KR102137709B1 - Endotracheal intubation tube with flexible in region of body temperature - Google Patents

Abstract

Tubes for tracheal intubation are provided. A tube for tracheal intubation according to an embodiment of the present application is a tube inserted into an airway, and is provided to surround a side surface of the hollow tube 10 and the tube 10, and an endothelial material having a ductility change in a body temperature region (20) and an envelope (30) surrounding the side of the endothelium (20), wherein the endothelium (20) is a glass transition state (Glassy Transition State), a rubber flat state (Rubbery Plateau State) and a high temperature region. It may be made of a material that exists in any one of the free flow state.

Description

Tube for flexible tracheal intubation in the body temperature area{ENDOTRACHEAL INTUBATION TUBE WITH FLEXIBLE IN REGION OF BODY TEMPERATURE}

The present application relates to a tube for tracheal intubation exhibiting flexibility in the body temperature region.

Tracheal intubation tube refers to a tube inserted into the airway to secure the airway. Since the tongue is rolled up in the direction of blocking the airway in patients who are unconscious or unconscious, the tube that continuously secures the airway must be inserted and maintained, and the tracheal intubation tube is intubated through the nasal cavity or the oral cavity. It is inserted up to the part.

The material of the tracheal intubation tube has a rigidity of a certain strength or more to maintain the shape of the tube, so that the operator must be able to support the force of pushing the tube into the airway, so it can be intubated smoothly without unnecessary bending in an emergency. However, due to the rigidity of the tracheal intubation tube, in the case of a patient who uses the intubation tube for a long period of time, a constant and intensive pressure is applied to the portion in contact with the tube (FIG. 1 ). This can interfere with blood circulation in the area and cause tissue weakness and even tissue cell necrosis.

Therefore, there is a need for an organ intubation tube that does not have any side effects such as tissue necrosis during long intubation, while smooth intubation is possible without bending during intubation.

Korean Registered Patent Document No. 10-14920233 (2015.02.04) Japanese Patent Publication No. 2016-527024 (2016.09.08)

The present application relates to a tube for tracheal intubation, which has strength to enable smooth intubation without bending during intubation, but does not cause side effects such as tissue necrosis even during long-term intubation due to change in ductility in the body temperature region.

One embodiment of the present application for solving the above problems is a tube inserted into the airway, is provided to surround the side of the hollow tube 10, the tube 10, the ductility changes in the body temperature region It includes a material endothelium 20 and an envelope 30 surrounding a side surface of the endothelium 20, wherein the endothelium 20 is a glass transition state in a body temperature region (Glassy Transition State), a rubber flat state (Rubbery Plateau State) It provides a tube for tracheal intubation, made of a material present in any one of a) and a rubbery flow state.

In one embodiment, the endothelium 20 may be made of a material having an elastic modulus value of 0.3 GPa or less in the body temperature region.

In one embodiment, the endothelium 20 may be thicker than the envelope 30.

In one embodiment, the sheath 30 may be made of a material having a Yield Strength value of 1450 psi or more and 3600 psi or less.

In one embodiment, the portion of the tube that comes into contact with the tissue of the object to be inserted may be deformed to have a shape corresponding to the abutting tissue.

In addition, the present application is a tube that is inserted into the airway, has a size that can surround the hollow tube 10 and the tube 10, and includes a holder 40 detachably mounted to the tube 10 And, the holder 40 is provided to surround the side surface of the hollow first envelope 41, the first envelope 41, the endothelium 42 and the endothelium of a material whose ductility changes in the body temperature region ( It includes a second envelope 43 surrounding the side of the 42, the endothelial 42 is a glass transition state (Glassy Transition State), rubber flat state (Rubbery Plateau State) and rubbery fluid state (Rubbery) in the body temperature region It provides a tube for tracheal intubation, which is made of a material existing in any one of flow states.

In one embodiment, the endothelium 42 extends from the first portion 41a to the second portion 42a facing the first portion 41a to surround the side surface of the first envelope 41. , The thickness may be thicker as it is farther from the first portion 41a.

In one embodiment, the endothelium 42 may be made of a material having an elastic modulus value of 0.3 GPa or less in the body temperature region.

In one embodiment, the holder 40 may have a length of 8cm to 10cm.

In one embodiment, the holder 40 may be mounted in the position of the tube 10 corresponding to the tongue portion after the front teeth of the object to be inserted.

In one embodiment, the tube 10 may be formed with a pair of protrusions 11 and 12 for fixing the position of the holder 40 with respect to the tube 10.

