KR100233922B1 - Continuous injector with glucose sensor - Google Patents

Abstract

The present invention provides an injection liquid autoinjector which connects a syringe unit to an injection liquid (insulin) autoinjector main body, comprising: a needle member integrally formed with a glucose sensor unit in an injection needle on a pressing piece of the syringe unit; It is an injection liquid autoinjector having a glucose sensor, characterized in that it comprises a main body having a control unit for controlling the supply of insulin by receiving the output through the glucose sensor unit, and the resulting glucose when the injection liquid is supplied in excess or small amount The change of glucose is recognized by the sensor and the injection solution is automatically adjusted to protect the user in case of abnormality, thus maximizing the safety of the product.

In addition, since a sensor for detecting a change in blood glucose caused by an excessive injection of the injection solution is installed together with the needle, the sensor does not need to be separately installed, thereby simplifying use.

Description

Injection fluid injector with glucose sensor

The present invention relates to an injection liquid autoinjector having a glucose sensor, and more particularly, by adding a means for detecting an excessive injection of an injection liquid when injecting an injection liquid (especially insulin), thereby determining a abnormal state of blood glucose due to abnormal injection. The present invention relates to an injection autoinjector having a glucose sensor which reduces or increases the injection amount, thereby automatically and continuously injecting the injection solution.

In general, the injection liquid (in the description herein, the injection liquid mainly refers to insulin and hereinafter referred to as insulin). The autoinjector is a -shaped horizontal needle (also called a butterfly needle, a delivery tube, and It is composed of a main body 4. However, the conventional injection liquid auto-injector as described above is composed of a straight butterfly needle (1) is very painful because the user has to insert while looking directly into his skin tissue, skin tissue Since the inlet of the needle may be blocked by cellular tissues, the inlet of the needle may not be smoothly supplied.

To this end, the Applicant forms a needle of the syringe unit in a-shape, adheres to the back of the needle a bacterial infection prevention member made of a synthetic resin pressing member and a sterilized nonwoven fabric, and connects the rib to the pressing member. Formed to form a connection to the thinly formed transport pipe, and has been proposed to the injection liquid auto-injector configured to be connected to the injection liquid auto-injector body by forming a connector having a screw portion on the other end of the transfer pipe.

That is, as shown in Figures 2 and 3, the syringe unit is composed of a needle member (A), a transfer pipe (B) and a connector (C).

The needle member (A) forms a shape of the needle (11) in a shape, and the needle (11) is inserted into the connecting rib (12) and is installed in the connecting rib (12). To form an integral connection. The needle 11 inserted into the connecting rib 12 is formed so that the bent portion 13 is formed as shown in FIG. 3, and the pressing piece 14 which can push when the needle 11 is inserted is integrated. To form. The pressing member 14 is fixed to the bacterial infection prevention member 15 made of a non-woven fabric that has been sterilized forward. The material of the bacterial infection prevention member 15 is used as natural wood pulp. It is possible to form the diameter of the transfer pipe (B), the length is formed longer. The connector (C) is formed to be connected to the lower end of the transfer pipe (B), the length is formed longer. The connector (C) is formed to connect to the lower end of the transfer pipe (B), to form a male screw portion 15 in the connector (C) to be coupled to the protective cap 17 having a female threaded portion (16). In addition, the connector (C) is coupled to the connector portion 5 of the injection solution auto-injector 4, the connector portion 5 is coupled to form a female screw portion (5a). (18) is a needle protection cap, and (19) is a syringe for storing an injection liquid.

This configuration supplies the injection liquid to the syringe 19 of the injection liquid auto-injector 4, separates the protective cap 17 coupled to the connector (C) and screw-connects with the connector portion (5). Subsequently, the needle protection cap 18 inserted into the needle 11 is removed. Thereafter, the pressing piece 14 is inserted into the skin tissue of the user while pushing the fingertips.

The injection liquid auto injector having such a structure is capable of injecting the injection liquid of the syringe 19 into the body according to a set amount (speed) according to the user's operation, and excessively injecting the user's operation inexperience (or children's mischief, etc.). Sometimes. However, when the injection (insulin) is excessively injected, the state becomes hypoglycemic, the pulse rate of the user increases, sweating, body temperature decreases, and may cause fatal injury to the user.

Meanwhile, in the general medical field, glucose oxidase (GLUCOSE OXIDASE) is used as an enzyme to measure the sugar content of the body. It is a redox enzyme that catalyzes β-D-glucose + O ₂ = D-glucono-1,5-lactone + H ₂ O ₂ , and is a specific protein with high specificity to β-D-glucose. Therefore, it is used to measure glucose in blood or urine specimens and sometimes use the color represented by hydrogen peroxide produced during the reaction. However, it is simply used as an enzyme to measure the sugar by taking blood and the situation that can not be measured from time to time the sugar changes during injection.

