KR20220040236A - Apparatus for treatment of submucosal tissue equipped with motion detection sensor - Google Patents

Abstract

According to an embodiment of the present invention, a treatment device for a submucosal tissue includes: a probe member including a head portion accessing a mucous membrane of a treatment site, and a body portion connected to the head portion; an electrode installed in the head portion and applying an electrical signal to a blood vessel of the submucosal tissue of the mucous membrane; a motion detection sensor installed in the head portion and sensing an operation of the head portion; and a control unit connected to the body portion and controlling an output of the electric signal according to the operation of the head portion detected by the motion detection sensor. The present invention can prevent burns, and provides the treatment device for the submucosal tissue with improved hygienic and economic efficiency.

Description

Treatment device for submucosal tissue with motion detection sensor

The present invention relates to a device for treating submucosal tissue provided with a motion sensor, and more particularly, includes a motion detection sensor capable of adjusting the output of an electrical signal by detecting a movement motion of a head in which an electrode for applying an electrical signal is installed. It relates to a device for the treatment of submucosal tissue.

The mucous membrane of the body refers to the inner wall of a mid-cavity organ that is in direct contact with the outside, such as a respiratory organ, a digestive organ, a genitourinary system, and the like. More specifically, the mucous membranes of the body may be classified into oral mucosa, nasal mucosa, pharyngeal mucosa, bronchial mucosa, vaginal mucosa, glans mucosa, urethral mucosa, anal mucosa, and the like according to location.

These mucosal and submucosal tissues can be damaged as a result of the inflammatory response. Aging, dry environment, physical damage from repeated friction, and chemical exposure increase the inflammatory response of mucous membranes and submucosal tissues, and activate the proteolytic system of the extracellular matrix. Phagocytes released into tissues through blood vessels cause inflammation and release matrix metalloproteinase (MMP). These MMPs degrade collagen and elastomeric molecules after the inflammatory process. MMP-1 decomposes collagen I and collagen III, while MMP-12 causes the most active decomposition action on elastic cells. Excessive collagen and elastomer degradation results in flaccid and elongation of mucosal tissues.

On the other hand, various diseases or abnormal symptoms may occur in the mucous membrane, and appropriate treatment should be performed according to the symptoms. As one of the symptoms of abnormalities in the mucous membrane of the body, there is vaginal laxity in which the vaginal mucosa in women is stretched. The vaginal mucosa in women is composed of a flexible tissue, but when sexual intercourse and childbirth are repeatedly performed, the vaginal mucosa gradually stretches, reducing elasticity and friction, and contractility decreases. As such, when the contractility of the vaginal mucosa is lowered, the pressure and friction during sexual intercourse are reduced, and thus sexual pleasure is reduced, as well as the problem of urinary incontinence or self-confidence, thereby experiencing psychological atrophy.

Since the elongation of the vaginal mucosa is related to the formation of new blood vessels in the vaginal submucosal tissue, it may help to maintain the contractility of the vaginal mucosa by early suppressing the excessive production of new blood vessels. However, there are few studies on a technique for treating vaginal abnormalities (vaginal laxity) by acting on the blood vessels of the vaginal submucosal tissue.

An object of the present invention is to provide an apparatus for treating submucosal tissue that can prevent burns, and is hygienic and economical.

An apparatus for treating submucosal tissue according to an embodiment of the present invention includes: a probe member including a head part accessing the mucous membrane of a treatment site, and a body part connected to the head part; an electrode installed in the head and applying an electrical signal to the blood vessels of the submucosal tissue of the mucosa; a motion detection sensor installed in the head unit and configured to detect an operation of the head unit; and a controller connected to the main body and configured to adjust the output of the electric signal according to the operation of the head sensed by the motion sensor.

It is installed on the main body and further includes a driving motor for rotating the head, the driving motor may be controlled by the control unit.

It is installed on the main body portion may further include a direction indicating portion for indicating the rotation direction of the head portion.

The head part and the main body part may be detachable.

Further comprising an electrical coupling portion comprising an electrical coupling plate installed on the electrical coupling pin, and the head portion is installed in the body portion, the electrical coupling pin is inserted into the electrical coupling groove of the electrical coupling plate to be electrically coupled can

It may further include a detachable part for attaching and detaching the head part and the main body part, and the detachable part may include a hook part installed in the body part, and a hook part installed in the head part and coupled to the hook part.

