KR102881663B1 - Needle structure with hemostasis function - Google Patents

Abstract

The present invention relates to a needle structure capable of effectively delivering a hemostatic agent and a system for applying a hemostatic agent to the needle, and to minimize bleeding that may occur during examination or treatment of internal organs using a needle, thereby enabling safe and effective examination or treatment. A needle structure equipped with a hemostatic function according to an embodiment of the present invention includes a helical groove (directed in the same direction as a general screw) in the needle, and a hemostatic agent component is applied to the tip of the needle body, including the hemostatic groove in the needle body. The hemostatic agent applied to the needle may be lost during some of the insertion process, but the hemostatic agent in the hemostatic groove remains. After a certain period of time, muscles, etc. naturally contract, causing the hemostatic agent in the hemostatic groove to flow out. In particular, during the process of removing the needle, the hemostatic agent in the hemostatic groove is naturally pushed out, allowing the hemostatic agent to be applied to a necessary area.

Description

Needle structure with hemostasis function

The present invention relates to a needle structure equipped with a hemostatic function to prevent internal organ bleeding or leakage of cerebrospinal fluid, etc., that occurs when performing a biopsy or surgery on an internal organ of the human body or performing a lumbar puncture, etc.

Bleeding can occur during tissue biopsies or surgeries on internal organs, and cerebrospinal fluid (CSF) leakage can occur during lumbar punctures for anesthesia. However, since these bleeding and leakage occur within the body, it is difficult to provide appropriate external treatment. In some cases, a hemostatic agent can be applied to the needle. However, the hemostatic agent applied to the needle is often washed away by skin or muscles during the needle's entry into the body, rendering it ineffective on the actual organ. Consequently, the risk of bleeding and other issues remains when accessing internal organs with a needle. Therefore, there has been no effective, non-invasive treatment for needle-induced bleeding or CSF leakage. The background technology described above is intended solely to illustrate the background of the present invention and should not be construed as representing any previously known technology.

The present invention provides a needle structure equipped with a hemostatic agent that can effectively prevent bleeding or leakage of cerebrospinal fluid, etc., when accessing an organ using a needle by preventing the hemostatic agent component applied to the needle from being lost during the process of inserting the needle into the human body, thereby effectively delivering the hemostatic agent.

The present invention relates to a needle structure capable of effectively delivering a hemostatic agent and a system for applying a hemostatic agent to a needle, and is intended to minimize bleeding that may occur during examination or treatment of internal organs using a needle, thereby enabling safe and effective examination or treatment.

A needle structure equipped with a hemostatic function according to an embodiment of the present invention has a helical groove (directed like a normal screw) in the needle, and a hemostatic component is applied to the tip of the needle, including the groove in the needle.

When a needle coated with a hemostatic agent is inserted into the desired area, bleeding can be minimized by the hemostatic agent applied to the tip of the needle and the groove provided on the needle, allowing for safe and effective examination and treatment.

While the hemostatic agent applied to the needle may be lost during some of the insertion process, the hemostatic agent in the groove remains. After a certain period of time, the muscles naturally contract, causing the hemostatic agent in the groove to flow out. Furthermore, during the needle removal process, the hemostatic agent in the groove is naturally pushed out, allowing it to be applied to the necessary area.

A needle structure equipped with a hemostatic function according to an embodiment of the present invention is a needle structure equipped with a hemostatic function for preventing internal organ bleeding or cerebrospinal fluid leakage that occurs during a biopsy or surgery or lumbar puncture on an organ in the human body, and may include a medical needle having a needle body having a needle structure and a hemostatic groove provided on an outer surface of the needle body; and a hemostatic agent applied to the hemostatic groove to prevent bleeding or cerebrospinal fluid leakage during a biopsy or surgery or lumbar puncture on an organ.

The above hemostatic groove may be formed in a spiral shape along the outer circumference of the needle body.

The needle body may be made of a shape memory alloy in which the shape of the hemostatic groove changes depending on temperature. The needle structure equipped with a hemostatic function according to an embodiment of the present invention may be configured such that the hemostatic agent applied within the hemostatic groove flows out of the hemostatic groove within the human body according to the change in the shape of the hemostatic groove. The needle body may change shape so that the volume of the hemostatic groove decreases depending on the temperature of the human body.

