JPH0461867A - Continuous feed device for medicinal solution - Google Patents

Abstract

PURPOSE:To enable the extreme reduction of the bacterial contamination in medicinal solution by expanding a plastic contraction body via the discharge of gas from an airtight chamber with a vacuum means, housing a medicinal solution container in the elastic contraction body and purging the solution container of the medicinal solution with the elastic pressing force of the elastic contraction body. CONSTITUTION:A vacuum case 1 having a built-in elastic contraction body 2 is set to a vacuum means 3. In this state, an air-tight chamber between the elastic contraction body 2 and the vacuum case 1 is connected to the suction port of the vacuum means 3. This vacuum means 3 is operated and the air is released from the airtight chamber 5 between the elastic contraction body 2 and the vacuum case 1. In this case, vacuum is generated on the external surface of the elastic contraction body 2, thereby causing the expansion of the body 2. A medicinal solution container 4 is inserted in the expanded elastic contraction body 2. Thereafter, the vacuum case 1 is detached from the vacuum means 3, thereby opening space between the elastic contraction body 2 and the vacuum case 1 to the atmosphere. In this state, the medicinal solution container 4 is pressed with the elastic contraction force of the body 2, and the medicinal solution inside is exposed to pressure.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a continuous drug infusion device that applies pressure to a drug using the elastic contraction force of rubber or the like and injects the drug into the body using a catheter or the like.

[Conventional technology]

Infusion systems have already been developed that use the contraction force of balloons to inject medical solutions into the body. This system is commonly called a "balloon infusion device." This device is described, for example, in Japanese Patent Laid-Open No. 11465/1983. The apparatus described in this publication is shown in FIG. This device includes a cylindrical body 10, a balloon 11, a valve 12, a tube 13, and an injection needle. A balloon 11 is fixed to the outer periphery of the cylindrical body 10 in airtight contact. The balloon 11 has a communication hole extending through the cylindrical main body 10 . A tube I3 is connected to the tip of the cylindrical body IO, and a valve 12 is provided at the rear end. The valve 12 can inject a medical solution toward the cylindrical body lO,
The injected drug solution will not flow back. This device is used under the following conditions. ■ Transfer the drug solution to the cylindrical body 10 using a syringe or the like. A medical solution is injected into the cylindrical body 10 from the rear end through a valve 12. At this time, to prevent the liquid from flowing out from the tip of the cylindrical body 10, the tube 13 is pressed or a stopcock is used to prevent the liquid from flowing. (2) The medical solution injected into the cylindrical body 10 fills the balloon 11 and inflates it. The medical solution injected into the cylindrical body 10 is prevented from flowing backwards by the valve 12. In this state, the medical solution is kept under pressure by the elastic contraction force of the balloon 11. ■ Insert the injection needle connected to the tip of the tube 13 into the human body. ■ Release the member blocking the middle of the tube 13. The pressure of the balloon II forces the medical solution into the human body at a constant flow rate. The flow rate of the chemical solution is controlled by a flow rate adjustment valve provided at the tip of the cylindrical body IO. A device that can inject liquid medicine into the human body in this state can be made portable. Therefore, it is possible to inject a medicinal solution without restraining the child in bed, as in the case of an intravenous drip. Furthermore, devices for injecting medical solutions using the expansion and contraction force of a balloon are disclosed in, for example, JP-A-62-11464 and JP-A-62-5.
No. 01.333, JP-A-64-70069,
JP 1-135360, JP 2-11159
It is also described in Japanese Patent Application Laid-Open No. 2-11160.

[Problem to be solved by the invention]

However, in the conventional continuous drug infusion devices described in these publications, it was necessary to transfer the drug into the balloon using a syringe or the like. Unlike conventional intravenous drips, it cannot be directly injected into the body from a drug container, which requires a lot of effort to transfer the drug, and there is also a risk that the drug may be contaminated with bacteria during this process. . Furthermore, in the conventional device, the balloon and the cylindrical body to which it is fixed are disposable, and furthermore, a syringe or the like is required to transfer the balloon, resulting in high running costs. The present invention was developed with the aim of further solving this drawback, and an important objective of the present invention is to provide a continuous drug solution infusion device that can significantly reduce bacterial contamination of the drug solution. Another important object of the present invention is to provide a continuous drug infusion device that can reduce running costs and inject drug solutions with simple operations.

