KR20200020106A - Light operating patch and healthcare platform with the same - Google Patents

Abstract

The present invention relates to a healthcare platform. A healthcare platform according to an embodiment of the present invention comprises: a light operating patch for irradiating low-power light of 100 mW or less; a mobile device having a smartphone application used to be connected to the light operating patch on a wireless communications network; and a healthcare platform server provided to be able to transmit and receive operation information data of the light operating patch, wherein the healthcare platform server has a database (DB) for collecting operation information of the light operating patch, which is received from the mobile device, and controls an operation of the light operating patch by comparing the operation information collected in the DB with preset reference data and then reviewing the same, or controls the mobile device to show customized operation information extracted as the operation information.

Description

LIGHT OPERATING PATCH AND HEALTHCARE PLATFORM WITH THE SAME}

The present invention relates to a light treatment patch and a health care platform having the same, and more particularly, having a built-in battery, which can be reused through charging, and can be selectively used in a plurality of local sites as a relatively small and thin plate shape. The present invention relates to a health care platform capable of providing a personalized optical procedure history management and self-customized health care provided with the configured optical procedure patch.

External preparations, commonly called pars or pain patches, are drugs that are attached to the human body and have the purpose of alleviating pain in the affected area. The paste is formed in the form of a band in which the paste solution is mixed with the adhesive solution, and is used by being attached to the affected part during use. The paste has a hot or cold paste according to the component or type of the applied paste solution, and recently, a magnet or a needle is placed in the center to improve blood flow.

However, the above-described side effects such as skin problems, large and small burns, skin rashes and sores are caused by the applied adhesive liquid or pars liquid, insufficient air circulation. In particular, there is a problem in that it is difficult to use due to these side effects to people, such as people with innately weak skin or children. In addition, the general parser has a limited effect, not a fundamental treatment, and most of them have to be used for a single use, and thus, there is a disadvantage in that it is not environmentally friendly with cost burden in the long term use.

Meanwhile, in recent years, various types of healthcare platforms have been developed for general health care. However, the healthcare platform has been developed in a limited way based on simple biometric information acquisition or basic diagnosis such as heart rate measurement, heart rate variability measurement, oxygen saturation level or exercise amount measurement. However, such a diagnosis-based healthcare platform was developed in a form that excludes information on personalized procedures based on it. Therefore, limited information is provided because it is more practical and lacks or poor information in terms of treatment and treatment. There is a disadvantage that it is a healthcare platform that derives only the value as.

The problem to be solved by the present invention is to provide a light treatment patch using a low-power laser or LED light source having a high treatment effect, and there is no skin problems such as skin rash, allergy, burn, etc. and a healthcare platform having the same .

The problem to be solved by the present invention consists of plate-shaped patches of relatively small size to be applied to a topical site, the optical procedure patch made so that the user can select and combine the patches according to the type of procedure and the desired topical site And to provide a healthcare platform having the same.

The problem to be solved by the present invention is a safe and easy self-treatment through the smartphone app (App) that provides a general guide to the pain relief procedures and the use of these patches and procedures during daily or professional life It is to provide a light surgical patch made to be performed and a healthcare platform having the same.

The problem to be solved by the present invention is the optical information that can be developed to the treatment information generated on the basis of the optical procedure for the purpose of pain relief or blood flow improvement, and to the healthcare big data, personal health care and remote professional medical services based on the same The present invention provides a healthcare platform having a procedure patch.