In one embodiment, the first sheath 41 and the second sheath 43 may be made of a material having a yield strength value of 1450 psi or more and 3600 psi or less.

In one embodiment, the portion of the holder 40 that comes into contact with the tissue of the object to be inserted may be deformed to have a shape corresponding to the abutting tissue.

In addition, the present application is a tube inserted into the airway, the hollow tube 10, the second part facing the first part 13 from the first part 13 to surround the side of the tube 10 ( It extends to 14), and includes an endothelial 50 of a material whose ductility changes in the body temperature region and an outer shell 60 surrounding a side surface of the endothelial 50, wherein the endothelial 50 is the first portion 13 ), the thicker the endothelium 50, the endothelium 50 exists in any one of the glass transition state, rubbery plateau state, and rubbery flow state in the body temperature region A tube for tracheal intubation made of a material.

In one embodiment, the endothelial 50 may be made of a material having an elastic modulus value of 0.3 GPa or less in the body temperature region.

In one embodiment, the sheath 60 may be made of a material having a Yield Strength value of 1450 psi or more and 3600 psi or less.

In one embodiment, the portion of the tube that comes into contact with the tissue of the object to be inserted may be deformed to have a shape corresponding to the abutting tissue.

According to the present application, since the load applied to the tissue in contact with the tube is distributed by including the endothelium in which the ductility changes in the body temperature region, problems such as necrosis of the tissue in contact with the tube are conventionally solved even during long tube intubation.

In addition, the outer skin surrounding the endothelial is made of a material having a certain strength or higher, and thus, during intubation, the operator can sustain the force of pushing the tube into the airway, and thus can be intubated smoothly without unnecessary bending in an emergency.

Various embodiments are possible. By using the holder 40 detachably mounted on the tube 10 to place the holder 40 only in the portion where the load is concentrated, cost reduction is possible, and of the endothelial 50 corresponding to the portion where the load is concentrated. By designing the thickness to be the thickest, it is possible to maximize the effect of load distribution by maximizing the contact surface with the tissue.

1 is a cross-sectional view for explaining a tube for conventional tracheal intubation.
2 is a schematic perspective view of a tube 100A for tracheal intubation in the first embodiment.
3 is a cross-sectional view taken along line AA in FIG. 2.
4 is a cross-sectional view for describing the shape of the tube 100A for tracheal intubation in the body temperature region.
5 is a graph for explaining the thermal properties of the polymer.
6 is a schematic perspective view of a second embodiment tracheal intubation tube 100B.
7 is a cross-sectional view (a) taken along line AA in FIG. 6 and a cross-sectional view taken along line BB (b).
8 is a cross-sectional view for explaining a portion where the load is concentrated when the tube for intubation is inserted.
9 is a sectional view of a tube 100C for intubation of a third embodiment.

Hereinafter, the term "body temperature region" means the body temperature of the object to be inserted, and when the object to be inserted is a human body, the body temperature region may be 35°C to 40°C, and specifically, 36°C to 38°C day Can.

Hereinafter, the term "object to be inserted" means an object into which a tube for tracheal intubation is inserted. When targeting the human body, the human body may correspond to this.

With reference to the accompanying drawings, a tube for tracheal intubation according to an embodiment of the present application will be described in detail.

1. The first Example

First, referring to Figures 2 to 5 will be described in detail the tube 100A for intubation according to the first embodiment of the present application. FIG. 2 is a schematic perspective view of a tube 100A for tracheal intubation in a first embodiment, FIG. 3 is a cross-sectional view taken along line AA in FIG. 2, and FIG. 4 shows the shape of the tube 100A for tracheal intubation in the body temperature region. It is a sectional view for explaining, and FIG. 5 is a graph for explaining the thermal properties of the polymer.

2 is a schematic perspective view of a tube 100A for tracheal intubation in the first embodiment. Referring to Figure 2, the tube 100A for tracheal intubation according to the first embodiment of the present application has a tubular shape as a whole, and is located outside the first end 110 and the object to be inserted in the airway of the object to be inserted It is located and includes a second end 120 which is connected to an oxygen supply, such as a medical gas supply, anesthesia, oxygen supply, ventilator and ventilator. Specifically, a cap 200 is mounted on the second end 120, and an oxygen supply device such as a medical gas supply device, an anesthetic device, an oxygen supply device, an aeration device, and a ventilator may be connected to the cap 200.

3 is a cross-sectional view taken along line A-A in FIG. 2. Referring to FIG. 3, the first embodiment tracheal intubation tube 100A includes a tube 10, an endothelial 20, and an outer sheath 30 from the inside to the outside.

