KR100967358B1 - Radioisotope solution dispenser and method of dispensing - Google Patents

Abstract

The disclosed radioisotope solution ejector includes a drive unit for distributing a radioisotope solution in a cylinder of the syringe by pushing a piston of the syringe by a control unit, wherein the drive unit has a seating groove and a head of the cylinder to seat the cylinder of the syringe on an upper surface thereof. A frame portion having a front frame having an insertion groove, a rear frame having a through hole, and a plurality of guide rails connecting the front frame and the rear frame to be inserted therein, and coupled to one side of the piston on an upper surface thereof. A body having a groove and a fixing bar rotatably coupled to the coupling groove to fix the piston, and are inserted through the fastener and the through hole disposed on the guide rail, and receives the fastener to receive the driving force of the motor. It may include a screw for linear movement on the guide rails There. According to the radioisotope solution ejector as described above, breakage of the syringe can be prevented when the syringe is coupled to the radioisotope solution ejector.

Radioisotopes, ejectors, distribution

Description

Radioisotope solution dispenser and method of dispensing

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radioisotope solution ejector and a method of ejecting the same, and more particularly, to a radioisotope solution ejector and a method of ejecting the radioisotope solution for precisely distributing various radioisotope solutions used for medical purposes and the like.

Radioactive isotopes began to be used in medicine around 1961, and they began to spread after 1965. It is currently used in all clinical departments such as internal medicine, surgery, and pediatrics, and is growing into an independent division of nuclear medicine.

The diagnostic method by nuclear medicine is an in vitro imaging test that injects a radiotracer in accordance with a desired purpose into the body to image its distribution, and an in vitro specimen test for testing serum components to be measured from the collected blood using radioisotopes. Radioactive isotopes can be used to treat thyroid cancer or bone metastasis.

The radioisotope solution used for such nuclear medical diagnostics or treatment is distributed to the container by an ejector.

Dispensing to the container is via a syringe coupled to the ejector, the syringe coupling to the ejector being forced-fit by a coupling device.

Therefore, when the syringe is coupled to the ejector by the coupling device, the syringe may be broken by the force of the coupling device acting on the syringe.

In addition, since the syringe is forcibly coupled to the ejector, there is a problem that a portion of the syringe contacting the ejector may be damaged.

If the syringe is broken as described above, the environment is contaminated with radioactivity by the radioisotope solution, which can be fatal to humans exposed to it.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide an improved radioisotope solution ejector capable of preventing breakage of the syringe when the syringe is coupled to the radioisotope solution ejector.

The radioisotope solution ejector according to the present invention may include a control unit and a driving unit for distributing the radioisotope solution in the cylinder of the syringe by pushing the piston of the syringe by the control unit.

The control unit may have a built-in control program for controlling the driving unit, and may be provided with a touch screen that allows the user to operate the control program from the outside.

The drive unit has a front frame having a seating groove so that the cylinder of the syringe is seated on the upper surface, a rear frame having a through hole and a plurality of guide rails connecting the front frame and the rear frame; A body having a coupling groove to be coupled to one side end of the piston and a fixing bar rotatably coupled to the coupling groove to fix the piston, and are inserted through the fastener and the through hole disposed on the guide rail, Receiving a driving force of the motor may include a screw for linearly moving the fastener on the guide rail.

An insertion groove may be formed in the seating groove so that the head of the cylinder is fitted.

The motor may be shielded by lead.

The diameter of the seating groove may be within 5 ~ 50mm.

The control unit may determine the round trip distance and the round trip frequency of the fastener according to the size of the syringe input in advance when the user inputs the dispense / fill amount and the number of dispense of the radioisotope solution through the touch screen.

The control unit may be further provided with a dispensing / filling button of the origin switch of the screw and the radioisotope solution.

The control unit may control the driving unit to discharge the radioisotope solution in the cylinder at 0.05-5 ml / min per 0.1-50,000 μl.

The control unit is provided with an emergency button, the emergency button can be operated by either automatic or manual method if the number of distribution of the radioisotope solution is greater than the number of receiving containers of the radioisotope solution.