The motion detection sensor may include a gyro sensor or an acceleration sensor.

a guide member accommodating the probe member to be selectively rotatably and linearly movable, and for guiding the position of the electrode with respect to the mucous membrane of the treatment site; And it may further include a movement guide for guiding the rotation and linear movement of the probe member with respect to the guide member.

In the apparatus for treating submucosal tissue according to an embodiment of the present invention, a motion sensor for detecting the motion of the head is installed in the head, and a driving motor for rotating the head is installed in the main body, thereby rotating and linear movement of electrodes Since the position of the electrode can be changed by detecting

In addition, by manufacturing the head portion and the body portion of the probe member in a detachable manner, only the head portion in which the electrode is installed can be replaced, which is hygienic and economical.

1 is a schematic perspective view of an apparatus for treating submucosal tissue according to an embodiment of the present invention.
FIG. 2 is a front view of the apparatus for treating submucosal tissue of FIG. 1 in a state in which the head part and the body part are separated.
3 is a rear view illustrating a state in which a head portion and a main body portion of the submucosal tissue treatment device of FIG. 1 are separated.
FIG. 4 is a cross-sectional view of FIG. 1 .
5 and 6 are views illustrating an operation state of a detachable part of the apparatus for treating submucosal tissue according to an embodiment of the present invention.
7 is a cross-sectional view illustrating a state in which the guide member of the apparatus for treating submucosal tissue according to an embodiment of the present invention is installed in the head part and the main body part.
8 is an enlarged perspective view of a guide member and a movement guide of the apparatus for treating submucosal tissue according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

1 is a schematic perspective view of an apparatus for treating submucosal tissue according to an embodiment of the present invention, FIG. 2 is a front view of the apparatus for treating submucosal tissue of FIG. 1 in a state in which the head and body are separated, and FIG. 3 is 1 is a rear view of the apparatus for treating submucosal tissue in a state in which the head part and the body part are separated, and FIG. 4 is a cross-sectional view of FIG. 1 .

1 to 4 , the apparatus for treating submucosal tissue according to an embodiment of the present invention includes a probe member 100 , an electrode 200 , a motion detection sensor 300 , a driving motor 400 , and a control unit. 500 , a direction indicating unit 600 , an electrical coupling unit 710 , a detachable unit 720 , a guide member 800 , and a movement guide unit 900 .

The probe member 100 may include a head unit 110 that accesses the mucous membrane of the treatment site, and a body unit 120 connected to the head unit 110 .

The head part 110 is formed at the end of the body part 120 to have a larger size than the body part 120 , and may enter the vagina and contact the vaginal mucosa. The shape and structure of the head part 110 may be variously changed according to required conditions and design specifications. Preferably, when the head part 110 is inserted into the body, the outer surface of the head part 110 may be formed in a curved shape to minimize damage to the mucous membrane. For example, the head part 110 may be formed in an elliptical shape. In this way, by forming the head part 110 in an oval shape similar to the body entrance, the entrance of the head part 110 toward the inside of the body can be performed more easily, and the head part 110 enters the inside of the body. It can reduce the pressure applied to the patient when necessary, thereby obtaining a beneficial effect of enabling mucosal treatment in a more comfortable environment. In some cases, it is also possible to form the head portion 110 in a spherical shape, or to form a mortar shape with a concave central portion or other geometric shapes.

The body part 120 may be formed in a rod shape having a predetermined length. As an example, the main body 120 may be a straight circular rod having a circular cross-section. In some cases, the body part 120 may be formed to have an elliptical or polygonal cross-sectional shape. Alternatively, it is also possible to form the body part 120 in a bent shape, or to configure the body part by combining two or more members.

The body part 120 is preferably formed to have a sufficient length and thickness to be easily gripped and manipulated by an operator, and the present invention is not limited or limited by the length and thickness of the body part 120 .