[Means to solve the problem]

The continuous drug solution infusion device of the present invention has the following configuration in order to achieve the above-mentioned object. That is, the continuous drug solution infusion device of the present invention is a device for injecting a drug solution filled into a flexible drug container into a human body, and is characterized by having the following configuration. (a) The continuous drug infusion device includes a vacuum case 1, an elastic contractile body 2 that applies pressure to the drug solution, and a vacuum means 3 that expands the elastic contractile body 2. (b) Vacuum case] has a size that can accommodate the liquid medicine container 4 so that the elastic contraction body 2 can be expanded to a size that can accommodate the liquid medicine container 4 6 (c) Elastic contraction body 2 is disposed within the vacuum case 1 so as to be expanded by the vacuum case 1. (d) The elastic contractile body 2 is set in the vacuum case 1 in such a manner that an airtight chamber 5 is formed between it and the vacuum case 1 so that the elastic contractile body 2 is expanded by evacuating its outer surface. (e) The airtight chamber 5 between the elastic contractile body 2 and the vacuum case I is connected to the vacuum means 3. (f) The vacuum means 3 exhausts the gas in the airtight chamber 5 and expands the elastic contracting body 2, and the liquid medicine container 4 is accommodated in the elastic contraction body 2, and the inside of the liquid medicine container 4 is filled by the elastic pressing force of the elastic contraction body 2. It is configured to push out a chemical solution.

[Effect]

The continuous drug infusion device of the present invention is used in the following conditions. (2) As shown in FIG. 1, a vacuum case l containing an elastic contractile body 2 is set in the vacuum means 3. In this state, the airtight chamber 5 between the elastic contractile body 2 and the vacuum case 1 is connected to the suction port of the vacuum means 3. (2) The vacuum means 3 is operated to exhaust air from the airtight chamber 5 between the elastic contractile body 2 and the vacuum case 1. (2) The outer circumferential surface of the elastic contracting body 2 becomes vacuum and is expanded as shown in FIG. (2) As shown in FIG. 3, insert the drug solution container 4 inside the expanded elastic contractile body 2. (2) Separate the vacuum case 1 from the vacuum means 3 and open the space between the elastic contractile body 2 and the vacuum case 1 to the outside air. In this state, as shown in FIG. 4, the drug solution container 4 is pressed by the elastic contraction force of the elastic contractile body 2, and the drug solution inside is pressurized. (2) As shown in FIG. 6, a drug solution injection member fixed to the tip of the tube is inserted into the human body, and the drug solution is injected into the human body. Although not shown, the injection amount of the chemical solution is adjusted by connecting a flow rate regulating valve in the middle of the tube, or by providing a flow rate regulating valve in the chemical solution injection member 6 connected to the tip of the tube.

