KR102515703B1 - Negative Pressure Wound Therapy Apparatus - Google Patents

Abstract

Negative Pressure Wound Therapy can determine the current state of the wound by installing a device that can measure the acidity of the exudate in the canister that receives and collects the exudate from the wound from the NPWT (Negative Pressure Wound Therapy) equipment. There is an effect that the doctor treating the wound can easily judge the wound based on more accurate information about the wound and start treatment.
The present invention has the effect of providing a basis for objectively determining the condition of the wound even during non-face-to-face treatment later using the wound acidity value.

Description

Negative Pressure Wound Therapy Apparatus}

The present invention relates to a negative pressure wound treatment device, and more particularly, by installing a device capable of measuring the acidity of exudate in a canister that receives and collects exudate from a wound in NPWT (Negative Pressure Wound Therapy) equipment to determine the current state of the wound. It relates to a negative pressure wound treatment device capable of determining.

Various types of wounds occur in clinical medicine, and accordingly, efforts are being made to treat the wounds with various types of methods.

Unlike acute wounds, chronic wounds such as bedsores, diabetic ulcers, and foot ulcers are difficult to achieve complete healing despite the development of various treatment methods, so surgical treatment is considered the best.

Patients with chronic wounds often have a relatively short operation time because they have a large amount of blood loss or cannot endure long-term anesthesia. In this case, a process of making the shape of the wound into a form that can be healed is required. Wound treatment to achieve this purpose is currently used as a useful method of negative pressure wound treatment (Negative Pressure Wound Therapy).

In particular, in the case of bedsore patients, it is not easy to visit a hospital where pressure ulcer treatment and local negative pressure treatment (Vacuum Assisted Closure) are available, such as a university hospital, due to poor mobility, and it is difficult to determine the state of the wound in a nursing hospital. There were limitations in determining the disinfection time or disinfection method.

Korean Patent Publication No. 10-2017-0043953

In order to solve this problem, the present invention is to determine the current state of the wound by installing a device capable of measuring the acidity of the exudate in a canister that receives and collects the exudate from the wound in NPWT (Negative Pressure Wound Therapy) equipment. Its purpose is to provide a negative pressure wound treatment device that can be used.

Negative pressure wound treatment device according to the features of the present invention for achieving the above object,

A wound pad attached to a wound to seal it and a tube adapter coupled thereto;

a tube having one side connected to the tube adapter to transfer the negative pressure provided from the negative pressure pump to the wound site;

a canister having one side connected to the tube to suck in and store the exudate removed from the wound; and

A main body connected to the canister and provided with the negative pressure pump to provide negative pressure to the wound site;

A sensor unit for measuring acidity (pH) of the exudate may be provided in an inner space of the canister, and the main body may display the measured acidity on a display unit.

According to the configuration described above, the present invention has an effect that the doctor treating the wound can easily determine the wound based on more accurate information about the wound and start treatment using the wound acidity value.

The present invention has the effect of providing a basis for objectively determining the condition of the wound even during non-face-to-face treatment later using the wound acidity value.

The present invention has the effect of providing an environment in which efficient wound care by a wound nurse can be made in a nursing hospital.

The present invention has the advantage of being able to easily apply a simple acidity measuring device while maintaining the excellence of existing NPWT products.

1 is a diagram showing the configuration of a negative pressure wound treatment device according to a first embodiment of the present invention.
2 is a diagram showing a configuration device connected to a control unit according to a first embodiment of the present invention.
3 is a diagram showing the configuration of an optical fiber sensor unit among an example of a sensor unit according to a first embodiment of the present invention.
4 is a view showing how exudate is accommodated in the canister via the optical fiber sensor unit according to the first embodiment of the present invention.
5 is a view showing the configuration of a vertical movement device installed inside a canister according to a second embodiment of the present invention.
6 is a diagram showing a configuration device connected to a control unit according to a second embodiment of the present invention.
7 is a diagram illustrating an interlocking relationship between a plurality of negative pressure wound treatment devices and a hospital server according to an embodiment of the present invention.

Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

In addition to judging the wound by looking at the state of the wound itself, there are various indicators that can indirectly determine the state of the wound.

Among these, the simplest and most useful way to measure is to measure the acidity (pH) of a wound. Chronic wounds have higher wound healing power when acidity is closer to neutrality, and wounds do not heal well as acidity progresses to alkalinity, and may have various sequelae.

Measuring the acidity (pH) of a wound can be an indicator for determining wound healing. The present invention is to install a device capable of measuring the acidity of the exudate in a canister that receives and collects the exudate of the wound used in the NPWT equipment, so that the current state of the wound can be determined.

1 is a diagram showing the configuration of a negative pressure wound treatment device according to a first embodiment of the present invention, and FIG. 2 is a diagram showing a configuration device connected to a control unit according to a first embodiment of the present invention.