Dispensing of the radioisotope solution may resume once the emergency button is released.

The method for discharging the radioisotope solution may include mounting a syringe on a driving unit, setting a screw of the driving unit to an origin point, inputting a single dispensing amount from the syringe to the controller, and counting the number of dispensing from the syringe. Inputting to a control unit; filling the syringe with a radioisotope solution; and operating the screw to dispense the radioisotope solution within the syringe.

The single dose amount may be determined by the moving distance of the screw according to the capacity of the syringe.

The moving distance of the screw according to the single dispensing amount may be (single dispensing amount) / (dispensing amount / pitch of the syringe) X (moving distance mm / pitch).

According to the radioisotope solution ejector of the present invention and a method for discharging the same, a recess is formed in the front body of the driving unit to seat the cylinder of the syringe, and the insertion groove is fitted so that the head of the syringe cylinder is fitted in the mounting groove. By forming a to prevent the breakage of the syringe when the syringe is coupled to the radioisotope solution ejector.

In addition, since the drive of the drive unit can be controlled by the control program, the piston can precisely discharge the radioisotope solution in the body of the syringe.

Hereinafter, a radioisotope solution ejector according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a plan view showing a radioisotope solution ejector according to an embodiment of the present invention.

FIG. 2 is a side sectional view of the radioisotope solution ejector of FIG. 1. FIG.

1 and 2, the radioisotope solution ejector 10 may include a controller 200 and a driver 100.

The control unit 200 is for controlling the driving of the driving unit 100, a control program is built in, and the control program may be operated by a touch screen 210 that can be operated by a user from the outside. have.

The control unit 200 determines a straight forward distance of the driving unit 100 according to the dimensions of the syringe 300 input in advance when the user inputs the dose of the radioisotope solution through the touch screen 210. Radioactive isotope solutions can be automatically dispensed.

For example, if the syringe 300 is a dimension capable of accommodating 5000 μl of the radioisotope solution, and the distribution amount to the receiving container (not shown) is 50 μl, the control unit 200 calculates the straight forward distance of the driving unit 100. Only 50 μl of the radioisotope solution in 5000 μl of the radioisotope solution in the syringe 300 can be automatically dispensed into the receiving vessel.

The control unit 200 may be provided with an emergency button 220.

The emergency button 220 may be operated by either automatic or manual if the number of distribution of the radioisotope solution is greater than the number of containers of the radioisotope solution.

When the emergency button 220 is released, the driving unit 100 is operated by the control unit 200 again, and the distribution of the radioisotope solution may proceed again.

The control unit 200 may be further provided with a home switch 230 and the dispense / charge button 240 of the radioisotope solution.

The home switch 230 is a switch to return the screw 130 to be described later to the initial state, the dispensing / filling button 240 is a radioactive isotope filled or filled with a radioisotope solution in the syringe 300 A switch for dispensing a solution.

On the other hand, the control unit 200, unlike the drive unit 100 is provided in a place that is not exposed to the radioisotope, this is to prevent damage or malfunction of the control unit 200 by the radioactive material.

The driving unit 100 is accommodated in the cylinder 310 of the syringe 300 by pushing the piston 320 of the syringe 300 coupled to the driving unit 100 under the control of the control unit 200. The radioisotope solution can be dispensed externally.

Distribution of the radioisotope solution by the driving unit 100 may be made by the control unit 200 at a rate of 0.05-5 ml / min per 0.1-50.000 μl.

The driving unit 100 may include a frame 110, a motor 140, a screw 130, and a fastener 120.

The frame unit 110 may include a front frame 111, an intermediate frame 112, a rear frame 113, and a mounting frame 115.

3 is a perspective view schematically showing the front frame of the radioisotope solution ejector of FIG.

Referring to FIG. 3, the front frame 111 is a place where the cylinder 310 of the syringe 300 is seated, and a seating groove 111a may be formed on the upper surface thereof so that the outer circumferential surface of the cylinder 310 is seated. have.