The tube 10 may be the same material as that used in the tube for conventional tracheal intubation, and as an embodiment, a PVC (Poly Vinyl Chloride) material may correspond to this.

The endothelium 20 is provided to surround the side surface of the tube 10, and may be made of a material whose ductility changes in the body temperature region. Specifically, the endothelium 20 has flexibility in the body temperature region, and as shown in FIG. 4, may be made of a material that maximizes a contact surface in contact with the tissue of the object to be inserted. More specifically, it may be made of a material that exists in any one of a glass transition state, a rubbery plateau state, and a rubbery flow state in a body temperature region.

5, the thermal properties of the polymer will be described in detail. Unlike general molecules, polymers have unique thermal properties because monomers are long connected, and according to temperature, they exist in any one of the following five states.

"Glassy State" is a hard and fragile state, in which polymers in this state can only vibrate and rotate at short distances.

The term "Glassy Transition State" means that the elastic modulus decreases rapidly as the temperature rises, and unlike the glass state, it starts a long-range molecular motion, so that the apparently hard material becomes somewhat flexible, and sudden changes in many properties It is a result.

"Rubbery Plateau State" means that the diffusion of molecules becomes more active, and the elastic modulus decreases gradually as the temperature increases in the case of a thermoplastic resin, and the elastic modulus constant value as the temperature increases in the case of a thermosetting resin. It is in a state to keep.

"Rubbery Flow State" refers to a state in which molecular motion is very active and large scale full-scale parallel movement is possible. The polymer material in this state depends on the experiment time according to the experimental conditions, and the rubber elasticity is observed according to the experiment of the short experiment time, and the double-sided property of the flowability is observed according to the experiment of the long experiment time.

"Liquid state" refers to a state that has a complete liquid-like flow, such as a fluid.

Here, the endothelium 20 exists in a glass state at room temperature, but any one of a glass transition state, a rubbery plateau state, and a rubbery fluid state in the body temperature region It is desirable to exist in one state to exhibit flexibility, and as a result, the shape of the tube 100A, which comes into contact with the tissue of the object to be inserted, has a shape corresponding to that of the abutting tissue, as shown in FIG. 4. By dispersing the pressure applied to the tissue, it is possible to prevent side effects such as tissue necrosis due to long-term intubation tube maintenance.

Specifically, the endothelium 30 may be made of a material having an elastic modulus value of 0.3 GPa or less in the body temperature region, for example, one selected from the group consisting of PCL (PolyCaproLactone), gelatin, and hydrogel. One can be applied. When the material of the endothelium 30 has a modulus of elasticity greater than 0.3 GPa, it may not have sufficient flexibility in the body temperature region, and pressure may be concentrated on the abutting portion when maintaining the intubation tube for a long time, resulting in problems such as tissue necrosis.

The outer shell 30 is a portion surrounding the side surface of the inner shell 20, and is a portion forming the outer portion of the tube 100A. When the tube (100A) is inserted into the airway, it comes into contact with the tissue of the object to be inserted, and the tube (100A) may be made of a material having a certain strength or more so that it can be inserted without unnecessary bending during the insertion process, and the endothelial (20 ) May be made of a material having a certain degree of flexibility so that the shape can be changed by reflecting the shape deformation in the body temperature region.

The outer cover 30 may be provided to be thinner than the inner cover 20, so that even if the outer cover 30 is made of a material having a predetermined strength or higher, it is possible to reflect the shape deformation of the inner cover 20 in the body temperature region. Specifically, the outer cover 30 may be made of a material having a value of yield strength of 1450 psi or more and 3600 psi or less, and for example, a flexible PVC material may be applied.

2. The second Example

6 and 7, the tube 100B for tracheal intubation according to the second embodiment of the present application will be described in detail. FIG. 6 is a schematic perspective view of a tube 100B for tracheal intubation in a second embodiment, and FIG. 7 is a cross-sectional view (a) along line A-A and a cross-sectional view (b) along line B-B in FIG. 6.

The first difference is that the parts corresponding to the inner skin 20 and the outer skin 30 of the tube 100A for intubation of the trachea are provided as separate holders 40 and detachably mounted to the tube 10. to be.

When a long-term airway is secured by inserting a tube for tracheal intubation, the tongue portion (about 8 cm to 10 cm) after the front teeth is continuously pressured by the tube, as shown in FIG. 8.