【Example】

Embodiments of the present invention will be described below based on the drawings. However, the embodiments shown below are illustrative of a device for embodying the technical idea of this invention, and the device of this invention has the material, shape, structure, and arrangement of the component parts as shown below. It is not specific. Various modifications may be made to the device of the present invention within the scope of the claims. Furthermore, in order to make the claims easier to understand, the numbers corresponding to the members shown in the embodiments are indicated in [Claims column] and [Means for Solving the Conventional Problems]. Additional notes are added to the members shown in the "Column" and "Column of Action". However, the members shown in the claims are by no means limited to the members of the embodiments. The continuous drug infusion device shown in FIG. 7 is a device for injecting a drug filled in an accessible drug container 4 into a human body, and has the following configuration. The drug solution container 4 is deformed by being pressed from the outside,
Any device that can generate internal pressure to push out a medicinal solution and inject it into the human body can be used. For example, the drug solution container 4 may be made of an accessible synthetic resin and molded into a bag shape as shown in FIG. 8. The accessibility of the drug solution container 4 can be achieved by making the container thinner, by molding it with flexible synthetic resin, or by providing pleats to make it easier to deform, as shown in FIGS. 9 and 1O. . The accessibility required of the liquid medicine container 4 is such that when the elastic contraction member 2 presses it from the outside, the liquid medicine container 4 deforms and pushes out the medicine inside. Therefore, the accessibility required of the drug solution container 4 is adjusted to an optimal value in consideration of the contractile force of the elastic contractile body 2. In other words, the contractile force of the elastic contractile body 2 is adjusted to an optimal value in consideration of the accessibility of the drug solution container 4. The elastic contractile body 2 is adjusted to an optimum value according to the amount of the drug solution to be injected into the body. The internal volume of the drug solution container 4 changes depending on the type of drug solution to be injected. For example, the internal volume of the elastic contractile body 2 is 0.5 mA to 3000 m, preferably 5 mjlL to
A 2000mA type can be used. A continuous drug infusion device that pumps a drug solution from an accessible drug solution container 4 includes a vacuum case 1, an elastic contractile body 2 that applies pressure to the drug solution, and a vacuum means 3 that expands the elastic contractile body 2. ing. As shown in FIGS. 7 and 11, the vacuum case 1 has a cylindrical shape or an elliptical shape with an open top and a closed bottom. The vacuum case 1 expands the elastic contractile body 2 to a size that can accommodate the chemical liquid container 4. Therefore, the size is such that the elastic contraction body 2 can be expanded to a size that allows the liquid medicine container 4 to be placed therein. Further, the air in the airtight chamber 5 between the vacuum case 1 and the elastic contraction body 2 is evacuated to expand the elastic contraction body 2. Therefore, the vacuum case l is made of a material that is non-porous and strong enough not to deform in a vacuum state, such as hard vinyl chloride.
Made of hard synthetic resin such as polycarbonate ABS resin, or metal, it is processed into a cylindrical shape. The vacuum case 1 shown in FIG. 5 has a double structure consisting of an outer case 1Δ and an inner case IB. The bottom of the outer case IA is closed at the bottom where the exhaust port 8 is located. Inner case 1B
It is made of thin and light synthetic resin and is molded into a cylindrical shape with openings at both the top and bottom ends. Inner case IB has its upper end hermetically connected to the upper end of outer case IA during use. In order to connect the inner case IB to the outer case IA in an airtight manner, for example, a downwardly opening groove (not shown) is provided on the upper edge of the inner case IB, and the upper end of the outer case IA is airtightly fitted into this groove. It can be attached and connected. This vacuum case 1 is constructed by evacuating the air in the airtight chamber to expand the elastic contracting body 2, placing the chemical liquid container 4 in the elastic contracting body 2, and then removing the inner case IB from the outer case LA.
It has the advantage of being portable and convenient to use. By the way, when the vacuum case 1 is made of synthetic resin, preferably transparent synthetic resin is used. The transparent vacuum case 1 has the advantage that the contracted state of the elastic contractile body 2 can be confirmed from the outside. The elastic contractile body 2 deforms elastically in the expanded state and presses the drug solution container 4 . There are roughly two types of states in which the elastic contractile body 2 is elastically deformed. That is, the elastic contracting body 2 is stretched,
a state in which it presses the drug solution container 4 with the restoring force of its contraction;