Since the seating groove 111a is in the form of the cylinder 310, that is, the cylinder 310 generally has a cylindrical shape, the seating groove 111a may have a semicircular shape to stably seat the cylinder 310.

Since the diameter of the cylindrical cylinder 310 is generally within 5 ~ 50mm, the diameter of the seating groove 111a may also be within 5 ~ 50mm.

The insertion groove 111b may be formed in the seating groove 111a so that the cylinder 310 may be fixed to the front frame 110 by inserting and fitting the head 311 of the cylinder 310. have.

The rear frame 113 may be disposed to be spaced apart from the front frame 111 by a predetermined interval, and may have a through hole in a central portion thereof.

The intermediate frame 112 may be interposed between the front frame 111 and the rear frame 113 and may have an open top.

In the intermediate frame 112, a plurality of guide rails 114 may be installed, one side of which is coupled to the front frame 111 and the other side of which is coupled to the rear frame 113.

If the intermediate frame 112 is removed, the plurality of guide rails 114 may be installed to connect the front frame 111 and the rear frame 113.

The mounting frame 115 may be installed to cover one surface of the front frame 111 or one surface of the intermediate frame 112 or one side of the front frame 111 and one side of the intermediate frame 112.

The mounting frame 115 may allow the radioisotope solution ejector 10 to be fixed to another device.

The fastener 120 may be movably coupled to the plurality of guide rails 114.

The fastener 120 may include a body 121 and a fixing bar 122.

The body 121 may be coupled to the plurality of guide rails 114, and a piston groove (not shown) may be formed on the upper surface of the body 121 to seat the piston 320 of the syringe 300.

A rotating shaft 123 may be installed in the piston groove.

4A and 4B are views illustrating the operation of the fixing bar in the radioisotope solution ejector of FIG. 1.

4A and 4B, the fixing bar 122 is for fixing the piston 320 seated in the piston groove, and may be rotatably coupled to the rotation shaft 123.

Rotation of the fixed bar 122 may be made manually or automatically under the direction of the control unit 200, and in a normal state while being perpendicular to the rotating shaft 123 in the normal direction when fixing the piston 320 The piston may be rotated to apply pressure to the piston 320.

The screw 130 is connected to the motor 140 driven by the control unit 200, it may be rotated by receiving the driving force of the motor 140.

The screw 130 is inserted through the through-hole of the rear frame 113 and coupled with the fastener 120, the fastener 120 is rotated by the screw 130, the plurality of guide rails 114 Allow linear motion on.

The fastener 120 is advanced by the rotation of the screw 130 to distribute the radioisotope solution in the cylinder 310. The single dose of the radioisotope solution is moved by the screw 130. Can be determined by distance.

The motor 140 may be shielded with lead 150 to protect it from radiation.

Reference numeral 160 is a motor housing.

In the above structure, when the syringe 300 is coupled to the radioisotope solution ejector 10 in order to distribute the radioisotope solution to an external receiving container, breakage of the syringe 300 may be prevented.

That is, in the radioisotope solution ejector 10 according to the present invention, the cylinder 310 of the syringe 300 is seated in the seating recess 111a formed in the front frame 111 and formed in the seating recess 111a. The head 311 of the cylinder 310 can be fitted into the insertion groove 111b.

Therefore, it is possible to prevent radioactive exposure due to external exposure of the radioactive isotope solution due to breakage of the syringe and breakage of the syringe caused by forcibly fitting the syringe to the conventional radioisotope solution ejector.

On the other hand, the user can control the amount, speed, frequency, etc. of the radioisotope solution by setting a control program from the outside through the touch screen 210 can provide a precise dispensing function.

Figure 5 is a flow chart sequentially showing the discharge method by the radioisotope solution ejector according to an embodiment of the present invention.

Referring to FIG. 5, in the method of discharging a radioisotope solution, a syringe is first mounted on the driving unit (S1), a volume of the syringe is selected on the touch screen, and a screw is disposed at an origin position (S2).

Next, the single dose of the radioisotope solution to be dispensed from the syringe is input to the controller (S3), and the number of dispenses is input to the controller (S4).