Therefore, rather than surrounding the entire tube with the endothelial 20 and the outer sheath 30, it would be more cost effective if the endothelial 20 and the outer sheath 30 are configured only in the portion where the pressure is concentrated.

The second embodiment tracheal intubation tube (100B) is a holder 40 having a length of about 8cm to 10cm is inserted into the tube 10, the inner diameter of the holder 40 is designed to correspond to the outer diameter of the tube 10 When it is mounted on the tube 10, it may be such that a separate space does not exist between the tube 10 and the holder 40.

Referring to FIG. 7, the holder 40 includes a hollow first sheath 41, an endothelial 42, and a second sheath 43.

The first sheath 41 is a portion in contact with the tube 10 and may be made of the same material as the sheath 30 of the tube 100A in the first embodiment. That is, the first sheath 41 may be made of a material having a value of Yield Strength of 1450 psi or more and 3600 psi or less, and for example, a flexible PVC material may be applied.

The endothelium 42 is a portion surrounding the side surface of the first envelope 41 and may be made of the same material as the endothelium 10 of the first embodiment tube 100A. That is, the endothelial 42 exists in a glassy state at room temperature, but any one of a glassy transition state, a rubbery plateau state, and a rubbery flow state in the body temperature region. It may be made of a material having flexibility in one state, and specifically, may be made of a material having an elastic modulus value of 0.3 GPa or less in the body temperature region, for example, PCL (PolyCaproLactone), gelatin, and hydrogel. Any one selected from the group consisting of (Hydrogel) may be applied.

In addition, the endothelium 42 can extend in both directions from the first portion 41a of the first envelope 41 to the second portion 41b facing it, like the endothelium 50 of the third embodiment described below. However, the thickness may be thicker toward the second portion 41b. That is, the thickness of the endothelium 42 is the thinnest in the first portion 41a of the first envelope 41, and the second portion 41b facing it may be the thickest.

The second shell 43 is a portion surrounding the side surface of the inner shell 42, and may be made of the same material as the outer shell 30 of the tube 100A of the first embodiment. That is, the second sheath 43 may be made of a material having a value of yield strength of 1450 psi or more and 3600 psi or less, and for example, a flexible PVC material may be applied. In addition, as in the first embodiment, the second sheath 43 is provided thinner than the endothelial 42 so that the tube 100B can be inserted without unnecessary bending during the insertion process, and may be made of a material having a certain strength or higher, It may have a certain degree of flexibility so that the shape can be changed by reflecting the shape deformation in the body temperature region of the endothelium 42.

The inner diameter of the holder 40 is provided to correspond to the outer diameter of the pipe 10 (preferably the same) and mounted on the pipe 10 in a tight fit manner, however, in order to provide a more improved fixing force, that is, the holder 40 ) In order to fix the position with respect to the tube 10, the protrusions 11 and 12 may be protruded on the tube 10. The spacing of the protrusions 11 and 12 may be the same as the length of the holder 40, and only a pair of protrusions 11 and 12 are shown in FIG. 6, but several pairs of protrusions are provided, so that different anatomy is different for each object to be inserted. It is possible to fix the holder 40 to the tube 10 by fully reflecting the enemy structure.

3. Third Example

Referring to Figure 9, the tube 100C for intubation according to the third embodiment of the present application will be described in detail. 9 is a sectional view of a tube 100C for intubation of a third embodiment.

The third embodiment tracheal intubation tube (100C) is characterized in that the thickness of the endothelium 50 surrounding the tube 10 is not constant.

Referring to FIG. 9, the endothelium 50 of the third embodiment tube 100C extends in both directions from the first part 13 to the second part 14 to surround the side surface of the tube 10. Here, the thickness of the endothelial 50, the first portion 13 is the thinnest, the second portion 14 may be the thickest, more specifically, the first portion 13 toward the second portion 14 The thicker it can be, the better. That is, as the distance from the first portion 13 increases, the thickness of the endothelium 50 may increase.

This is based on the fact that only a certain surface of the tube 100C for intubation of the trachea comes into contact with the tissue of the object to be inserted, and when the second end 14 with a thick endothelial 50 is in contact with the tissue of the object to be inserted, intubation is performed. Compared to the first and second embodiments, the contact surface between the tube 100C and the tissue is maximized, so that the effect of load distribution can also be maximized.

