KR101855508B1 - Simulator for Intravenous Injection and Blood Sampling - Google Patents

Abstract

The present invention allows simulated blood simulated by blood circulating in the human body to be supplied to a fluid tube provided in a human body model such as an arm or a leg so that an unskilled medical person can perform intravenous injection or blood sampling exercise The present invention relates to an intravenous injection and a blood sampling simulator for exercising an intravenous operation or a blood sampling operation with a feeling,
A simulated blood producing device 20 for producing and supplying a simulated blood corresponding to blood; (30) having a fluid tube (31) circulating a simulated blood therein and having a scanning part (35) formed at one surface thereof so as to pierce the needle with the fluid tube (31); A feed pump (11) for feeding the simulated blood prepared in the simulated blood generator (20) to the human body model (30); A flow meter 12 disposed between the manikin 30 and the feed pump 11 for measuring the amount of simulated blood supplied to the manikin 30; And a drain member installed between the manikin (30) and the flow meter (12) to discharge simulated blood.

Description

Simulator for Intravenous Injection and Blood Sampling

The present invention relates to an intravenous injection and a blood sampling simulator capable of performing an intravenous injection or a blood sampling exercise, and more particularly, to a simulator for simulating blood circulating in the body, The present invention relates to an intravenous injection and a blood sampling simulator that can be practiced in an intravenous injection operation or a blood collection operation with a feeling similar to an actual state by supplying the fluid to a fluid tube.

Medical simulation training is an educational method that enables medical trainees who are practicing medical education to acquire clinical experience by experiencing simulated clinical care and crisis situation close to the clinic. Medical simulation training can bring various clinical experiences to medical trainees, and there is no possibility of harm to patients, and it is safe for medical trainees and is introduced by many countries in the world.

Such medical simulation training is mainly applied to medical trainees such as medical practitioners, but it can also be applied to medical assistants such as nurses and nursing assistants.

Usually, a nurse or a nurse assistant performs medical assistance activities such as measuring a patient's blood pressure or giving an injection, and sometimes uses various medical devices. Nurses and nursing assistants use a manikin similar to the human body for medical practice. However, since there is no blood in the manikin, only the training of mannequins is enough to stab the prescribed needle. In fact.

As a result, nurses and nursing assistants are conducting medical practice using colleagues who are educated together. They also perform various medical exercises by forming a blood vessel-like duct on the mannequin and allowing the fluid to flow through the duct.

On the other hand, the intravenous injection has the advantage that the medicinal solution reaches the necessary tissues of the body through the heart within 1 to 2 minutes, so that the medicinal effect appears quickly and the response is also clearly visible. When the oral administration of water is not sufficient, Or to supply other necessary electrolytes, or to inject drugs such as antidotes into the blood, as well as blood supply after bleeding, or to expect fast drug efficacy.

However, in order to acquire the above-mentioned intravenous injection technique, when a novice learner performs a clinical operation directly on the human body, a safety accident may occur. Generally, in the case of a novice learner, repeated intravenous injection Pre-training in the form

However, the fluid flowing along the channel formed in the human body model such as the mannequin is completely different from the actual blood, so that it is not suitable for the education of the blood vessel or the education or training of using various medical devices related to the blood, There is a problem.

In addition, there are other problems in that the effect of education or training is limited because it is difficult to obtain various types of training blood for education or training, although the state of blood varies depending on the state of health or blood vessels flowing through the blood.

Meanwhile, as a result of investigation of the prior art related to the present invention, several patent documents have been searched, and some of them will be described as follows.

Patent Document 1 discloses a terminal equipped with a simulation program for simulation of intravenous injection and installed on an installation table; A terminal monitor connected to the terminal and displaying a program icon for selecting the simulation program; A simulation monitor is installed so that the screen is directed downward, functions for intravenous scan simulation driven by the simulation program are displayed on the screen in the reverse order, and a reflector is installed at a predetermined interval from the simulation monitor, The functions for the intravenous scan simulation are reflected and displayed correctly, a workbench formed in the space between the reflector and the lower portion and having a space for installing a haptic device, and connected to the terminal; And a haptic arm connected to the terminal through the workbench, the haptic arm being connected to the haptic main body, wherein the functions for the intravenous scan simulation displayed on the reflector are selected and executed by operating the haptic arm as a cursor, And a haptic device that allows the user to perform the same function as placing the actual intravenous injection with the haptic arm by selecting and executing the image on the screen. Thus, the intravenous injection The simulator is described.

