KR100290253B1 - Preventing needle clogging of portable autoinjectors - Google Patents

Abstract

In a portable automatic syringe consisting of a conduit for providing a long-term injection solution, a syringe syringe for providing an injection solution to the conduit and a piston, a body for accommodating the syringe syringe, and a power supply means for providing a push function of the piston shangdong through a rotating shaft. The resonator having high frequency vibration function is placed in the syringe holder of the syringe, the resonator is brought into contact with the piston to transmit the vibration frequency to the piston, and the resonator is connected with a separate high frequency generating means, so that the resonator is connected to the injection liquid through the piston. It is an injection needle blockage preventing device of an insulin auto-injector characterized in that it is configured to provide a high frequency, and the resonance output of the resonator is provided to the syringe through the piston so that ultrasonic waves are delivered to the injection solution to prevent the firming of the injection solution. Thus, when used by the patient, the insulin hardens to prevent an increase in the injection pressure of the insulin injection.

Description

Preventing needle clogging of portable autoinjectors

The present invention relates to a portable auto-injector that enables long-term scanning. In particular, a high-frequency (ultrasound) generated by placing a resonator in the syringe holder of the auto-injector and receiving a high-frequency output configured to be separately applied to the needle through the resonator It is an object of the present invention to provide a needle blocking device of a portable autoinjector configured to be provided.

In general, a long-time injection autoinjector forms a structure in which a push means for pushing a syringe piston is coupled to a housing for receiving an injection syringe. This can exemplify JP-A-52-3292 and US Pat. No. 4,417,889. Since the Japanese Laid-Open Fire No. 52-3293 has a structure in which a syringe injector is installed outside the basic case, it requires a double case, which is inconvenient to carry. In this way, a syringe having a dual case type was developed. As shown in FIG. 2, the output of the oscillator A1 is provided to the timer A2, and the timer A2 output and the switch A4 output are the digital comparators. Is applied to (A3). The output of the digital comparator A3 is connected to the counter A6 and the flip-flop A9. The output of the other oscillator A5 is provided to the counter A6, the AND gate A10 (A11) and the counter A13. The digital comparator A7 output resets flip-flop A9, and the digital comparator A14 output resets flip-flop A16. The control unit A17 is connected to operate the counter A13 by the operation of a manual infusion switch A12. The output of the control unit A17 is provided to the counters A13, A16 and A21. The digital comparator A22 output is connected to the step motor driver A19 to stop the step motor A20. The output of the flip-flop A16 is connected to one input terminal of the OR gate A18 and the other input terminal of the AND gate A11 to which the output is connected. The step motor driver A19 is used to drive the step motor A20. Each fixed number of switches A4, A8, A15 and A25 have five protruding insert bars and provide reference values for the respective digital comparators A3, A7, A14 and A22. It performs the function. The light source A24 and the photo sensor A23 are configured to provide the sensing result to the counter A21, which is provided with the light source A24 and the photo sensor A23 as shown in FIG. In FIG. 3, several holes A26 are formed at regular intervals in the gear plate. The gear shaft A27 is fitted and fixed to the gear plate. The piston plate A28 is screwed with the gear shaft A27 so as to be movable. The light source A24 and the photo sensor A23 are installed on separate fixing plates at intervals from the gear plate at upper and lower vertical portions of the hole A26. An example of a structure including all of these configurations may be illustrated as shown in FIG. 2, and a light source A24 and a photo sensor A23 are installed on the upper portion of the housing, and the light source A24 and the photo sensor A23 are installed. On the horizontal line between the gear mechanism (G) is installed, the gear mechanism (G) is driven by the motor (M). The driving of the motor M is controlled by the driving of the counter A21, the digital comparator A22, the switch A25 and the motor driver A19. The piston shaft A27 of the gear mechanism G is screwed to the piston plate A28 in the form of a nut, and the injection liquid (insulin) of the syringe I is moved to the needle N by the action of the piston plate A28. It is made to be injected. However, such a structure is easily infiltrated with water or moisture because the syringe is in conduction with the outside air. Accordingly, in order to take a shower during injection, it is inconvenient to take a shower after storing the housing in a separate sealing case.