This is a state in which the elastic contractile body 2 is elastically deformed, and the drug solution container 4 is pressed by the elasticity that restores the deformed shape to the original shape. Furthermore, an elastic contractile body that presses the drug solution container with both the contraction force due to extension and the restoring force due to deformation can also be used. The elastic contracting body, which presses the drug solution container with its contractile force to stretch and contract, is made of stretchable synthetic rubber or natural rubber. The elastic contracting body 2, in which a stretchable member such as rubber contracts to press the drug solution container 4, is shown in FIGS. 12 and 13. In the contracted state, the elastic contractile body 2 forms a cross shape and crushes the drug solution container 4. However, the elastic contractile body is 5
Although not shown, it is also possible to press the drug solution container by making the gap into a wave shape or other shape. Further, the elastic contracting body 2 that presses the drug solution container 4 with the restoring force of the deformed shape can also be made of a rubber-like elastic body. The elastic contractile body 2 that presses the drug solution container 4 in this state is shown in the sectional view of FIG. 14. Elastic contractile body 2 shown in these figures
In the deflated state without being expanded, the shape is narrow cross-shaped and has a small internal volume, as shown by the solid line. The elastic contractile body 2 is expanded by creating a vacuum between it and the vacuum case l. Therefore, the elastic contractile body 2 is set in the vacuum case 1 with an airtight chamber 5 formed between it and the vacuum case 1. The elastic contractile body 2 shown in FIG. 12 has a bag shape with a flange 7 provided at the opening. The outer periphery of the collar 7 is hermetically connected to the vacuum case 1, and an airtight chamber 5 is provided between the elastic contractile body 2 and the vacuum case 1. The elastic contractile body 2 is normally fixed to the vacuum case 1, and an airtight chamber 5 is formed between the two. However, as shown in FIG. 15, it is also possible to provide an airtight chamber 5 by detachably connecting the elastic contractile body 2 to the vacuum case 1. The elastic contractile body 2 shown in FIG. 15 is hermetically connected to the opening of the vacuum case 1 via a binding band 9. The binding band 9 folds back the elastic contractible body 2 to the outside of the opening, binds the outer periphery of the elastic body 2, and connects the elastic body 2 airtightly. With this structure, the continuous drug infusion device connects the elastic contractile body 2 to the vacuum case 1. After putting the drug container 4 inside the elastic contractile body 2, the elastic contractile body 2 is separated from the vacuum case 1, and the drug solution is injected into the human body. It has the feature that it can be injected into Furthermore, FIG. 16 shows elastic contracting bodies of different shapes. This elastic contractile body 2 has a tube shape with both upper and lower ends open, and has a collar 7 fixed to the upper end. It is necessary to fix the opening at the lower end of the elastic contractile body 2 having this shape to the vacuum case l. This is to provide an airtight chamber between the vacuum case 1 and the elastic contractile body 2. FIG. 17 shows a vacuum case 1 to which a tubular elastic contraction body 2 is attached. The vacuum case l shown in this figure is provided with a fixed cylinder 15 passing through the bottom. The fixed cylinder 15 is the first
As shown in FIG. 7, the lower end of one elastic contractile body 2 is inserted, folded back and tied around the outer periphery to form an airtight chamber 5 between the elastic contraction body 2 and the vacuum case 1. Furthermore, the elastic contractile body 2 shown in FIGS. 18 and 19 has a core material 14 embedded in the longitudinal direction6.The core material 14 includes an elastic metal wire, a hard or semi-hard synthetic resin wire such as PC, Alternatively, reinforcing fibers or the like can be used. The elastic contractile body 2 in which a metal wire or a synthetic resin wire is embedded has a feature that the core material 14 prevents the elastic body from elongating in the vertical direction, so that it can effectively press the drug solution container from the side. This invention does not specify a structure for airtightly connecting an elastic contractile body to a vacuum case.The continuous drug infusion device of this invention airtightly connects an elastic contraction body to a vacuum case to form an airtight chamber between the elastic contraction body and the vacuum case. structure can be adopted. An airtight chamber 5 between the elastic contractile body 2 and the vacuum case l is connected to a vacuum means 3. The vacuum case 1 shown in the drawings is provided with an exhaust port 8 on the bottom or outer periphery, and the exhaust port 8 is connected to the vacuum means 3. As the vacuum means 3, any means capable of evacuating the gas from the airtight chamber 5 can be used. For example, a vacuum pump driven by a motor or a mechanism that manually moves a piston in a cylinder back and forth to exhaust air can also be used. The vacuum means 3 has its suction side connected to the exhaust port 8 of the vacuum case, and exhausts the air inside the vacuum case 1.

