserted into the support 172, 170a can be selectively and resiliently mounted.

Here, the rear end of the compression spring 173 is fitted to the projection 134 of the control assembly 140.

The cutter cannula assembly 180 is formed in a tubular shape so that the probe 170a can penetrate the inside of the cutter cannula assembly 180. The cutter cannula assembly 180 is installed on the inner side of the slide frame 160, So as to be movable back and forth.

Further, a rotation hole 183 is coupled to the rear end of the cutter cannula 180a, and the rotation hole 183 is coupled to the through hole 182 of the support block 181 to idle, The support block 181 is interlocked.

The protruding pin 184 is coupled to the left and right of the support block 181 to penetrate the first guide slot 111 of the housing 110 and to couple the compression spring 185 to the back of the support block 181 .

In addition, it is preferable that a saw tooth-shaped cutting edge 186 is formed at the tip of the cutter cannula 180a so as to multiply the cutting force according to the rotation.

The rotation assembly 190 is configured to engage the front end of the threaded rod 191 with the rotation hole 183 of the cutter cannula assembly 180 so that the compression spring 185 is positioned in the inner diameter of the rotation assembly 190 and the threaded rod 191 The rear end is passed through the through hole 193 of the guide hole 192 and the rear end is coupled with the fixing washer 196 so as not to escape.

A guide pin 193 is projected from the peripheral edge of the through hole 193 of the guide hole 192 so that the threaded bar of the threaded rod 191 is fitted into the threaded rod 191. The threaded rod 191 is provided with a hole Are formed in the longitudinal direction.

Further, the guide pin 192 is provided with a fixing pin 195 protruding laterally from the left and right of the slide frame 160 to prevent it from rotating in the slide slot 162 and to move only forward and backward.

Therefore, when the threaded rod 191 passing through the guide hole 192 moves forward or rearward, the threaded rod 191 rotates forward or backward. As a result, when the cutter cannula assembly 180 rotates in conjunction with the threaded rod 191, do.

The operation of the present invention will be described as follows.

The probe 170 of the biopsy device 100 and the cutter cannula assembly 180 are retracted so that the compression springs 173 and 185 are compressed and the probe 170a and the cutter cannula The operation bar 143 rotates the locker 144 to release the engagement state of the probe assembly 170 so that the probe spring 170 is rotated by the compression spring 173, 170a advance forward and protrude forward from the front end of the cutter cannula 180a.

At this time, the tissue to be sampled naturally flows into the space of the sample notch 175 formed in the sample basket 174 of the probe 170a projecting forward.

In this state, when the next lower push button 141 is pressed, the operation bar 143 rotates the locker 144 to release the hooking state of the cutter cannula assembly 180, so that the cutter cannula 180a is pressed by the compression spring 185, So as to cut the human tissue introduced into the space of the sample notch 175 of the probe 170a while covering the outside and safely sample the human tissue to the sample notch 175. [

At this time, since the threaded bar 191 of the most important rotary assembly 190 of the present invention advances while being rotated by the guide pin 194 of the guide hole 192 maintaining the fixed state, the cutter cannula 180a also rotates, So that the sawtooth-shaped cutting edge 186 smoothly and safely collects the human tissue.

After sampling the human tissue as described above, when the bar-vision device 100 is separated from the human body and the projecting pin 184 of the cutter cannula assembly 180 is pulled backward, the sample notch 175 of the probe 170a The exposed human tissue is exposed and extracted to perform various tests.

On the other hand, when the human tissue is sampled again, the lever 150 is pulled back to the initial state so that the human tissue can be collected as described above.

The projecting pin 184 of the cutter cannula assembly 180 is positioned in the engaging groove 111a of the first guide slot 111 and the lever 150 is pulled out of the slide frame 162 when the projecting pin 184 is engaged. .

The support block 171 of the probe assembly 170 and the support block 181 of the cutter cannula assembly 180 are retracted while compressing the compression springs 173 and 185 so that the support blocks 171, So that the locker 144 is held in the initial state.

The protruding pin 184 of the cutter cannula assembly 180 is positioned in the engaging groove 111a of the first guide slot 111 so that the engaging groove is maintained and the threaded bar 191 passes through the guide hole 192 The threaded rod 191 is guided by the guide pin 194 and is rotated so that the rotating rod 191 is advanced while rotating forward so that the cutter cannula 180a is also advanced while rotating to collect the tissue Sampling.