Patent Document 2 discloses an arm model in which an insertion groove is formed in an upper portion and an arm is twisted so that the back of the hand and the upper arm are upward; A skin pad detachably attached to the insertion groove of the arm model and having a blood vessel simulation tube formed therein; A pump driving device connected to the blood simulation tube and the pad connection tube to supply blood; And a liquid blood supply container connected to the pump driving device by a container connection tube and supplying the stored blood to the blood simulation tube, so that the practitioner can feel the needle passing through the blood vessel through the arm model device The present invention relates to an arm model apparatus for intravenous training, which realizes realistic sense of realness similar to that of a human body and can perform injection training.

Patent Literature 3 discloses an apparatus and a method for providing an arm model, a skin pad attachable to the arm model, a pump driving device for supplying blood, and a liquid blood supply container The pulsation reduction device is provided in the pump driving device so as to reduce the pulsation. Thus, the practitioner realizes the feeling that the injection needle passes through the blood vessel through the arm model device, realizing a feeling of reality similar to a human body The pump drive device with the pump drive controller and the pulsation abatement device can greatly reduce the pulsation generated while supplying the blood at the blood flow rate similar to that of the actual pump. It is also possible to inject medication through intravenous injection as well as to perform catheter insertion and blood sampling. And an arm model device for intravenous training that facilitates the practice of the replacement and installation of the skin pads, the leakage is free, the durability is excellent, and the remote control can simultaneously perform the training and evaluation of a large number of personnel. .

KR 10-2012-0107752 A KR 10-2013-0033279 A KR 10-1317860 B1

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art described above, and it is an object of the present invention to provide a blood pressure monitor, The present invention provides an intravenous injection and a blood sampling simulator which can enhance the learning effect by allowing the user to receive a blood sample.

It is another object of the present invention to provide an intravenous injection and blood sampling simulator capable of enhancing the learning effect of unskilled medical personnel by making the color and condition of the simulated blood supplied to the fluid tube of the human body similar to the blood of the actual patient have.

It is another object of the present invention to provide an intravenous injection and a blood sampling simulator in which a human body model is worn or damaged and the remaining portions can be used continuously.

According to an aspect of the present invention, there is provided a blood testing apparatus comprising: a simulated blood producing apparatus for producing and supplying a simulated blood corresponding to actual blood; A human body model provided with a fluid tube circulating the simulated blood therein and having a injection section formed at one surface thereof so as to pierce the injection needle with the fluid tube; A feed pump for supplying the simulated blood prepared in the simulated blood generator to the human body model; A flow meter disposed between the torso and the feed pump for measuring the amount of simulated blood supplied to the torso; And a drain member installed between the manikin and the flowmeter to discharge the simulated blood.

According to the intravenous injection and blood sampling simulator of the present invention, the human body model includes a connection port in which one end of the fluid tube is exposed to the outside so that the simulated blood is supplied to the fluid tube or the simulated blood of the fluid tube is discharged to the outside. Respectively.

According to the intravenous injection and blood sampling simulator of the present invention, the drain member includes a drain tank in which the simulated blood discharged from the manikin is stored, and a drain tank having one side connected to one of the connection ports and the other side connected to the drain tank And the other side includes a three-way valve connected to the return pipe.

According to the intravenous injection and blood sampling simulator of the present invention, the connection port is connected to the three-way valve via a connection pipe.

According to the intravenous injection and blood sampling simulator of the present invention, the connection port and the connection pipe are detachably coupled.

According to the intravenous injection and blood sampling simulator of the present invention, the blood storage tank storing the simulated blood is connected to the feed pump, so that the simulated blood of the blood storage tank circulates the fluid tube of the human body model, Wherein the tank is detachably connected to the simulated blood maker.

The intravenous injection and blood sampling simulator of the present invention supplies simulated blood to the inside of a human body model equipped with a fluid tube, and a non-skilled medical person such as a practitioner, nursing student, nursing assistant, It has the advantage of enhancing the learning effect by practicing with the simulated blood similar to the blood of the actual patient by adjusting the ratio of various components constituting the simulated blood so as to receive a feeling similar to the real one when poking out the blood.

According to the intravenous injection and blood sampling simulator of the present invention, the simulated blood is supplied to the fluid tube provided in the human body model or the simulated blood of the fluid tube is discharged, thereby preventing contamination or damage of the human body model have.