For this purpose, a sealable syringe has been proposed, and FIG. 4 is a front view of the auto-injector illustrating this example, and the upper end of the housing 20 is sealed to the cover 10 and the lower end to the bottom cover 40. The cover 10 is screwed into the connector (2) integral with the conduit (1). The connector 2 engages with the syringe syringe 21, which is coupled to the piston 22 inside the housing 20 to receive the injection liquid. On the bottom surface of the housing 20, a power supply means 30 is accommodated, and a disk-shaped push means 50 that rotates and drives the piston 22 upwardly by rotating on the rotation shaft 31 of the power supply means 30 is screwed. To be combined.

FIG. 5 is a plan view of FIG. 4, in which a lid 10 is installed on the left side of the surface of the housing 20, and a battery lid 24 is installed on the right side. The cover 10 is connected to the connector (2) connected to the conduit (1).

6 is a cross-sectional exploded view taken along line AA of FIG. 5, in the center of the cover 10, a connector 2 and a screw groove 11 for screwing are provided. 12) and packing (13) are installed. The push means guide protrusion 51 of the push means 50 is fitted in the lower portion of the syringe holder 23 to form a push means guide groove 25 for guiding the rising and falling of the push means 50. A piston guide groove 27 for guiding the rise of the piston 22 shown in the figure is formed.

FIG. 7 shows the power supply means 30 fitted in the syringe holder 23 shown in FIG. 6 and the push means 50 on a disc screwed to the rotary shaft 31 thereof. The push means 50 is fitted with a push means guide groove 25 shown in FIG. 6 at its outer periphery and has a lower disc 54 with a push means guide protrusion 51 to move vertically, and a piston 22. There is a concave-convex means 52 for supporting the piston 22 to support the lower plate 54 is composed of an upper disc 55 integral with the lower disc 54. The power supply means 30 includes a deceleration mechanism 33 that decelerates the rotational force of the motor and provides it to the rotation shaft 31. A jig fitting groove (not shown) is formed in the upper disk 55 or the lower disk 54, and the push means guide protrusion 51 enters the center when the jig is fitted in the jig fitting groove.

When using this, in the state of FIG. 7 (assuming that the housing 20 is omitted), the piston 22 is inserted into the syringe 21 shown in FIG. 8, and the syringe 21 has a separate disposable injection needle. (Not shown) is inserted into the vial cap, and the piston 22 is pulled to store the injection liquid (for example, insulin) in the vial in the syringe 21.

In this state, the piston 22 is placed in the push means 50 (of course, into the syringe holder 23 of FIGS. 6 and 4, and the piston guide groove 27 shown in FIG. The piston guide protrusion 26 shown to be coupled is guided, and the push means guide protrusion 51 shown in FIG. 8 is coupled to be guided along the push means guide groove 25), and the lid 10 is a syringe holder ( 23) Screw on the top. In this state, when the connector 2 is screwed with the cover, the connector 2 is naturally engaged with the syringe tip 21-1. Thus, the contents of the syringe 21 in the sealed state are automatically scanned in accordance with the operation of the push means 50. At this time, the push means 50 is the push means guide protrusion 51 is coupled to the push means guide groove 25 of the syringe holder 23 so that it can be raised to the right position, the piston guide protrusion 26 shown in FIG. The piston 22 allows the piston 22 to rise to the right position along the piston guide groove 27 shown in FIG.

On the other hand, examples of the portable automatic needle unit for long-term injection include a "-" shaped horizontal needle member (aka, straight butterfly needle) 3, a conveying pipe (conduit) 1, and the like as shown in FIG. Consists of a connector (2) connected to the connector portion 20-5 of the housing 20.

However, since the needle of the above-described method is composed of a straight butterfly needle member (3) is very painful to be inserted when the user inserts directly into his skin tissue. That is, insulin, which is mainly used as a syringe injection for a long time, is injected into the body by a diabetic patient directly. Check with your eyes. In this case, the user who injects the needle into his body is very painful.

For this purpose, a needle unit has been developed that can be bent directly into the skin and be used in a shape, as shown in FIGS. 10 and 11, with a needle member 3, a transfer pipe 1, and a connector 2. Is done.