According to the first embodiment of the present invention, the negative pressure wound treatment device 100 includes a main body 110, a canister 120, a wound pad 131 attached to and sealed at a wound site in the patient's body 10, and a tube ( 130) and a tube adapter 132.

The main body 110 is a case that accommodates the electronic components of the negative pressure wound treatment device 100 therein, and includes a display unit 111, a control unit 112, a negative pressure pump 113, and a sensor unit 117 therein. .

A power switch (not shown) and a control button (not shown) for adjusting the intensity of the sound pressure generated by the negative pressure pump 113 are formed on the front of the main body 110 .

The display unit 111 outputs various information related to the operation of the negative pressure wound treatment device 100 .

The negative pressure pump 113 is a device for generating negative pressure, and transfers the generated negative pressure to the canister 120 through the negative pressure passage 113a. Here, the negative pressure generated by the negative pressure pump 113 is a state of atmospheric pressure lower than atmospheric pressure (760 mmHg).

The canister 120 is connected to the negative pressure passage 113a of the negative pressure pump 113 to form negative pressure through the air intake 121 .

The tube 130 is made of a flexible material and has one side connected to the coupling part 133 at the inlet side of the canister 120 and the other side connected to the tube adapter 132 .

The negative pressure generated by the negative pressure pump 113 passes through the canister 120, the coupling part 133, and the tube 130, and through the through hole (not shown) of the tube adapter 132, the wound pad 131 and the patient's wound delivered to the part.

The negative pressure generated by the negative pressure pump 113 is transmitted to the wound site of the patient through the wound pad 131 while the wound pad 131 is attached to the wound site of the patient.

The exudate discharged from the wound site is sucked into the canister 120 through the tube adapter 132 and the tube 130 and received therein.

The canister 120 is made of a transparent material so that exudate generated from the wound can be observed from the outside, and a scale (50ml, 100ml, etc.) is formed on the outer surface to indicate the amount of exudate.

A sensor unit 117 for measuring acidity (pH) of the exudate may be provided in the inner space of the canister 120 . The control unit 112 receives the acidity of the exudate measured by the sensor unit 117 and controls the display unit 111 to be displayed.

The results of measuring the pH of 247 chronically wounded wounds ranged from 5.43 to 8.65. In other studies, well-healed wounds have an average pH of 6.91 and poorly healed wounds have an average pH of 7.42.

Acidity (pH) can vary depending on the disease and stage of wound healing. Overall, it is judged that it is appropriate to maintain the pH at a maximum level of 6.8 to 7.2 in the wound treatment step, and it can be determined that the wound does not heal well when the pH is 7.2 or higher.

When the measured acidity is within a first predetermined range (pH 6.8 to 7.2), the control unit 112 determines that the wound at the wound site is being healed well, and when it is greater than or equal to a predetermined reference value (pH 7.2), at the wound site. It is judged that the wound does not heal well.

When the measured acidity is within a predetermined first range, the control unit 112 generates a first control signal indicating a wound healing state and displays it on the display unit 111, and when the measured acidity is equal to or greater than a predetermined reference value, A second control signal representing a state in which wound healing is not performed is generated and displayed on the display unit 111 .

When the measured acidity is pH 6.8 to 7.2, the display unit 111 displays the value in blue on the display unit 111, and when the measured acidity is pH 7.2 or higher, the display unit 111 displays the value in red along with the value. control to display.

The control unit 112 may display the colors on the display unit 111 differently according to the acidity value.

The controller 112 may change the values of the first range and the reference value because acidity may vary according to disease and wound treatment stages.

The sensor unit 117 includes a biosensor (not shown) that senses the acidity of the exudate by measuring the current value generated by causing oxidation and reduction reactions on the electrode, and a sensor (not shown) composed of a reagent layer containing an enzyme that reacts to the sample. Si), optical fiber sensor unit 140, etc., any device can be used as long as it is a device that senses the acidity of the exudate.

Although the present invention exemplifies the optical fiber sensor unit 140 as an example of the sensor unit 117, it is not limited thereto and may include any device capable of measuring the acidity of exudate. Hereinafter, the configuration of the optical fiber sensor unit 140 of one example of the sensor unit will be described in detail with reference to FIG. 3 .

3 is a diagram showing the configuration of an optical fiber sensor unit among an example of a sensor unit according to a first embodiment of the present invention.

As shown in FIG. 3, the optical fiber sensor unit 140 according to an embodiment of the present invention includes a sensing film 141, an optical fiber 142, a circulator 143, a light source unit 145, and a photodetector 147. include

The sensing film 141 protrudes on the air inlet 121 corresponding to the inlet of the canister 120, and when the exudate discharged from the wound passes through the tube 130 and is sucked into the canister 120, contact It is located on the aisle where it can be done.