According to an embodiment of the present invention, by preventing the loss of a hemostatic component applied to a needle during the process of inserting the needle into the human body, the hemostatic agent is effectively delivered, thereby effectively preventing bleeding or leakage of cerebrospinal fluid, etc., when accessing an organ using a needle, and minimizing bleeding or leakage of cerebrospinal fluid, etc., that may occur during examination or treatment of internal organs using a needle, thereby enabling safe and effective examination or treatment.

Figure 1 is a drawing showing a needle structure equipped with a hemostatic function according to an embodiment of the present invention.
FIG. 2 and FIG. 3 are drawings for explaining the use state and operational effect of a needle structure equipped with a hemostatic function according to an embodiment of the present invention.
Figure 4 is a cross-sectional view of a needle structure equipped with a hemostatic function according to another embodiment of the present invention.
Figures 5 and 6 are drawings for explaining the function and operational effect of the needle structure shown in Figure 4.

Since the embodiments described in this specification are intended to clearly explain the idea of the present invention to a person having ordinary skill in the art to which the present invention pertains, the present invention is not limited to the embodiments described in this specification, and the scope of the present invention should be interpreted to include modified or altered examples that do not depart from the idea of the present invention.

The terms used in this specification have been selected from widely used terms, taking into account the functions of the present invention. However, these terms may vary depending on the intentions of those skilled in the art, precedents, or the emergence of new technologies. However, if a specific term is defined and used with an arbitrary meaning, the meaning of that term will be described separately. Therefore, the terms used in this specification should be interpreted based on the actual meaning of the term and the overall content of this specification, rather than simply the name of the term.

The drawings attached to this specification are intended to facilitate explanation of the present invention, and the shapes depicted in the drawings may be exaggerated as necessary to help understanding of the present invention, and therefore the present invention is not limited by the drawings.

In this specification, if it is determined that a specific description of the configuration or function of a public notice related to the present invention may obscure the gist of the present invention, a detailed description thereof will be omitted as necessary.

The present invention relates to a needle structure capable of effectively delivering a hemostatic agent and a system for applying a hemostatic agent to a needle, and is intended to minimize bleeding or leakage that may occur during examination or treatment of internal organs using a needle, thereby enabling safe and effective examination or treatment.

Fig. 1 is a drawing showing a needle structure equipped with a hemostatic function according to an embodiment of the present invention. Figs. 2 and 3 are drawings for explaining the use state and operational effect of the needle structure equipped with a hemostatic function according to an embodiment of the present invention. Referring to Figs. 1 to 3, the needle structure (100) equipped with a hemostatic function according to an embodiment of the present invention has a hemostatic function for preventing internal organ bleeding or cerebrospinal fluid leakage that occurs during a tissue examination, surgery, or lumbar puncture on an internal organ (10) of the human body.

To this end, the needle structure (100) has a spiral groove in the needle body, and a hemostatic agent is applied to the tip of the needle body, including the hemostatic agent groove provided in the needle body. When the needle body to which the hemostatic agent has been applied is introduced into a desired area, bleeding can be minimized by the hemostatic agent applied to the hemostatic agent groove provided in the tip and outer surface of the needle body, thereby enabling safe and effective examination and treatment.

While the hemostatic agent applied to the needle body may be lost during some insertion processes, the hemostatic agent within the hemostatic groove remains. After a certain period of time, muscles naturally contract, causing the hemostatic agent within the hemostatic groove to flow out. Furthermore, during the needle body removal process, the hemostatic agent within the hemostatic groove is naturally pushed out, allowing it to be applied to the required area.

Hereinafter, a needle structure equipped with a hemostatic function according to an embodiment of the present invention will be described in more detail. The needle structure (100) may include a medical needle (110) having a needle body (112) having a needle structure, and a hemostatic groove (114) provided on the outer surface of the needle body (112); and a hemostatic agent (120) applied within the hemostatic groove (114) to prevent bleeding or leakage of cerebrospinal fluid during a biopsy or surgery on an organ (10) or a lumbar puncture. The hemostatic groove (114) may be formed in a spiral shape along the outer surface of the needle body (112). The hemostatic agent (120) may include a hemostatic component such as thrombin, fibrinogen, or tissue factor, for example, but the components of the hemostatic agent (120) applicable to the present invention are not limited to these examples.

Fig. 4 is a cross-sectional view of a needle structure equipped with a hemostatic function according to another embodiment of the present invention. Figs. 5 and 6 are drawings for explaining the function and operational effect of the needle structure illustrated in Fig. 4. The needle structure (100) illustrated in Figs. 4 and 6 differs from the previously described embodiment in that the needle body (112) is made of a shape memory alloy in which the shape of the hemostatic groove (114) changes depending on temperature.