The electrode 200 is installed in the head unit 110 and can treat a disease of the submucosal tissue by applying an electric signal to the blood vessels of the submucosal tissue of the mucous membrane. Here, the electrode 200 is in contact with the mucous membrane and the application of the electrical signal is defined as applying the electrical signal to the blood vessels of the submucosal tissue in order to improve the disease or abnormality of the mucous membrane, and depends on the type and characteristics of the electrical signal. The present invention is not limited or limited by the As an example, the electrode 200 may be configured to apply radio frequency (RF) energy to the vaginal mucosa. In some cases, it is also possible that the electrode 200 is configured to apply another type of energy, such as microwave or ultrasound. As the electrode 200 , a conventional monopolar electrode 200 or a bipolar electrode 200 may be used, and the present invention is not limited or limited by the type of the electrode 200 .

The electrode 200 may be a monopolar electrode or a bipolar electrode, and a pair of electrodes may be formed by splitting the electrode in two and placing an insulator in the middle, or splitting the electrode into two or more plural by placing an insulator in between, such as splitting a watermelon. By forming a pair of electrodes, one electrode may act as a (+) electrode and an adjacent electrode may be configured as a (-) electrode to exhibit polarity. Also, the electrical signal applied from the electrode 200 may be an AC electrical signal. The alternating current electrical signal has a property of effectively inducing a thermal coagulation reaction in blood vessels in the treated tissue. Alternatively, the electrical signal applied from the electrode 200 may be a direct current electrical signal. The direct current electrical signal helps to deliver a substance such as a drug into the tissue to be treated or has a property of destroying the tissue. Preferably, the electrical signal applied from the electrode 200 has a frequency of 0.3 ~ 300Mhz. More preferably, the electrical signal applied from the electrode 200 has a frequency of 0.5 to 10 Mhz. Most preferably, the electrical signal applied from the electrode 200 has a frequency of 0.5 to 3 Mhz. As such, by making the electrical signal applied from the electrode 200 have a frequency of 0.3 to 300 Mhz, an appropriate thermal reaction may be generated in the blood vessels of the submucosal tissue, which is a cause or aggravation factor.

The outer surface of the electrode 200 may have a spherical curved surface, and an electric signal may be radiated through the curved surface in a radial shape. The electrode 200 may be formed of a material having excellent electrical conductivity and excellent thermal conductivity, and the material of the electrode 200 may be variously changed according to required conditions. For example, the electrode 200 may be formed of stainless steel, copper, aluminum, gold, silver, or the like.

The motion detection sensor 300 is installed on the head unit 110 and may detect the operation of the head unit 110 . That is, the motion detection sensor 300 may detect whether the electrode 200 installed in the head unit 110 is rotated or moved in a straight line. The motion detection sensor 300 may include a gyro sensor or an acceleration sensor.

The driving motor 400 is installed in the main body 120 and can rotate the head 110 . The driving motor 400 may be controlled by the controller 500 .

The control unit 500 is connected to the body unit 120 and may adjust the output of the electric signal according to the operation of the head unit 110 detected by the motion detection sensor 300 . That is, the control unit 500 reads data regarding the operation of the head unit 110 sensed by the motion detection sensor 300 and determines the rotation and linear movement of the electrode 200 to adjust the output of the electrical signal. .

Accordingly, when the motion of the head unit 110 on which the electrode 200 is installed is not detected, the motion detection sensor 300 transmits it to the control unit 500 to stop the output of the electrical signal to prevent burns of the mucous membrane. Also, the control unit 500 may drive the driving motor 400 to rotate the head unit 110 in which the electrode 200 is installed. Therefore, it is possible to accurately irradiate the electric signal to the mucous membrane of the treatment site by adjusting the position of the electrode 200 .

The direction indicator 600 is installed on the main body 120 and may indicate the rotation direction of the head 110 . Since the exact rotation angle of the electrode 200 can be known using the direction indicator 600 , the rotation angle of the electrode 200 can be accurately adjusted. The direction indicator 600 may be implemented as a liquid crystal display, but is not necessarily limited thereto and may be implemented in various structures.