【Effect of the invention】

The continuous drug solution infusion device of the present invention can inject a drug solution into a human body by pressing the outer surface of the drug solution container with an elastic contractile body. Therefore, there is no need to transfer the medicinal solution to the injection device, unlike conventional continuous infusion devices, and it has the advantage of being able to easily inject the medicinal solution. Furthermore, the continuous drug infusion device of the present invention has the advantage of minimizing bacterial contamination of the drug. This is because there is no need to transfer the drug solution from the container to the balloon or the like using a syringe or the like. This is extremely important for this type of device. This is because medical solutions injected into the human body are required to always contain zero bacteria. Furthermore, the continuous drug infusion device of the present invention does not require a member for injecting the drug from the container into the balloon or the like, and
Remove the balloon and the disposable parts it is attached to (
Therefore, the apparatus of the present invention can also realize the feature of significantly reducing running costs.

[Brief explanation of the drawing]

1 to 6 are schematic sectional views showing how the continuous drug infusion device of the present invention is used, FIG. 7 is a partially sectional front view of the continuous drug infusion device showing an embodiment of the present invention, and FIG. 8 Figures 10 to 10 are front views and cross-sectional views showing the chemical liquid container, and Figure 11 is
The figure is a perspective view showing the vacuum case and the elastic contraction body, Figures 12 to 14 are side views and cross-sectional views showing the elastic contraction body, and Figure 15 is a specific example of fixing the elastic contraction body to the vacuum case. 16 is a side view showing an elastic contracting body of another embodiment, FIG. 17 is a sectional view showing a state in which the elastic contracting body shown in FIG. 16 is fixed to a vacuum case, and FIGS. FIG. 19 is a side view and cross-sectional view of an elastic contractile body according to another embodiment, and FIG. 20 is a cross-sectional view of a conventional continuous drug infusion device. l・・・・・・・・・Vacuum case, IA・・・・
・・・－・・・・・・Outer case, 1B－・・・・・・・・・
・・Inner case, 2・・・・・・・・・・Elastic contraction body, 3・・・・・・・・・・−・Vacuum means, 4・・・・・・・・・・
・・・・・−・Medicinal solution container, 5・・・・・・・・・−・・
Airtight chamber, 6...... Chemical injection member, 7---
・・・・・・Brim, 8−・・・・・・・Exhaust port, 9 ・・・・・・・・・・Cable tie, lO・・
......Cylindrical body, 11---...
・・・Balloon, 12・・・・・・・・・Valve, 13・・・・・・・・・Chief 14・・・・・・・・・Core material, 15・・・・・・・・・・・・Fixed tube.

Claims (1)

[Claims] (1) A continuous drug solution infusion device which is a device for injecting a drug solution filled into a flexible drug container into a human body, and is characterized by having the following configuration. (a) The continuous drug infusion device includes a vacuum case 1, an elastic contractile body 2, and a vacuum means 3. (b) The vacuum case 1 has a size that allows the chemical solution container 4 to be placed therein. (c) The elastic contractile body 2 is disposed within the vacuum case 1. (d) The elastic contractile body 2 has an airtight chamber 5 between it and the vacuum case 1.
It is set in the vacuum case 1 in a state where it can be used. (e) The airtight chamber 5 between the elastic contractile body 2 and the vacuum case 1 is connected to the vacuum means 3. (f) The vacuum means 3 evacuates the gas in the airtight chamber 5 and expands the elastic contracting body 2, and the liquid medicine container 4 is housed in the elastic contraction body 2, and the elastic pressing force of the elastic contraction body 2 causes the liquid medicine container 4 to be inside. It is configured to push out a chemical solution.