100: bi-ops device 110: housing
111: first guide elongated hole 111a:
112: second guide elongated member 113: guide member
114: Slide groove 115: Locking hole
116: support protrusion 117: working chamber
118: screw 119: guide piece
120: Cap 121: Operator ball
122: screw 130: fastener
131: stationary ring 132: support plate
133: hole 134: projection
140: control assembly 141: push button
142: End connection 143: Operation bar
144: Rocker 145: Pin
146: spring 150: lever
151: rotation shaft 152: guide slot
160: slide frame 161: insertion hole
162: slide slot 164:
170: probe assembly 171a: probe
171: Support block 172:
173: Compression spring 174: Sample basket
175: sample notch 180: cutter cannula assembly
180a: cutter cannula 181: support block
182: Through hole 183:
184: projecting pin 185: compression spring
186: cutting edge 190: rotating member
191: Nasabong 192: Guide Area
193: Through hole 194: Guide pin
195: fixing pin 196; Fixing Washer

Claims (9)

A bi-observing apparatus for sampling a human tissue,
A probe assembly 170 having a probe 170a which advances forward to hold a human tissue,
A cutter cannula assembly 180 having a cutter cannula 180a for cutting and picking up a human body by rotating the probe 170a of the probe assembly 170 while rotating the outer circumference of the advancing probe 170a, Wherein the first and second biaxial devices are arranged in a matrix.
The method according to claim 1,
And a housing (100) for receiving the probe assembly (170) and the cutter cannula assembly (180)
A cap 120 coupled to a front end of the housing 110 to form an operation hole 121 at the center,
A fastener 130 coupled to a rear end of the housing 110,
A control assembly 140 installed on upper and lower sides of the housing 110,
A lever 150 coupled to the outer periphery of the housing 110,
A slide frame 160 inserted into the housing 110 and moving back and forth,
A probe assembly 170 for elastically supporting the slide frame 160 to move back and forth,
A cutter cannula assembly 180 for allowing the probe 170a to pass through the slide frame 160 by moving the slide frame 160 in a forward and rearward direction,
And a rotary member (190) coupled to a rear end of the cutter cannula assembly (180) to rotate when the cutter cannula assembly (180) moves back and forth.
3. The method of claim 2,
The housing 110 has an operation chamber 117 formed at the center thereof to allow insertion of the slide frame 160 and slide grooves 114 are formed on the upper and lower sides of the housing 110 to install the control assembly 140, A locking hole 115 is formed in the rear side of the upper side slide groove 114 and the lower side side slide groove 114 to communicate the operation chamber 117 with the slide groove 114, A first guide elongated hole 111 for interrupting the slide frame 160 and a second guide elongated hole 112 for interrupting the lever 150 are provided on the side surface of the support frame 110 in the longitudinal direction And a latching groove (111a) is formed upward in a front end of the first guide slot (111).
The method according to claim 2 or 3,
The fixture 130 includes a fixing ring 131 and is fitted to the outer periphery of the guide piece 113 of the housing 110 so that the support plate 132 is positioned at the rear end of the guide piece 113,
The control assembly 140 is provided with the locker 144 by a resilient force of the spring 146 on the locking hole 115 of the upper and lower slide grooves 114, And a push button 141 is coupled to the rear end of the operation bar 143,
Wherein the lever (150) is formed to have a guide slot (152) for engaging with the support protrusion (116) from the upper side to the lower side of the housing (110) and connecting the slide frame (160).
The method according to claim 2 or 3,
The slide frame 160 has insertion holes 161 formed in the front and back sides thereof and slide slots 162 formed on the left and right sides thereof and locking pins 163 projected on the rear left and right sides thereof to form the second guide slots 112 of the housing 110 (150) of the lever (150) through the guide slot (152) of the lever (150).
3. The method according to claim 1 or 2,
The probe assembly 170 includes a probe 170a formed as a rod and a sample basket 174 formed on the rear end of the probe 170a to form a sample notch 175 for guiding sample tissue on the sample basket 174 A support block 171 is coupled to the rear end of the probe 170 and a support 172 is protruded rearward from the back surface of the support block 171 and a compression spring 173 is fitted to the support 172 .
3. The method according to claim 1 or 2,
The cutter cannula assembly 180 includes a cutter cannula 180a formed in a tubular shape so as to penetrate the probe 170a into the cutter cannula assembly 180 and is installed on the inner side of the slide frame 160, And the projecting pin 184 is coupled to the left and right of the support block 181 so that the rotation pin 183 is engaged with the through hole 182 of the support block 181, And the compression spring (185) is coupled to the rear of the support block (181) so as to pass through the first guide slot (111) of the housing (110).
3. The method according to claim 1 or 2,
Wherein a sawtooth cutting edge (186) is formed at the tip of the cutter cannula (180a) of the cutter cannula assembly (180) to multiply the cutting force according to rotation.
8. The method of claim 7,
The rotary assembly 190 is configured such that the front end of the threaded rod 191 is coupled to the rotary shaft 183 of the cutter cannula assembly 180 and the rear end of the threaded rod 191 is inserted into the through hole 193 of the guide hole 192 A guide pin 193 is protruded from the periphery of the through hole 193 of the guide hole 192 so that the threaded hole of the threaded rod 191 is fitted into the threaded hole 191, And a fixing pin (195) protrudes from the left and right sides of the guide hole (192).

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