Conventionally, when inserting the probe member 100 into the mucous membrane of the treatment site for a procedure, since the operator cannot visually check the probe member, the treatment is performed by rotating and linear movement of the probe member by hand. In other words, when the part inserted into the human body (head part) and the part that is not inserted into the human body (body part) by the operator's hand are rotated integrally, the angle of rotation of the probe member arbitrarily without the operator's eye And since the depth of the linear movement must be adjusted, it is not easy to accurately control the rotation angle and the depth of the linear movement of the probe member. Therefore, if the operator does not pay attention or lacks experience, the previously treated treatment area may not be re-treated or moved at an appropriate time, leading to a risk of burns.

However, in the apparatus for treating submucosal tissue according to an embodiment of the present invention, a motion detection sensor 300 for detecting the operation of the head 110 is installed in the head 110 , and the head part ( By including the driving motor 400 for rotating the 110, only the head part 110 can be configured to be able to rotate in a state where the body part 120 held by the operator's hand does not move. Therefore, since the position of the electrode 200 can be changed by sensing the rotation and linear movement of the electrode 200, it is possible to prevent continuous irradiation of high-frequency signals to the mucous membrane at the same location due to the operator's carelessness to prevent burns of the mucous membrane. can

Meanwhile, the head part 110 and the body part 120 are detachable. To this end, an electrical coupling part 710 and a detachable part 720 may be installed in the head part 110 and the body part 120 . The electrical coupling part 710 allows the head part 110 and the body part 120 to be electrically detachable from each other, and the detachable part 720 is the head part 110 and the body part 120 physically detachable from each other. to do it

First, the electrical coupling portion 710 may include an electrical coupling pin 711 installed on the body portion 120, and an electrical coupling plate 712 installed on the head portion (110). The electrical coupling pin 711 may be electrically coupled by being inserted into the electrical coupling groove of the electrical coupling plate 712 .

Therefore, the electrical coupling unit 710 can be easily turned on and off electrically with the head unit 110 and the body unit 120 when the head unit 110 and the body unit 120 are detachable from each other. . The electrical coupling unit 710 may have a pogo pin structure, but is not limited thereto, and various structures are possible.

5 and 6 are views illustrating an operation state of a detachable part of the apparatus for treating submucosal tissue according to an embodiment of the present invention;

5 and 6 , the detachable unit 720 may physically detach the head unit 110 and the body unit 120 from each other.

The detachable part 720 may include a hook part 721 installed on the body part 120 and a hook part 722 installed on the head part 110 and coupled to the hook part 721 .

As shown in FIG. 5 , the hook-shaped end of the hook part 721 is fixed to the locking part 722 , so that the body part 120 and the head part 110 may be physically coupled to each other. And, as shown in FIG. 6, by reversing the switch connected to the hook-shaped end of the hook portion 721, the hook-shaped end is separated from the engaging portion 722, and the body portion 120 and the head portion 110. can be physically separated from each other.

In this way, by manufacturing the head portion 110 and the body portion 120 of the probe member 100 in a detachable manner, only the head portion 110 in which the electrode 200 is installed can be replaced, which is hygienic and economical.

7 is a cross-sectional view illustrating a state in which the guide member of the apparatus for treating submucosal tissue according to an embodiment of the present invention is installed in the head part and the main body part, and FIG. 8 is an apparatus for treating submucosal tissue according to an embodiment of the present invention. It is an enlarged perspective view of the guide member and the movement guide of

7 and 8, the guide member 800 is accommodated so that the probe member 100 can be selectively rotated and moved in a straight line, and can guide the position of the electrode 200 with respect to the mucous membrane of the treatment site. . The guide member 800 is fixed in position with respect to the mucous membrane, and the probe member 100 may be selectively rotatably accommodated in the guide member 800 . As described above, by fixing the position of the guide member 800 with respect to the mucous membrane and allowing the probe member 100 to rotate with respect to the guide member 800 , the electrode 200 mounted on the probe member 100 becomes vaginal. Even if it is inserted inside and covered, the operator can recognize the position of the electrode 200 with respect to the guide member 800 .