The light surgical patch according to the present invention includes a plate-shaped patch body having a transmission hole for transmitting light, a circuit board disposed inside the patch body, an internal battery disposed in the patch body, and the internal battery power. A wireless communication module operated by a low voltage, such as a relatively low low level laser or a low output LED (LED), which is electrically connected to the circuit board and is a power of the built-in battery, which is 80 mW or less outside the patch body as its own power. Low level light device for irradiating light, the oscillator provided to apply vibration energy to the user, driven by the power of the built-in battery on the circuit board, and selective electricity from an external charger for the built-in battery For supply, the charging terminal includes a charging terminal provided in the patch body, the wireless communication module is It is linked with a mobile device equipped with a database that collects personal procedure information using low power light and an app connected with a healthcare platform that determines, analyzes, and feeds back the procedure information, and the low power light device is a low power light for pain relief purposes. And a second device for irradiating low-power light for improving blood flow, having a relatively higher wavelength band than the first device, wherein the second device is disposed in a central region of the patch body. The first element is disposed along the periphery with respect to the second element, and the first element and the second element are designed to be irradiated simultaneously or sequentially.

The healthcare platform according to the present invention is a light procedure patch for irradiating a low output light of less than 100mW, a mobile device having a smartphone app (App) used in conjunction with the optical procedure patch and wireless communication network and the procedure information of the optical technology patch And a healthcare platform server provided to transmit and receive data, wherein the healthcare platform server includes a database (DB) for collecting the procedure information of the optical procedure patch received from the mobile device and the procedure information collected into the database. Compare and examine the preset reference data, and control the operation of the optical procedure patch, or control the mobile device to show the user personalized procedure information extracted as the procedure information.

According to the invention

1 is a view showing an optical procedure patch and charger of the optical procedure patch set according to the present invention.
2 is a view showing the members for attaching the human body of the light surgical patch according to the present invention.
3 is a perspective view showing a light surgical patch according to an embodiment of the present invention.
FIG. 4 is a cross-sectional view illustrating an internal configuration of the light procedure patch shown in FIG. 3.
5 is a flowchart showing a method of using a light surgical patch according to an embodiment of the present invention.
Figure 6 is a view showing the indication form according to the indication of the optical procedure patch according to an embodiment of the present invention.
7 is a view showing a light surgical patch according to another embodiment of the present invention.
FIG. 8 is an exploded perspective view of the light procedure patch shown in FIG. 7.
9 is a view showing a light surgical patch according to another embodiment of the present invention.
10 is a view showing a healthcare platform having a light surgical patch according to an embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various forms. The embodiments may be provided to make the disclosure of the present invention complete, and to fully inform the scope of the invention to those skilled in the art. Like reference numerals refer to like elements throughout the specification.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, 'comprise' and / or 'comprising' refers to a component, step, operation and / or element that is mentioned in the presence of one or more other components, steps, operations and / or elements. Or does not exclude additions.

In addition, the embodiments described herein will be described with reference to cross-sectional views and / or plan views, which are ideal illustrations of the present invention. In the drawings, detailed sizes, shapes, thicknesses, curvatures, and the like of the components are exaggerated or illustrated for effective explanation of technical contents, and the shapes thereof may be modified by tolerances and the like.

Hereinafter, an optical procedure patch and an optical procedure patch set having the same according to an embodiment of the present invention, and a healthcare platform including the same will be described in detail with reference to the accompanying drawings.

1 is a view showing a light surgical patch and a charger of the light surgical patch set according to the present invention, Figure 2 is a view showing the members for human body attachment of the light surgical patch according to the present invention.

1 and 2, an optical procedure patch set 10 according to an embodiment of the present invention stores and stores a patch band 20, a charger 30, an optical procedure patch 100, and these components. Packaging boxes (not shown) and the like. In addition, a stationary charger (not shown) capable of simultaneously charging at least one or more of the optical procedure patch 100 and a portable charger while simultaneously charging at least one or more of the optical procedure patch 100 from external shocks A portable cradle (not shown) may be further provided to protect the same.

In addition, the optical surgery patch set 10 may further include a mobile device 40 having a smartphone app 42 that can be used in conjunction with or associated with the optical surgery patch 100. The smartphone app 42 may include various types of smartphones and user applications implemented in various mobile devices including the same. The smartphone app 42 can provide a user registration, product introduction, personalized procedure guide, personal procedure history management, linkage and linkage control with the product, product promotion, and procedure cycle and suitable use guide, etc. have.