Further, according to the intravenous injection and blood sampling simulator of the present invention, the connection port of the three-way valve and the male model is connected via the connection pipe, and the connection port and the connection pipe are detachably coupled, It is effective to replace only the model and continue to use the rest.

In addition, according to the intravenous injection and blood sampling simulator of the present invention, since the fluid-liquid storage tank storing the simulated blood is connected to the feed pump, the intravenous injection and the blood sampling exercise can be performed even when there is no simulated blood producing device .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a vein injection and blood sampling simulator according to the present invention. FIG.
FIG. 2 is a conceptual view showing the intravenous injection and blood sampling simulator of the present invention. FIG.

Hereinafter, the intravenous injection and blood sampling simulator of the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, the intravenous injection and blood collection simulator according to the present invention includes: a simulated blood generator 20 for preparing and supplying a simulated blood corresponding to an actual blood; An arm or leg-shaped human body model 30 having a fluid tube 31 in which a simulated blood circulates, and a scan section 35 formed at one surface of the fluid tube 31 so as to pierce the needle with the fluid tube 31; A feed pump (11) for feeding the simulated blood prepared in the simulated blood generator (20) to the human body model (30); A flow meter 12 disposed between the manikin 30 and the feed pump 11 for measuring the amount of simulated blood supplied to the manikin 30; And a drain member installed between the manikin (30) and the flow meter (12) to discharge the simulated blood.

The human body model 30 is connected to both ends of the fluid tube 31 so that the simulated blood is supplied to the fluid tube 31 or the simulated blood of the fluid tube 31 is discharged to the outside, And a connection port 32 connected thereto. As a result, it is possible to supply the simulated blood to the fluid tube 31, which is a virtual blood vessel formed in the human body model 30, or to discharge the simulated blood remaining in the fluid tube 31, .

In addition, the injection unit 35 formed on the human body 30 is formed of silicone or the like that is relatively flexible as compared with other portions, so that it is preferable that the injection needle is easily pierced for intravenous injection or blood collection.

 The drain member is connected to one of the connection ports (32), one side is connected to the drain tank (14), the other side is connected to the drain tank (14) And a valve (13). Therefore, the simulated blood discharged from the human body 30 can be circulated to the feed pump 11 side through the return duct by using the three-way valve 13, and the simulated blood of the fluid tube 31 can be circulated through the drain tank (14).

At this time, the connection port 32 is preferably connected to the three-way valve 13 via the connection pipe 15, and it is further preferable that the connection port 32 and the connection pipe 15 are detachably coupled . The three-way valve 13 and the connection port 32 are connected to each other through the connection pipe 15 because they are difficult to be directly coupled as pipe connection ports. At this time, the connection port 32 and the connection pipe 15 are detachably coupled to each other so that the human body 30 can be replaced when the human body 30 is damaged.

In the above description, it is described that the simulated blood is directly supplied from the simulated blood maker 20. In some cases, the blood storage tank 16 storing the simulated blood is connected to the feed pump 11, So that the simulated blood of the human body 30 can circulate through the fluid tube 31 of the human body model 30. In this case, it is a matter of course that the blood storage tank 16 should be detachably connected to the simulated blood generator 20. Thus, the entire size of the product can be miniaturized, and the apparatus can be used even in a case where the simulated blood maker 20 is not provided.

The simulated blood maker 20 is for producing simulated blood simulating the color and viscosity of blood. The simulated blood maker 20 includes a distilled water tank 21 containing distilled water; A red tank 22 containing a red ink; A black tank 23 containing black ink; A gel tank (24) containing a gel component; A mixer (25) connected to each tank by a conduit to uniformly mix raw ingredients supplied from respective tanks; And a plurality of metering pumps 56, which are respectively installed in conduits connecting the respective tanks and the mixer 25 to regulate the amount of the raw material components supplied to the mixer 25.

Here, the mixer 25 is a type of stirrer that is provided with a rotatable stirring blade (not shown) therein and uniformly mixes raw material components supplied from respective tanks in accordance with the rotation of the stirring blades, The structure is not limited as long as it can be mixed.

The above-mentioned simulated blood includes distilled water corresponding to plasma in the blood, red ink and black ink used for controlling the degree of redness and blackness of the blood, and a gel component for indicating the viscosity of blood corresponding to the cholesterol in the blood. Are mixed and formed.

Specifically, the simulated blood is preferably formed by mixing 3 to 80% by weight of a red ink, 3 to 80% by weight of a black ink and 3 to 30% by weight of a gel component with respect to 100% by weight of distilled water, More preferably, the total amount of the black ink is 80 to 85% by weight.