The endothelium 50 may be made of the same material as the endothelium 10, 42 of the first and second exemplary tubes 100A, 100B. That is, the endothelium 50 exists in a glass state at room temperature, but any one of a glass transition state, a rubbery plateau state, and a rubbery fluid state in the body temperature region It may be made of a material having flexibility in one state, and specifically, may be made of a material having an elastic modulus value of 0.3 GPa or less in the body temperature region, for example, PCL (PolyCaproLactone), gelatin, and hydrogel. Any one selected from the group consisting of (Hydrogel) may be applied.

The outer shell 60 is a portion surrounding the side surface of the inner shell 50, and may be made of the same material as the outer shells 30, 41 and 43 of the first and second embodiment tubes 100A and 100B. That is, the sheath 60 may be made of a material having a value of yield strength of 1450 psi or more and 3600 psi or less, and for example, a flexible PVC material may be applied. In addition, as in the first and second embodiments, the outer shell 60 is made thinner than the inner shell 50 so that the tube 100C can be inserted without unnecessary bending during the insertion process, and is made of a material having a certain strength or higher. It may have a certain degree of flexibility so that its shape can be changed by reflecting the shape deformation in the body temperature region of the endothelium 50.

As described above, the present specification has been described with reference to embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present application, but this is merely exemplary, and those skilled in the art can make various modifications and equivalents from the embodiments of the present application. It will be understood that embodiments are possible. Therefore, the protection scope of the present application should be defined by the claims.

10: tube
20: endothelium
30: envelope
40: holder
41: first envelope
42: endothelium
43: second envelope
50: endothelium
60: envelope
100: tube
110: first end
120: second end
200: cap

Claims (17)

delete delete delete delete delete A tube inserted into the airway,
Hollow tube 10; And
It includes a holder 40 having a size capable of surrounding the tube 10 and detachably mounted to the tube 10.
The holder 40,
A hollow first envelope 41;
An inner shell 42 of a material provided to surround the side surface of the first outer shell 41 and having a ductility change in a body temperature region; And
Includes; second envelope 43 surrounding the side of the endothelial 42;
The endothelial 42 is made of a material that exists in any one of a glass transition state, a rubbery plateau state, and a rubbery flow state in the body temperature region,
Tube for tracheal intubation.
The method of claim 6,
The endothelial 42 extends from the first portion 41a to the second portion 42a facing the first portion 41a so as to surround the side surface of the first envelope 41, the thickness of which is the first The farther from the 1 part (41a), the thicker,
Tube for tracheal intubation.
The method of claim 6,
The endothelial 42 is made of a material having an elastic modulus value of 0.3 GPa or less in the body temperature region,
Tube for tracheal intubation.
The method of claim 8,
The holder 40 has a length of 8cm to 10cm,
Tube for tracheal intubation.
The method of claim 9,
The holder 40 is mounted at the position of the tube 10 corresponding to the tongue portion after the front teeth of the object to be inserted,
Tube for tracheal intubation.
The method of claim 10,
In the tube 10, a pair of protrusions 11 and 12 for fixing the position of the holder 40 with respect to the tube 10 is formed,
Tube for tracheal intubation.
The method of claim 6,
The first sheath 41 and the second sheath 43 are made of a material having a yield strength value of 1450 psi or more and 3600 psi or less,
Tube for tracheal intubation.
The method according to any one of claims 6 to 12,
The portion of the holder 40 that comes into contact with the tissue of the object to be inserted is deformed so as to have a shape corresponding to the abutting tissue,
Tube for tracheal intubation.
A tube inserted into the airway,
Hollow tube 10;
An endothelial (50) of material extending from the first portion (13) to the second portion (14) facing the first portion (13) so as to surround the side surface of the tube (10), the ductility of which varies in the body temperature region ; And
Includes; outer shell 60 surrounding the side of the endothelial 50;
The endothelial 50 is thicker as it is farther from the first portion 13 and closer to the second portion 14,
The second portion 14 is intubated to contact the tissue of the object to be inserted,
The endothelial 50 is made of a material present in any one of a glass transition state (Glassy Transition State), a rubber flat state (Rubbery Plateau State) and a rubbery fluid state (Rubbery flow State) in the body temperature region,
Tube for tracheal intubation.

The method of claim 14,
The endothelial 50 is made of a material having an elastic modulus value of 0.3 GPa or less in the body temperature region,
Tube for tracheal intubation.
The method of claim 15,
The shell 60 is made of a material having a yield strength value of 1450 psi or more and 3600 psi or less,
Tube for tracheal intubation.
The method according to any one of claims 14 to 16,
The portion of the tube that comes into contact with the tissue of the object to be inserted is deformed to have a shape corresponding to that of the abutting tissue,
Tube for tracheal intubation.

Images