The needle member 3 forms the shape of the needle 3-11 in the shape of “a”, and the needle 3-11 is inserted into the connection rib 3-12 and is connected to the connection rib 3. -12) to form the transfer pipe (1) integrally connected. The needle 3-11 inserted into the connecting rib 3-12 is formed such that the bent portion 3-13 is formed as shown in FIG. 11, and can be pushed when the needle 3-11 is inserted. The pressing piece 3-14 is formed integrally. The bacterial infection prevention member 3-14-1 made of the nonwoven fabric which has been sterilized in the forward direction is adhered to the pressing piece 3-14. The material of the bacterial infection prevention member 3-14-1 is used as natural wood pulp. The diameter of the feed pipe 1 is made thin, and the length is formed longer. The connector 2 is formed to connect to the lower end of the transfer pipe 1, forming a male screw portion (2-15) in the connector (2) having a protective cap (2--16) having a female screw portion (2-16) 17). In addition, the connector 2 is coupled to the connector portion 20-5 of the housing 20 of the automatic insulin injector, which connector portion 20-5 is coupled to form a female screw portion 20-5a. Unexplained reference numeral 3-18 of Book 10 is a needle protection cap.

In order to receive the insulin by coupling the needle unit configured as described above to the housing 20 of the portable auto-injector, first, remove the protective cap (2-17) coupled to the connector (2) and the connector portion 20-5 And screw together. Next, the needle protective cap 3-18 inserted in the needle 3-11 is removed. Then, the pressing piece (3-14) is inserted into the skin tissue of the user while pushing the fingertips. At this time, since the needle (11) is composed of a "b" type can be inserted in the vertical to the skin tissue, the user can be instantaneously inserted without the need to visually confirm that the needle is inserted. Accordingly, the user can safely eliminate the pain that follows when injecting the needle into his body, and can be conveniently used as shown in FIG. In addition, since the needle 3-11 is formed in a “a” shape and inserted vertically, there is no fear that the inlet of the needle 3-11 may be blocked by the layered skin tissue. Can be. As the insulin can be smoothly supplied as described above, the diameter of the delivery pipe 1 can be reduced, and the length thereof can be increased. Since the diameter of the delivery tube 1 can be reduced, the waste of insulin can be minimized and the cost can be reduced when the air in the delivery tube 1 and the needle 3-11 is removed. As it can be lengthened, the width of the portion that can be inserted when used as shown in Figures 12 and 13 can be widened for ease of use. As the natural nonwoven fabric sterilized in front of the pressing piece (3-14) is fixed, the pressing piece (3-14) made of synthetic resin is directly applied to the skin when the needle (3-11) is inserted into the skin tissue to supply insulin. We can prevent touching and can prevent bacterial infection. As the shape of the needle 3-11 is “a”, it is vertically inserted when used by injecting into the skin tissue. Thus, even when an external force is applied, the flow of the needle 3-11 does not easily occur, thereby causing tissue damage. Prevents blood flow and does not cause pain.

However, when the needle unit is used in connection with a portable autoinjector, when a small amount of medicine (for example, insulin) placed in the syringe of the portable autoinjector is used for a long time (for example, for three days), the injection liquid (insulin) There is a problem that it is difficult to smoothly inject like some hardening so-called atherosclerosis.

It is an object of the present invention to provide a syringe which adds a vibration means to prevent the insulin from partially curing in the syringe so that the vibration frequency is applied to the injection solution to prevent the insulin from hardening.

To this end, the present invention is to store the oscillator in the syringe holder to transmit the vibration frequency to the syringe liquid, the oscillator to receive the output of the high frequency generator.

1 is a control block diagram of a conventional portable autoinjector.

2 is a perspective view showing an example of installation of the photo sensor of FIG.

3 is a cross-sectional view of a conventional syringe in a state of using the configuration of FIG.

4 is a front view showing another example of a conventional portable autoinjector.

5 is a plan view of FIG.

6 is an exploded view taken along the line A-A of FIG.

7 is a front view showing an example of a conventional power supply means.

8 is an exploded view of a use state showing an example of a conventional push means.