The optical fiber 142 is composed of a core (not shown) and a clad (not shown) surrounding the core, and forms a sensing film 141 formed at an end such that the core is more exposed than the clad.

The circulator 143 transmits the light emitted from the light source unit 145 and transmitted through the input optical fiber 144 to the optical fiber 142, passes through the sensing film 141, and then transmits the light in the reverse direction through the optical fiber 142. The light to be transmitted is transmitted to the output optical fiber 146.

The sensing film 141 is formed at the end of the optical fiber 141, and is formed of a phosphor film in which a fluorescent dye is solidified in a core exposed to the end of the optical fiber 141 and an oxidase film on the phosphor film.

The oxidase film reacts with the fluorescent dye and the exudate (blood components as secretions from the affected area) of the test subject.

The light source unit 145 is a light emitting diode that emits blue light of a central wavelength, and emits light to the sensing film 141 through the input optical fiber 144 and the optical fiber 141 .

The photodetector 147 detects and transmits the reaction light generated when the oxidase film of the sensing film 141 reacts with the exudate is transmitted through the optical fiber 141 and the output optical fiber 146 to the control unit 112. .

The control unit 112 calculates the acidity of the exudate of the wound area to be measured from the light detected by the photodetector 147 and outputs the calculated acidity to the display unit 111 .

The controller 112 may calculate the acidity of the affected area using a lookup table in which acidity values corresponding to the detected light have been previously measured and recorded through experiments.

4 is a view showing how exudate is accommodated in the canister via the optical fiber sensor unit according to the first embodiment of the present invention.

As shown in FIG. 4 , the exudate discharged from the wound is introduced into the air inlet 121 of the canister 120 through the tube 130 and the coupling part 133 and is accommodated in the inner space of the canister 120. . At this time, the exudate moves into the inner space of the canister 120 while contacting the sensing film 141 of the optical fiber sensor unit 140 disposed between the coupling part 133 and the air inlet 121 . The optical fiber sensor unit 140 senses the acidity of the exudate.

In FIG. 5 , an example in which the optical fiber sensor unit 140 is located inside the canister 120 will be described.

5 is a view showing the configuration of a vertical movement device installed inside a canister according to a second embodiment of the present invention.

A vertical moving member 150 having an optical fiber sensor unit 140 is installed in the inner space of the canister 120 .

In the vertical movement device 150 according to the second embodiment of the present invention, a first support 152 having a predetermined shape is formed on the inner bottom surface of the canister 120, and a predetermined distance is formed on the ceiling surface from the first support 152. A shaped second support 151 is formed, and a screw member 153 having a predetermined length is connected between the first support 152 and the second support 151 .

The inner space of the second support 151 includes a second driven gear 155 , a driving gear 156 , and a driving motor 158 .

Inside the second support 151, the driven gear 155 is gear-engaged with the drive gear 156, the center of the drive gear 156 is coupled to the rotation shaft 157, and the rotation shaft 157 has a drive motor ( 158).

One end of the screw member 153 penetrates the second support 151 and is coupled to the driven gear 155 disposed in the inner space, and the other end is coupled to the first support 152 to allow the inside of the canister 120 It stands vertically in space.

As the screw member 153 rotates, the driven gear 155 coupled to one end is rotated, and the other end is rotated inside the first support 152.

The screw member 153 penetrates the hexahedron-shaped moving member 154 in the vertical direction and is coupled thereto.

The movable member 154 forms a certain space therein, and reciprocates vertically on the screw member 153 according to the rotation of the screw member 153 .

As an example of the sensor unit 117, an optical fiber sensor unit 140 is provided in the inner space of the moving member 154, and the sensing film 141 extends to the outside of the moving member 154 and is exposed.

The screw member 153 has a circular cross-section and a screw thread is formed on the outer surface, and the screw thread is in contact with a screw groove formed on the inner surface of the moving member 154.

A screw groove engaged with a screw thread formed on an outer circumferential surface of the screw member 153 is formed on the inner surface of the moving member 154 .

A sensing film 141 protrudes from one side of the moving member 154 to the outside.

The inside of the moving member 154 includes an optical fiber 142, which is an internal device of the optical fiber sensor unit 140, a circulator 143, a light source unit 145, and a photodetector 147.

The screw member 153 linearly moves the movable member 154 connected to the screw member 153 in the vertical direction while being rotated by the driving motor 158 .

The moving member 154 converts the rotational motion of the screw member 153 into linear motion, and rises or descends according to the forward or reverse direction of the rotational motion of the screw member 153.

As the driving motor 158 is driven, the driven gear 155 and the driving gear 156 are rotated, and thus the screw member 153 is rotated in one direction.