The guide member 800 includes a guide body portion 810 having a first accommodating hole 812 in which the probe member 100 is rotatably accommodated, and the first accommodating hole 812 communicating with the probe member 100 . A second accommodating hole 822 in which the is rotatably accommodated is formed and may include an expansion guide part 820 integrally expanded and formed in the guide body part 810 . Preferably, the expansion guide part 820 is formed to have a cross-sectional area that is expanded from a proximal end adjacent to the guide body part 810 to a distal end. For example, the expansion guide part 820 may be formed to have a sectional area gradually expanded from one end to the other, like a trumpet shape. In this case, the expansion guide part 820 may be formed in a circular shape, a polygonal shape, or an elliptical shape, and the present invention is not limited or limited by the shape and structure of the expansion guide part 820 . Preferably, the expansion guide portion 820 may be formed in a size that can be fixed from the outside of the vaginal entrance (size that can be hung from the outside of the vaginal entrance).

The reference position display unit 802 may be formed in the form of a protrusion or a recessed groove on the outer surface of the guide member 800 . The rotational position of the electrode 200 with respect to the mucous membrane may be controlled based on the reference position display unit 802 .

The movement guide unit 900 may guide rotation and linear movement of the probe member with respect to the guide member 800 . Here, guiding the linear movement of the probe member 100 with respect to the guide member 800 means that while the probe member 100 moves along the linear movement path with respect to the guide member 800, the linear movement path is deviated. It is defined as suppressing the movement of the probe member 100 and guiding the probe member 100 to move only along a linear movement path. In addition, guiding the rotation of the probe member 100 with respect to the guide member 800 suppresses a shift in the rotation center of the probe member 100 with respect to the guide member 800, and rotation of the probe member 100 It is defined as keeping the center constant.

The movement guide unit 900 may be configured to guide rotation and linear movement of the probe member 100 with respect to the guide member 800 in various ways according to required conditions and design specifications.

As an example, the movement guide unit 900 includes a guide groove 930 formed in the probe member 100 and a guide protrusion 830 formed in the guide member 800 to be movable along the guide groove 930. may include

In a state in which the guide protrusion 830 is accommodated in the guide groove 930, the movement of the guide protrusion 830 to the outside of the guide groove 930 is suppressed, so the rotation of the probe member 100 with respect to the guide member 800 and It can guide linear movement. In addition, an entry groove 936 may be formed in the body portion 120 of the probe member 100 to communicate with the guide groove 930 , and the guide protrusion 830 may pass through the entry groove 936 to the guide groove 930 . ) is entered. For example, the entry groove 936 may be formed in a straight shape along the length direction of the probe member 100 . In some cases, it is also possible to form the entry groove in a curved shape or inclined to the longitudinal direction of the probe member.

More specifically, the guide groove 930 includes a straight guide groove 932 formed on the outer surface of the body part 120 along the longitudinal direction of the body part 120 of the probe member 100, and a straight guide groove ( It communicates with the 132 and may include a rotation guide groove 934 formed on the outer surface of the body portion 120 along the circumferential direction of the body portion (120).

While the guide protrusion 830 is moving along the linear guide groove 932 , the linear movement of the probe member 100 with respect to the guide member 800 is guided, and the guide protrusion 830 rotates along the guide groove 934 . During movement, the rotation of the probe member 100 with respect to the guide member 800 may be guided. Preferably, a plurality of rotation guide grooves 934 are provided to be spaced apart from each other in the longitudinal direction of the probe member 100 , and each rotation guide groove 934 may communicate with the straight guide groove 932 .

The straight guide groove 932 includes a first section guide groove 932a formed between a pair of adjacent ones of the plurality of rotation guide grooves 934 and the other one adjacent to each other among the plurality of rotation guide grooves 934 . It is formed between the pair and may include a second section guide groove 932b disposed on the same line as the first section guide groove 932a along the longitudinal direction of the probe member 100 .

In this way, by making the first section guide groove 932a and the second section guide groove 932b constituting the straight guide groove 932 arranged on the same line with each other, the guide protrusion 830 is the first section guide After moving along the groove 932a, it can enter the second section guide groove 932b directly. That is, the guide protrusion 830 moves along a linear movement path passing through the first section guide groove 932a → the second section guide groove 932b. Depending on the condition of the patient, it may be difficult to perform treatment with the electrode 200 on a specific site (eg, a wound site) of the mucous membrane. Accordingly, by allowing the linear movement of the probe member 100 with respect to the guide member 800 to be continuously performed in the first section guide groove 932a and the second section guide groove 932b, the electrode ( 200) can pass more quickly, and thus, advantageous effects of shortening the treatment time and increasing the treatment efficiency can be obtained.