9 is a perspective view showing an example of a conventional needle unit.

10 is a perspective view showing another example of a conventional needle unit.

11 is a partial cross-sectional view showing an example of the needle unit of FIG.

12 is a partially enlarged view showing a state of use of the needle unit of FIG.

FIG. 13 is a perspective view showing a state of use of the needle unit of FIG. 10; FIG.

14 is a front view showing a state in which the resonator of the present invention is placed.

15 is an enlarged view illustrating main parts of FIG. 14.

16 is a block perspective view illustrating the concept of the present invention.

17 is a block diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: conduit 2: connector

2-15: Male thread portion 2-16: Female thread portion

2-17: protective cap 3: needle member

3-11: needle 3-11-1: bend

3-12: connecting rib 3-13: bend

3-14: Push piece 3-14-1: Bacterial infection prevention member

3-14-2: Protective cap pipe groove 3-14-3: Projection

3-18: Protective cap 3-18-1: Fitting diameter

3-18-2: Insertion diameter 10: Cover

11: thread groove 12: bolt screw

13: packing 20: housing

20-5: connector portion 21: syringe

22: piston 23: syringe repairer

24: battery cover 25: push means guide groove

26: piston guide protrusion 27: piston guide groove

30: power supply means 31: rotating shaft

32: motor 33: deceleration mechanism

40: bottom cover 50: push means

51: guide means for pushing means 52: uneven means

54: lower disc 55: upper disc

60: resonator 61: diaphragm

62: electrode plate 63: rotating shaft through hole

64: wire 70: high frequency (ultrasound) generator

80: micom

That is, the present invention is a syringe for a long time injection consisting of a conduit for providing a long time injection, a syringe syringe for providing an injection to the conduit, a piston, a body for receiving a syringe syringe, and a power supply means for providing a push function of the piston shandong through a rotating shaft. In the syringe holder of the portable auto-injector, the resonator having a high frequency vibration function is placed, the resonator is brought into contact with the piston to transmit the vibration frequency to the piston, and the resonator is connected to a separate high frequency generating means so that the resonator An object of the present invention is to provide a needle clogging prevention device for an insulin autoinjector, which is configured to provide a high frequency to an injection liquid through a piston.

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

14 is a front view of the main portion of the installation state showing the case where the resonator of the present invention is installed, the push means 50 is fitted to the push means guide groove 25 shown in FIG. Lower disc 54 with means guide protrusion 51 and concave and convex means 52 which support piston 22 and seat piston 22 and upper disc 55 integral with lower disc 54. Is done. The power supply means 30 includes a deceleration mechanism 33 that decelerates the rotational force of the motor and provides it to the rotation shaft 31. A jig fitting groove (not shown) is formed in the upper disk 55 or the lower disk 54, and the push means guide protrusion 51 enters the center when the jig is fitted in the jig fitting groove. Resonator 60 of the present invention is placed on the upper disk 55 is configured to transmit the vibration force due to the resonance to the piston (22).

FIG. 15 is an enlarged main view of the case where the resonator of the present invention is placed, and the lower disc 54 is coupled to the rotating shaft 31, and the upper disc 55 is set to rotate integrally on the lower warp plate 54. The resonator 60 is placed on the upper disc 55. The resonator 60 is composed of a diaphragm 61 in the middle layer and electrode plates 62 above and below the diaphragm 61, and the upper and lower electrode plates 62 describe the high frequency output through the conducting wire 64. It may be configured to be in contact with the electrode formed on the inner wall of the syringe holder 23 while being applied through the generator 60 or moving up and down through the contact terminal 65 in the form of a wire.

FIG. 16 is a view showing driving means connected to the resonator 60 used in the present invention together, the high frequency generator 70 performing a high frequency generation function under the control of the microcomputer 80, and a high frequency generator. An output of the 70 consists of a donut-shaped resonator 60 that is applied through the conductive wire 64. In the center of the resonator 60, a rotating shaft through hole 63 through which the rotating shaft 31 passes is formed, and the resonator 60 has a configuration in which the electrode plate 62 is integrated above and below the central diaphragm 61. Achieve.