As the moving member 154 rotates, the sensing film 141 coupled to the moving member 154 is also moved while linearly moving in an up and down direction from one end of the screw member 153 to the other end of the screw member 153 as the screw member 153 rotates. .

6 is a diagram showing a configuration device connected to a control unit according to a second embodiment of the present invention.

The controller 112 of the second embodiment of the present invention includes a display unit 111, a negative pressure pump 113, a pressure sensor 114, a level sensor 115, a wireless communication unit 116, a sensor unit 117, and a drive motor. It is electrically connected to (158).

A pressure sensor 114 for measuring the pressure inside the canister 120 is installed in the inner space of the canister 120, and a level sensor 115 for detecting the level of the exudate indicating the remaining amount of exudate is installed.

The control unit 112 receives the pressure value inside the canister 120 from the pressure sensor 114 and receives the level value of the exudate from the level sensor 115 .

The control unit 112 calculates distance information by determining to what level the internal space of the canister 120 is filled with exudate based on the pressure value and the level value. Here, the distance information corresponding to the pressure value and the level value uses a look-up table previously measured and recorded through an experiment.

The control unit 112 generates a driving control signal of the driving motor 158 according to the calculated distance information and transmits it to the driving motor 158 . As the driving motor 158 is driven, the driving gear 156 and the driven gear 155 are rotated, and as the screw member 153 rotates, the sensing film 141 coupled to the moving member 154 releases exudate. It is moved in a downward direction to contact.

The sensor unit 117 constitutes the optical fiber sensor unit 140 as shown in FIG. 3 .

The control unit 112 may transmit the acidity value measured by the optical fiber sensor unit 140 to the hospital server 200 through the communication network 101 through the wireless communication unit 116 together with location information and personal information.

7 is a diagram illustrating an interlocking relationship between a plurality of negative pressure wound treatment devices and a hospital server according to an embodiment of the present invention.

Each negative pressure wound treatment device 100 measures the acidity of the exudate and transmits the measured acidity value to the hospital server 200 via the wireless communication unit 116 via the communication network 101 .

The hospital server 200 matches the acidity value of the exudate, date, time, disease type, and personal information for each individual and creates a database.

Using data collected from the hospital server 200, the treating doctor can easily determine the wound based on more accurate information about the wound and start treatment.

The present invention has the effect of providing a basis for objectively determining the condition of the wound even during non-face-to-face treatment later using the wound acidity value.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also included in the scope of the present invention. that fall within the scope of the right.

100: negative pressure wound treatment device
110: main body
111: display unit
112: control unit
113: negative pressure pump
117: sensor unit
120: canister
130: tube
131 Wound pad
132: tube adapter
140: optical fiber sensor unit

Claims (6)

A wound pad attached to a wound to seal it and a tube adapter coupled thereto;
a tube having one side connected to the tube adapter to transfer the negative pressure provided from the negative pressure pump to the wound site;
a canister having one side connected to the tube to suck in and store the exudate removed from the wound; and
A main body connected to the canister and provided with the negative pressure pump to control the negative pressure to be provided to the wound,
A sensor unit for measuring acidity (pH) of the exudate is provided in the inner space of the canister, and the main body displays the measured acidity on a display unit,
A vertical movement device to which the sensor unit is coupled is formed in the inner space of the canister, and the vertical movement device has a screw member of a certain length erected vertically, and is composed of a gear and a motor at one end of the screw member and driven by the motor. The screw member rotates in one direction,
The screw member is coupled by penetrating a movable member of a predetermined shape in the vertical direction, and the sensor unit is coupled to one side of the movable member to move the sensor unit along with the movable member according to the rotation of the screw member to contact the exudate. Negative pressure wound care device. The method of claim 1,
The main body generates a first control signal indicating a wound healing state when the measured acidity is within a predetermined first range and displays the first control signal on the display unit, and when the measured acidity is equal to or greater than a predetermined reference value, the wound A negative pressure wound treatment device for generating a second control signal indicating a non-treatment condition and displaying the second control signal on the display unit. The method of claim 2,
The first range is pH 6.8 to 7.2, and the reference value is pH 7.2. The method of claim 1,
The sensor unit,
optical fiber;
a sensing membrane including a fluorescent dye and an oxidase reacting with the exudate;
a light source unit emitting light to the sensing film through the optical fiber;
a photodetector for detecting reaction light generated in response to the oxidase of the sensing layer; and
Negative pressure wound treatment device further comprising a control unit for calculating the acidity of the exudate from the light detected by the photodetector. The method of claim 3,
The main body changes the color according to the measured acidity value and displays it on the display unit, and changes the value of the first range and the reference value according to the wound treatment stage. delete

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