The input of the one-time dispense amount and the number of dispense times may be made by manipulation of the touch screen.

Next, the radioisotope solution is filled in the syringe (S5), and the radioactive isotope solution in the syringe is dispensed by operating the screw (S6).

In this case, the single dose of the radioisotope solution may be determined by the moving distance of the screw according to the volume of the syringe, and the moving distance of the screw according to the single dose may be determined by the following equation. have.

Travel distance of screw = (dispense volume once) / (dispensing volume of syringe / pitch) X (travel distance mm / pitch)

1 is a plan view showing a radioisotope solution ejector according to an embodiment of the present invention.

FIG. 2 is a side cross-sectional view of the radioisotope solution ejector of FIG. 1. FIG.

Figure 3 is a perspective view of the front frame of the radioisotope solution ejector of Figure 1;

4a and 4b is an operation diagram showing the operation of the fixing bar of the radioisotope solution ejector of FIG.

Figure 5 is a flow chart sequentially showing a radioactive isotope solution discharge method by a radioisotope solution ejector according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10 ... radioisotope solution dispenser 100 ... drive section

110 ... frame section 111 ... front frame

113 ... rear frame 114 ... guide rail

120 Fasteners 121 Body

122 ... fixing bar 130 ... screw

140 ... motor 150 ... lead

200 ... control unit 300 ... syringe

310 ... Cylinder 320 ... Piston

Claims (14)

Control unit; And A driving unit which pushes the piston of the syringe by the control unit to distribute the radioisotope solution in the cylinder of the syringe, The control unit has a built-in control program for controlling the drive unit, the touch screen is provided with a user can operate the control program from the outside, The drive unit: A frame portion having a front frame having a seating groove on the upper surface thereof, a rear frame having a through hole, and a plurality of guide rails connecting the front frame and the rear frame; A fastener disposed on the guide rail, the body having a body having a coupling groove so as to be coupled to one side end of the piston, and a fixing bar rotatably coupled to the coupling groove to fix the piston; And And a screw inserted into the through hole and receiving a driving force of a motor to linearly move the fastener on the guide rails. delete delete The method according to claim 1, The seating groove is a radioisotope solution ejector, characterized in that the insertion groove is formed so that the head of the cylinder is fitted. The method according to claim 1, And the motor is shielded by lead. The method according to claim 1, The diameter of the seating groove is a radioisotope solution ejector, characterized in that within 5 ~ 50mm. The method according to claim 1, The control unit may determine the reciprocating distance and the number of round trips of the fastener according to the dimensions of the syringe input in advance when the user inputs the amount of distribution / filling of the radioisotope solution through the touch screen. Isotope solution ejector. The method according to claim 1, The control unit is a radioisotope solution ejector characterized in that the control unit is further provided with a dispensing / filling button of the radioactive solution and the origin switch of the screw. The method according to claim 1, The control unit is a radioisotope solution ejector, characterized in that for controlling the driving unit to discharge the radioisotope solution in the cylinder at 0.05 ~ 5ml / min per 0.1 ~ 50,000 μl. The method according to claim 1, The control unit is provided with an emergency button, And wherein the emergency button operates by either automatic or manual if the number of distribution of the radioisotope solution is greater than the number of receiving vessels of the radioisotope solution. The method according to claim 10, And dispensing the radioisotope solution again when the emergency button is released. Mounting a syringe on the drive; Matching the screw of the driving unit to the origin; Inputting a dose amount from the syringe to the controller; Inputting the number of dispenses from the syringe into the control unit; Filling the syringe with a radioisotope solution; And Operating the screw to dispense the radioisotope solution in the syringe. The method according to claim 12, Wherein said single dose is determined by the distance traveled by said screw in accordance with the capacity of said syringe. 14. The method of claim 13, The moving distance of the screw according to the single dose A method for dispensing a radioactive isotope solution, characterized in that (dispensing amount per dose) / (dispensing amount / pitch of a syringe) X (traveling distance mm / pitch).

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