The present invention is intended to solve this problem, an object of the present invention is to inject an injection (insulin) abnormally caused by abnormal blood glucose symptoms, it is detected by the sensor to enable the automatic syringe to automatically adjust the injection of the injection constant .

Another object of the present invention is to form a detection means for detecting a blood glucose abnormality caused by the abnormal injection of the injection unit integrally with the needle of the syringe unit so that it can be detected without a separate facility.

To this end, the present invention includes a sensor unit for detecting a blood glucose abnormality in the needle of the syringe unit, the transfer pipe is integrally embedded with a wire connected to the sensor unit, the automatic injector main body means for sensing the voltage of the sensor unit, In response to detection, a control unit for controlling injection is provided so that the sensor unit detects the abnormality in blood glucose and the main body automatically controls the injection of injection.

1 is a perspective view showing a typical injection liquid autoinjector,

2 is a partial exploded perspective view showing another injection liquid injector in general,

3 is an enlarged partial cross-sectional view of the syringe unit shown in FIG.

4 is an excerpt of the main portion of the use state diagram according to FIG. 3, in which the needle is inserted into the subcutaneous tissue,

5 is a use state according to the general syringe unit,

6 is a cross-sectional view of the needle member according to the present invention,

7 is a block diagram of an injection liquid autoinjector according to the present invention;

8 is an exemplary view of according to the present invention;

9 is a partially enlarged view showing an example of the glucose sensor unit used in the present invention.

<Brief description of symbols for the main parts of the drawings>

A: needle member B: transfer tube

C: connector 11: needle

12: connector 13: bend

14: push 15: male thread

16: female thread 17: protective cap

18: needle protection cap 19: injection syringe

100: needle member 101: glucose sensor unit

102: enzyme body 103: electrode part

104: insulating layer 105, 106: conducting wire

110: voltage detection means 120: microcomputer

130: motor drive unit 131: relay

132: motor 133: gear mechanism

150: transfer pipe 160: alarm unit

170: control unit

That is, the present invention is an injection liquid autoinjector using a syringe unit connected to the injection liquid autoinjector main body, the needle member having a glucose sensor unit integrally formed on the needle forming the syringe unit; It is to provide an injection liquid auto-injector having a glucose sensor, characterized in that it comprises a main body having a control unit for automatically controlling the supply of the injection by receiving the output through the glucose sensor unit.

The conductive wire connected to the glucose sensor unit installed in the needle of the needle member is configured to be embedded together in the transfer pipe.

The main body includes a voltage sensing means for sensing a voltage value of the glucose sensor unit, and a control unit for controlling the motor driving unit for supplying the injection liquid by comparing the detected value of the voltage sensing means with a set level.

The control unit includes a microcomputer for comparing and determining the detected values of the voltage sensing means, and a motor driving unit for selecting an amount of rotation of the injection liquid supply motor according to the microcomputer's determination.

The glucose sensor used in the present invention is preferably configured so that the enzyme body used for measuring the general sugar level is provided on the outer circumference of the needle, and the electrode portion for recognizing the organic voltage is also integrally added to the needle.

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

6 is a cross-sectional view of the needle member constituting the present invention, FIG. 7 is a circuit block diagram of the main body of the present invention, and FIG. 8 is an example of the present invention, and is integrally embedded in the needle 11 constituting the syringe unit. A needle member 100 having a glucose sensor unit 101; It is configured to include a main body 180 having a control unit 170 for receiving the output through the glucose sensor unit 101 to control the injection of injection such as insulin.

The conductive wire connected to the glucose sensor unit 101 of the needle member 100 is configured to be embedded together in the transfer pipe 150.

The main body 180 compares the voltage sensing means 110 for sensing the voltage value of the glucose sensor unit 101 and the sensing value of the voltage sensing means 110 with a set level to supply the motor driver 130 for insulin supply. It comprises a control unit 170 for controlling.

An example of the voltage sensing unit 110 is an amplifier 111 for amplifying the level sensed by the glucose sensor unit 101 and a transistor 112 biased according to an output level through the amplifier 111 to perform a switching function. ) And an analog-to-digital converter 113 for converting the output of the transistor 112 into a digital value.

The control unit 170 compares and determines the detected value of the voltage detecting unit 110 to control the control unit 170 as a whole, and the injection liquid supply motor 132 according to the determination of the microcomputer 120; And a motor driving unit 130 to select the amount of rotation and the power transmission portion.