The hemostatic agent (120) flows out from the hemostatic groove (114) inside the human body according to the change in shape of the hemostatic groove (114) due to the change in temperature during the process of inserting the needle body (112) into the human body. To this end, the shape of the needle body (112) can change so that the volume of the hemostatic groove (114) decreases according to the temperature of the human body. Since the method of manufacturing a material whose shape changes according to temperature using a shape memory alloy is already known, a detailed description thereof will be omitted so as not to obscure the gist of the present invention.

During the process of inserting the needle body (112), the temperature of the needle body (112) is lower than the reference temperature at which the shape of the shape memory alloy changes, and at this time, the space of the hemostatic groove (114) is not reduced, so that the hemostatic agent (120) is positioned within the hemostatic groove (114), as illustrated in FIG. 4. Therefore, during the process of inserting the needle structure (100) into the human body, the hemostatic agent (120) is not exposed to the outside of the hemostatic groove (114), so that the hemostatic agent (120) is not wiped off by the skin or internal organs of the human body.

When the needle body (112) is inserted into the human body, the temperature of the needle body (112) gradually rises due to body temperature, and when the temperature of the needle body (112) becomes higher than the reference temperature, the shape of the hemostatic groove (114) changes and the space of the hemostatic groove (114) shrinks. Accordingly, the hemostatic agent (120) located within the hemostatic groove (114) comes out of the hemostatic groove (114) as shown in FIGS. 5 and 6, and reacts with blood or cerebrospinal fluid, thereby performing a hemostatic function to prevent bleeding or leakage.

In the embodiment illustrated in FIG. 5, as the temperature of the needle body (112) rises, the bottom surface (114b) of the hemostatic groove (114) rises toward the outer surface of the needle body (112), thereby reducing the volume of the internal space of the hemostatic groove (114). Reference numeral 114a illustrated in FIG. 5 represents the hemostatic groove (114) before shape change, reference numeral 114b represents the bottom surface of the hemostatic groove (114) before shape change, reference numeral 114c represents the hemostatic groove (114) after shape change, and reference numeral 114d represents the bottom surface of the hemostatic groove (114) after shape change.

The hemostatic groove (114) before the shape change is formed with a first depth (H1) and a first width (W1) from the outer surface of the needle body (112). When the temperature changes as the needle body (112) made of a shape memory alloy is inserted into the human body, the shape of the needle body (112) is deformed, and accordingly, the depth of the hemostatic groove (114) from the outer surface of the needle body (112) is reduced from the first depth (H1) before the shape change to a second depth (H2) smaller than the first depth (H1). Accordingly, as the spatial volume of the hemostatic groove (114) is reduced, some of the hemostatic agent within the hemostatic groove (114) is discharged to the outside of the hemostatic groove (114), so that the amount of the hemostatic agent that reacts with blood or cerebrospinal fluid, etc. may increase.

Unlike the example of FIG. 5, the embodiment illustrated in FIG. 6 shows that the volume of the internal space of the hemostatic groove (114) is reduced in a manner that the horizontal width of the hemostatic groove (114) is reduced as the temperature of the needle body (112) rises. In the case of the embodiment illustrated in FIG. 6, as the temperature of the needle body (112) rises, the width (114c) of the hemostatic groove (114) is reduced, thereby reducing the volume of the internal space of the hemostatic groove (114).

In Fig. 6, reference numeral 114a denotes a hemostatic groove (114) before shape change, reference numeral 114b denotes the bottom of the hemostatic groove (114) before shape change, and reference numeral 114e denotes a hemostatic groove (114) after shape change. The hemostatic groove (114) before shape change is formed to have a size of a first width (W1) based on the outer circumferential direction of the needle body (112). When the needle body (112) made of a shape memory alloy is inserted into the human body and the temperature changes, the shape of the needle body (112) is deformed, and accordingly, the width of the hemostatic groove (114) is reduced from the first width (W1) before shape change to a second width (W2) smaller than the first width (W1) through shape change. Accordingly, as the spatial volume of the hemostatic groove (114) is reduced, some of the hemostatic agent within the hemostatic groove (114) may be discharged to the outside of the hemostatic groove (114), thereby increasing the amount of hemostatic agent that reacts with blood or cerebrospinal fluid.