If the amount of the red ink is less than 3% by weight, the quantity of the black ink becomes too large, and the blood of the simulated blood appears black, so that blood flowing through the artery can not be replicated. If the amount of the black ink exceeds 80% by weight, I can not simulate blood. Similarly, when the amount of the black ink is less than 3% by weight, the amount of the red ink becomes too large to replicate the blood flowing in the vein. When the amount of the black ink exceeds 80% by weight, To 3 to 80 wt%, respectively.

The reason why the sum of the red ink and the black ink is 80 to 85% by weight based on 100% by weight of the distilled water is that the ratio of plasma to blood cells in the blood is 55:45, will be.

When the gel component is less than 3% by weight, the viscosity of the blood can not be simulated. When the gel component exceeds 30% by weight, the viscosity becomes too high and the flow of the simulated blood is inhibited. %.

In addition, the gel component may be mixed at a ratio of 50 to 500 mg / dl to a mixture of distilled water, a red ink and a black ink. This is in response to the level of cholesterol contained in the blood, taking into account the fact that if the total cholesterol level is less than 200mg / dl, it is the 'normal value', and if it is more than 240mg / dl, the cholesterol is suspected.

Here, the red ink and the black ink correspond to the oxygen concentration in the blood, that is, the oxygen saturation (the ratio of the hemoglobin to the oxygen), and the hemoglobin (Hb) contained in the red blood cells and the hemoglobin When oxygen is contained and oxygen is contained in the solution at a certain concentration or more, the color of the solution can be simulated so that it appears as a color closer to red than that of black.

In order to transfer carbon dioxide into the lungs to simulate that carbon dioxide is bound to carbamino hemoglobin (HbCO ₂ ) in the human body, when oxygen becomes a certain concentration or less in the blood and the concentration of carbon dioxide becomes a certain concentration or more, Can be made to appear as a black color rather than a red color.

Therefore, when the blood flowing in the artery is simulated, the content of the red ink is increased, and when the blood flowing in the vein is simulated, the content of the black ink is increased. The gel component is a viscous substance, which simulates the viscosity of blood, and polyacrylic acid and the like can be used.

Further, it is more preferable to control the ratio of the red ink and the black ink constituting the simulated blood in consideration of the type of the blood through which the blood passes, the health condition of the patient, and the like.

That is, when blood of a healthy person containing oxygen or a certain concentration of oxygen in the blood passing through the artery or the like is replicated, the ratio of the red ink in the mixed ink is increased and oxygen in the blood or blood passing through the vein is set to a certain concentration And the blood of the unhealthy person is replicated, the ratio of the black ink in the mixed ink is increased.

In other words, the mixing ratio of the red ink and the black ink is adjusted so that the color of the blood becomes red as the oxygen concentration in the blood becomes closer to 100%, and as the oxygen concentration in the blood becomes closer to 0% And also to simulate the blood flowing through the artery or vein and to adjust the amount of the gel component to simulate the blood cholesterol level.

The simulated blood maker produces the simulated blood by uniformly mixing raw ingredients supplied from respective tanks.

A predetermined amount of infusion pump 26 provided in a pipeline connecting the distilled water tank 21 and the red tank 22, the black tank 23 and the gel tank 24 and the mixer 25 is used to separate The raw material components are supplied to the mixer 25 so that the raw material components are uniformly mixed by rotating the stirring wing in the mixer 25 so that 3 to 80 weight parts of the red ink corresponding to the color of blood % Of a black ink, 3 to 80% by weight of a black ink, and 3 to 30% by weight of a gel component which changes the viscosity of blood in response to cholesterol in the blood.

At this time, if the amount of the black ink supplied from the black tank 23 is increased, the blood of the varicose vein flowing in the vein of the blood vessel or the simulated blood corresponding to the blood of the patient whose oxygen in the blood is below a certain concentration can be formed, When the amount of the black ink supplied from the tank 23 is reduced and the amount of the red ink supplied from the red tank 22 is increased, the blood of the aneurysm flowing in the artery in the blood vessel or the blood of the healthy person Can be formed. In addition, by increasing the gel component supplied from the gel tank 24, a simulated blood corresponding to the blood of the hyperlipidemic patient can be formed.

The intravenous injection and blood collection simulator of the present invention configured as described above allows the intravenous injection and blood collection to be learned by using a human body model equipped with a fluid tube filled with simulated blood similar to actual blood, thereby improving the learning effect.