However, the positions of the first section guide groove 932a and the second section guide groove 932b are not necessarily limited thereto, and the first section guide groove 932a and the second section guide groove 932b are on different lines from each other. By being disposed in the guide member 800 so that the linear movement of the probe member 100 with respect to the guide member 800 is performed step by step as much as the spacing between each rotation guide groove 934, increasing treatment efficiency and improving the safety and convenience of treatment Examples are also possible.

In addition, a restraining groove 938 in which the guide protrusion 830 is accommodated and temporarily restrained may be formed in the guide groove 930 . For example, the restraining groove 938 may be formed in a hemispherical shape in which the guide protrusion 830 can be selectively accommodated or withdrawn. In a state in which the guide protrusion 830 is accommodated in the restraining groove 938 , the arrangement state of the guide protrusion 830 is restrained without an external force (operator's operating force) being applied to the probe member 100 . On the other hand, when an external force is applied to the probe member 100 while the guide protrusion 830 is accommodated in the restraining groove 938 , the guide protrusion 830 comes out of the restraining groove 938 . In this way, by forming the constraint groove 938 in the guide groove 930, the operator can feel a feeling of operation when the probe member 100 is manipulated, and the position of the electrode 200 with respect to the mucous membrane is visually recognized. (For example, recognizing the position of the electrode 200 with respect to the reference position display unit 802) and tactile (sound and shock felt when the guide protrusion 830 is accommodated or drawn out in the restraining groove 938) ) to make it recognizable. For example, the restraining grooves 938 may be formed to be spaced apart along the circumferential direction of the main body 120 . Preferably, the constraining grooves 938 may be formed to be spaced apart from each other at equal intervals along the circumferential direction of the main body 120 .

Although the present disclosure has been described through preferred embodiments as described above, the present invention is not limited thereto, and various modifications and variations are possible without departing from the scope of the claims set forth below. Those in the field will understand easily.

100: probe member 110: head portion
120: body part 200: electrode
300: motion detection sensor 400: drive motor
500: control unit 600: direction indicating unit
710: electrical coupling unit 720: removable unit
800: guide member 900: movement guide unit

Claims (8)

a probe member including a head portion accessing the mucous membrane of the treatment site, and a body portion connected to the head portion;
an electrode installed in the head and applying an electrical signal to the blood vessels of the submucosal tissue of the mucosa;
a motion detection sensor installed in the head unit and configured to detect an operation of the head unit; and
A control unit connected to the main body and controlling the output of the electric signal according to the operation of the head unit detected by the motion detection sensor
A treatment device for submucosal tissue comprising a. The method of claim 1,
A driving motor installed in the main body and rotating the head
further comprising,
The drive motor is a submucosal tissue treatment device controlled by the control unit. 3. The method of claim 2,
A direction indicating part installed on the main body and indicating the rotation direction of the head part
Submucosal tissue treatment device further comprising a. According to claim 1,
The head part and the main body part are removable submucosal tissue treatment apparatus. 5. The method of claim 4,
Electrical coupling pins installed in the body portion, and
Further comprising an electrical coupling unit comprising an electrical coupling plate installed in the head,
The electrical coupling pin is inserted into the electrical coupling groove of the electrical coupling plate is electrically coupled to the submucosal tissue treatment device. 5. The method of claim 4,
A detachable part for attaching and detaching the head part and the main body part
further comprising,
The detachable part
a hook part installed in the body part; and
A locking part installed in the head part and coupled to the hook part
A treatment device for submucosal tissue comprising a. According to claim 1,
The motion detection sensor is a submucosal tissue treatment device including a gyro sensor or an acceleration sensor. According to claim 1,
a guide member accommodating the probe member to be selectively rotatable and linearly movable, and for guiding the position of the electrode with respect to the treatment site mucosa; and
A movement guide unit for guiding rotation and linear movement of the probe member with respect to the guide member
Submucosal tissue treatment device further comprising a.

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