FIGS. 5 and 6 merely illustrate examples of how the spatial volume of a hemostatic groove (114) within a human body is reduced by a shape change of a shape memory alloy. Therefore, the shape change of the hemostatic groove (114) according to the temperature of the shape memory alloy is not limited to the examples of FIGS. 5 and 6 and may be modified in various ways. For example, the shape of the hemostatic groove (114) within a human body may be changed so that both the depth and width are reduced.

In one embodiment of the present invention, the depth of the hemostatic groove (114) may be formed such that the depth (H1) from the outer surface of the needle body (112) becomes thinner in the direction toward the tip (112a) of the needle body (112). Accordingly, during the process of inserting the needle structure through the skin or organ of the human body, the hemostatic agent (120) that is partially wiped off by the skin or organ may be pushed to the rear side within the hemostatic groove (114) based on the needle insertion direction and may remain within the hemostatic groove (114). Thereafter, when the needle structure (100) is moved in the discharge direction, the hemostatic agent (120) located in the hemostatic groove (114) is pushed toward the tip (112a) of the needle structure (100) as it comes into contact with the skin or organ, and the depth of the hemostatic groove (114) becomes thinner in the direction toward the tip (112a) of the needle body (112), so that the hemostatic agent is effectively discharged to the outside of the hemostatic groove (114) through the hemostatic groove (114) near the tip (112a) of the needle body (112), thereby preventing bleeding or leakage.

Although the embodiments have been described with limited examples and drawings, those skilled in the art will appreciate that various modifications and variations can be made based on the above teachings. For example, appropriate results can be achieved even if the described techniques are performed in a different order than described, or if the components of the described systems, structures, devices, etc. are combined or combined in a different manner than described, or if they are replaced or substituted with other components or equivalents. Therefore, other implementations, other embodiments, and equivalents of the claims also fall within the scope of the claims described below.

10: Organs in the human body
100: Needle structure with hemostatic function
110: Medical needles
112: Needle body
112a: The tip of the needle body
114: Hemostatic Home
114a: Hemostatic home before shape change
114b: Bottom of the hemostatic groove before shape change
114c, 114e: Hemostatic groove after shape change
114d: Bottom surface of hemostatic groove after shape change
120: Hemostatic agent
H1: Depth of the hemostatic groove before shape change
H2: Depth of hemostatic groove after shape change
W1: Width of the hemostatic groove before shape change
W2: Width of the hemostatic groove after shape change

Claims (5)

A needle structure equipped with a hemostatic function to prevent internal organ bleeding or cerebrospinal fluid leakage that occurs during tissue examination, surgery, or lumbar puncture of an internal organ of the human body.
A medical needle having a needle body having a needle structure and a hemostatic groove provided on the outer surface of the needle body; and
Including a hemostatic agent applied within the hemostatic groove to prevent bleeding or cerebrospinal fluid leakage during a biopsy or surgery on an organ or a lumbar puncture;
The above needle body is made of a shape memory alloy in which the shape of the hemostatic groove changes depending on the temperature.
The hemostatic agent applied within the hemostatic groove is configured to flow out of the hemostatic groove within the human body according to a change in the shape of the hemostatic groove.
A needle structure equipped with a hemostatic function. In claim 1,
The above hemostatic groove is formed in a spiral shape along the outer surface of the needle body.
A needle structure equipped with a hemostatic function. delete A needle structure equipped with a hemostatic function to prevent internal organ bleeding or cerebrospinal fluid leakage that occurs during tissue examination, surgery, or lumbar puncture of an internal organ of the human body.
A medical needle having a needle body having a needle structure and a hemostatic groove provided on the outer surface of the needle body; and
Including a hemostatic agent applied within the hemostatic groove to prevent bleeding or cerebrospinal fluid leakage during a biopsy or surgery on an organ or a lumbar puncture;
The above needle body is made of a shape memory alloy in which the shape of the hemostatic groove changes depending on the temperature.
The hemostatic agent applied within the hemostatic groove is configured to flow out of the hemostatic groove within the human body according to a change in the shape of the hemostatic groove.
The above needle body is a needle structure equipped with a hemostatic function, the shape of which changes so that the volume of the hemostatic agent groove decreases depending on the temperature of the human body. In claim 1,
A needle structure equipped with a hemostatic function, wherein the hemostatic groove is formed so that the depth from the outer surface of the needle body becomes thinner as it moves toward the tip of the needle body.