First, the simulated blood is prepared by using the simulated blood maker 20, and the simulated blood is supplied to the fluid tube 31 of the human body model 30 by the feed pump 11. The amount of the blood to be supplied to the fluid tube 31 is measured using the flow meter 12 located at the outlet side of the feed pump 11 so that the blood is not excessively injected into the fluid tube 31 Do not.

At this time, it is preferable that the three-way valve (13) is operated to communicate the fluid pipe (31) and the return pipe so that the simulated blood supplied from the feed pump (11) is circulated through the fluid pipe (31). In this state, the injection needle is inserted into the injection part 35 provided in the human body model 30, and the injection needle is inserted into the fluid pipe 31 through the injection part 35, And blood samples are taken out to perform blood sampling. Therefore, it is possible to perform the blood sampling exercise or the intravenous injection exercise using the simulated blood flowing along the fluid tube 31, and the learning effect is enhanced.

Here, it is preferable that the fluid tube 31 and the scan unit 35 are formed of a soft silicone material so that scan shots can be easily removed during practice of blood sampling or intravenous injection and leakage of the simulated blood is prevented.

On the other hand, when the intravenous injection and the blood sampling are completed, the three-way valve 13 is operated to allow the fluid tube 31 and the drain tank 14 to communicate with each other. Accordingly, the simulated blood in the fluid tube 31 is discharged to the drain tank 14, thereby preventing the contamination or damage of the human body model that may occur due to the remnant of the simulated blood in the fluid tube.

When the fluid tube 31 is damaged due to the progress of the intravenous injection and blood collection, and the human body model 30 can no longer be used, the connection tube 15 coupled to the connection port 32 is separated And the connection port 32 of the new human body model 30 is connected to the connector pipe 15, so that the human body model 30 is replaced and used. Therefore, the remainder of the body except for the human body model 30 can be reused.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be appreciated by those of ordinary skill in the art that numerous changes and modifications can be made to the present invention without departing from the scope of the present invention. And all such modifications and changes as fall within the scope of the present invention are therefore to be regarded as being within the scope of the present invention.

11 ... feed pump
12 ... Flowmeter
13 ... three-way valve
14 ... drain tank
15 ... connector
16 ... fluid storage tank
20 ... simulated blood maker
21 ... distilled water tank
22 ... Red tank
23 ... black tank
24 ... gel tank
30 ... human body model
31 ... fluid tube
32 ... connection port
35 ... scanning section

Claims (7)

A distilled water tank 21 containing distilled water, a red tank 22 containing a red ink, a black tank 23 containing black ink, a gel tank 24 containing a gel component, A simulated blood maker (20) which comprises a mixer (25) for mixing the components and supplies and supplies simulated blood corresponding to the blood;
(30) having a fluid tube (31) circulating a simulated blood therein and having a scanning part (35) formed at one surface thereof so as to pierce the needle with the fluid tube (31);
A feed pump (11) for feeding the simulated blood prepared in the simulated blood generator (20) to the human body model (30);
A flow meter 12 disposed between the manikin 30 and the feed pump 11 for measuring the amount of simulated blood supplied to the manikin 30;
And a drain member installed between the manikin (30) and the flow meter (12) for discharging simulated blood. The method according to claim 1,
The human body model 30 includes a connection port 32 having one end exposed to the outside at both ends of the fluid pipe 31 so that the simulated blood is supplied to the fluid pipe 31 or the simulated blood of the fluid pipe 31 is discharged to the outside. ) Are connected to each other. 3. The method of claim 2,
The drain member is connected to one of the connection ports (32), one side is connected to the drain tank (14), and the other side is connected to the drain tank (14) And a valve (13). The method of claim 3,
And the connection port (32) is connected to the three-way valve (13) via a connection pipe (15). 5. The method of claim 4,
Wherein the connection port (32) and the connection pipe (15) are detachably coupled to each other. 6. The method according to any one of claims 1 to 5,
The blood storage tank 16 storing the simulated blood is connected to the feed pump 11 so that the simulated blood of the blood storage tank 16 circulates the fluid tube 31 of the manikin 30,
Wherein the blood storage tank (16) is detachably connected to a simulated blood generator (20). The method according to claim 1,
The simulated blood of the simulated blood maker 20 comprises 3 to 80% by weight of a red ink, 3 to 80% by weight of a black ink and 3 to 30% by weight of a gel component, based on 100% by weight of distilled water. Injection and blood sampling simulator.

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