The motor driver 130 may include a relay 131 whose contact is changed to control the motor 132 and the gear mechanism 133 according to the control signal of the microcomputer 120, and the motor 132 according to the change of the contact of the relay 131. It consists of a gear mechanism 135 to vary the number of revolutions. Preferably, the auxiliary sensor 134 may be installed in the gear mechanism 133 to recognize the driving speed, and the microcomputer 120 may recognize the driving speed so as to control the motor driving unit 130.

In FIG. 6, illustration of the bacterial infection prevention member 15 is omitted.

FIG. 9 is a glucose sensor 101 showing an example of the present invention, which encapsulates charges according to blood glucose levels in the cortex of the body and is provided around the tip of the needle 11 and the enzyme body 102. It comprises an electrode portion 103 provided in the needle 11 in an insulated state from the needle 11 at a predetermined interval. The electrode unit 103 is preferably formed of a structure in which the insulating layer 104 is formed on the outer circumference of the needle 11 without the enzyme body 102 and the electrode is wound around the insulating layer 104. The enzyme body 102 may exemplify the glucose oxidase used for blood glucose measurement.

When using the present invention configured as described above, the general process is the same as the conventional one, but if the injection solution is set to inject excessively due to carelessness, the present invention automatically recognizes this and automatically controls the injection of the injection solution. That is, when the injection of insulin is excessively injected, the enzyme body 102 of the glucose sensor unit 101 integrated into the needle 11 promotes the reaction of blood glucose, and thus, when charge is generated around the enzyme body, the electrode unit ( 103). That is, when the blood sugar increases, the voltage of the electrode unit 103 increases, so that the voltage sensing unit 110 recognizes this through the conductive wires 105 and 106 integrated with the transfer pipe 150, and the control unit (eg, a digital value corresponding thereto). It is applied to the microcomputer 120 which is one element of 170. Of course, the microcomputer 120 has a built-in program that can recognize whether the voltage is abnormal. Therefore, the motor driving unit 130 is driven as a result through the microcomputer 120. That is, when the microcomputer 120 operates as shown in FIG. 8, the relay 131 operates according to the operation of the relay 131. By differently providing the polarity and level of the voltage applied to 133 (this technique itself is a conventional technique, detailed description thereof is omitted), increasing and decreasing the rotational force of the motor 132 as necessary. That is, when it is recognized that the sugar content is high, the gear mechanism 133 is driven to reduce the rotational force of the motor 132, and when it is recognized as low, the gear mechanism 133 is driven to increase the rotational force of the motor 132.

In the present invention, the gear mechanism 133 is configured to transfer the power of the motor 132 to a desired level and it is understood that such selection can be implemented in connection with a solenoid (not shown) according to the power supply of the relay 131. You can do it.

As described above, in the present invention, when the injection liquid is supplied in an excessive or excessive state in the injection liquid injector, the sensor unit recognizes a change in the physical blood sugar caused by the sensor and automatically supplies the injection liquid (insulin) in response thereto, thereby maximizing the safety of the product. do.

Accordingly, it is possible to prevent a medical accident due to the user's inadvertent manipulation.

In addition, since a sensor for detecting a change in blood glucose caused by an excessive injection of the injection solution is installed together with the needle, there is no need to install a sensor separately to simplify use.

Claims (4)

A syringe member having a glucose sensor unit integrally formed on the outer circumference of the needle of the syringe unit in an injection liquid auto injector connected to the main body of the syringe unit injection liquid injector; An injection liquid auto-injector having a glucose sensor, characterized in that it comprises a main body having a control unit for automatically controlling the supply of the injection liquid by receiving an output through the glucose sensor unit. The injection liquid auto-injector having a glucose sensor according to claim 1, wherein the conducting wire connected to the glucose sensor unit installed at an outer circumference of the needle is embedded in a transport tube. The method of claim 1, wherein the main body comprises a voltage sensing means for detecting a resistance value of the glucose sensor unit, and a control unit for controlling the motor drive unit for supplying the injection liquid by comparing the detected value of the voltage sensing means with a set level Injection liquid auto injector having a glucose sensor. The apparatus of claim 3, wherein the control unit comprises: a microcomputer for overall control of the control unit by comparing and determining the detection value of the voltage sensing unit; An injection liquid autoinjector having a glucose sensor, characterized in that it comprises a motor drive unit comprising a relay controlled by a microcomputer, a motor controlled according to a relay drive, and a gear mechanism functioning to select an output of the motor according to the relay control.

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