FIG. 17 is a block diagram showing the configuration of the present invention. The high frequency generator 70 under the control of the microcomputer 80 applies the generated high frequency to the resonator 60, and the resonance of the resonator 60 is performed. The output functions to be applied to the syringe 21 through the piston 22. In addition, the injection liquid (for example, insulin) in the syringe 21 forms a configuration in which high frequency is transmitted to the needle 3-11 through the transfer pipe 1 which is the needle member 3.

Before describing the operation of the present invention configured as described above, the resonator 60 used in the present invention refers to a piezoelectric vibrator, and means a piezoelectric element used for generating high frequency (ultrasound). The diaphragm 61 of the resonator 60 used in the present invention preferably uses a barium titanate material, and has a resonance frequency of 30-10000 Hz. The principle of the piezoelectric resonator is that distortion occurs when a certain kind of crystal is placed in the electric field, or a piezoelectric force is generated when the distortion is applied. This phenomenon is used as a vibrator and a resonator, and crystallization salt, barium titanate, and the like are typical. The theoretical background of the distortion is the piezo electric effect (Piezo electric effect), when the pressure is applied in a certain direction, such as crystal or rossel salt, the voltage is generated in a certain direction (direct piezoelectric effect) when the voltage is applied upside down It is a distortion (piezoelectric adverse effect) phenomenon (a phenomenon that generates a vibration output in conjunction with a high frequency input in an alternating current), and according to the name of the discoverer, the direct effect is called the Curie effect and the reverse effect is called the Leafman effect. Longitudinal effect is the case where the overcharge direction is the same, and lateral effect is the case where the right angle is generated. The large effect is crystal, rossel salt (sodium stannate, potassium), ammonium phosphate (to A), ethylene diamine (EDT), potassium stannate (DKT), etc., crystal oscillator or rossel salt acoustic element (crystal, Microphone, pickup, earphone, speaker) or ultrasonic piezoelectric element. As a result, the present invention applies the resonator 60, which is the vibration output means, to the insulin portable autoinjector, and combines the push means 50 for this purpose to transmit the vibration to the piston 22. Therefore, when the high frequency generator 70 is operated by controlling the microcomputer 80 or by using a separate switch (not shown), the output is applied to the electrode plate 62 of the resonator 60 by the wire 64. do. In this case, the diaphragm 61 is a substance (for example, barium titanate) that generates a piezoelectric effect (eg, a piezoelectric inverse distortion), and thus generates high frequency vibration, which is transmitted from the upper disc 55 to the piston 22. The high frequency (ultrasound) has a low amplitude in nature, so the transmission force is strong, so it is transmitted from the piston 22 to the syringe 21, and the injection liquid (insulin) of the syringe 21 passes through the conduit 1 to the needle 3-11. It is delivered by piggybacking the internal injection. Eventually, this may result in a kind of wave generation effect, which may eliminate the stiffness of the injection liquid to be solidified inside the needle.

The present invention described above is not limited to the above-described embodiments and drawings, and various permutations, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those who have

As described above, the present invention places the resonator in the syringe holder of the portable auto-injector, and the resonator receives a separate ultrasonic generator output, so that the ultrasonic generator output is sequentially transmitted to the piston, the syringe, and the needle through the resonator. Even if the injection of the insulin provided through the laten to the phenomenon that some of the hardening occurs by providing the ultrasonic output can prevent the solidification phenomenon can prevent the clogging of the needle.

Claims (2)

In a portable autoinjector comprising a conduit for providing an injection for a long time, a syringe and a syringe for providing an injection to the conduit, a main body for accommodating the syringe syringe, and a power supply means for providing a push function of the piston shangdong through a rotating shaft. The resonator having high frequency vibration function is placed in the syringe holder of the syringe, the resonator is brought into contact with the piston to transmit the vibration frequency to the piston, and the resonator is connected with a separate high frequency generating means, so that the resonator is connected to the injection liquid through the piston. The needle blockage preventing device of an insulin autoinjector, characterized in that configured to provide a high frequency. The needle blockage preventing device of the insulin autoinjector according to claim 1, wherein the resonator has a rotating shaft through-hole through which the rotating shaft passes.