The optical procedure patch 100 may be a device for irradiating the skin with a relatively low power laser, that is, a low level laser (LLL). Alternatively, the optical surgery patch 100 may be a device for irradiating the skin of the LED (LED) of a relatively low output. For example, the optical surgery patch 100 may be a medical device for irradiating a body with a low power laser or LED of about 100 mW or less.

The optical procedure patch 100 may have a relatively small and thin plate shape. The optical surgery patch 100 may have a plane having various shapes such as a disc shape, a square plate shape, and an oval shape. The plurality of optical surgery patches 100 may be provided in one packaging box 40 so that a user may use the plurality of optical surgery patches 10 in various combinations.

The patch band 20 may be for fixing the optical surgery patch 100 to the skin site desired by the user. As shown in Figure 2 (a), the patch band 20 according to an embodiment of the present invention and the fixing portion 22 and the fixing portion 22 for fixing one optical procedure patch 100 and It may be made of a band portion 24 connected. The band portion 24 may be for fixing to the human body while the optical procedure patch 100 is aligned to the desired area. In this case, as the fixing part 22, an opening or a groove formed in the band part 24, a mounting member for a separate seating, etc. may be used, and the user may attach the optical procedure patch 100 to the fixing part. After fitting, inserting, or fastening to 22, the band part 24 may be wound around the human body to fix the optical procedure patch 100 to the human body.

As shown in Figure 2 (b), the patch band 20a according to another embodiment of the present invention is fitted to the optical procedure patch 100 as a Velcro (velcro) fixed portion 22a and one surface The Velcro and the detachable Velcro treated band portion 24b of the fixing portion 22a may be provided. In this case, the fixing part 22a is attached to the fixing part 22a on the band part 24b at a desired position so as to correspond to a desired part of the user. Can be.

As shown in Figure 2 (c), the patch band 20b according to another embodiment of the present invention is provided with a fixing portion 22b to be used to fit the optical procedure patch 100, the fixing portion 22b On one side of the) may be coated with an adhesive material that can be fixed or adhered to the skin. In this case, the user may adhere the patch band 20b to the patch band 20b and then attach the patch band 20b to a desired portion.

As described above, the user may use the patch bands 20, 20a, and 20b of various types to attach the optical surgery patch 100 to the body. However, the member for attaching the body of the optical procedure patch 100 according to the present invention is not limited to the patch bands 20, 20a and 20b, and various types of members may be used.

For example, as another example of the member for attaching the human body of the optical procedure patch 100, as shown in FIG. 2 (d), a cupping device 20c made of a flexible material may be used. The cupping machine 20c has an opening or a groove for inserting or fastening the optical procedure patch 100 in a central region, and the remaining wing portion may be provided to be in close contact with a human body using its own elasticity. have. This type of cupping machine 20c is provided in the form of a so-called silicon cupping machine, and may be provided to be fixed to the human body through the fastening of the optical procedure patch 100. The combination use of the optical procedure patch 100 and the cupping machine 20c as described above is more effective in pain relief by adding the cupping treatment of the cupping machine 20c together with the optical and physical treatment by the optical procedure patch 100. And blood flow improvement procedure.

In addition, as another example of a member for attaching a human body of the optical procedure patch 100, an adhesive tape 20d as illustrated in FIG. 2E may be used. The adhesive tape 20d may be provided in a form having adhesiveness on both sides so that one surface is attached to the light irradiation surface of the light surgical patch 100 and the other surface is attached to the body. In addition, the adhesive tape 20d may be made of a transparent material so as not to obstruct or minimize the transmission of the irradiation light of the optical procedure patch 100. In addition, the adhesive data 20d may be provided in a form in which a perforation 20d 'is formed in the irradiation path portion of the light. The adhesive tape 20d as described above may be used as a consumable capable of one-time use or a limited number of repetitive use, and may be used to allow the user to fix the optical procedure patch 100 to the human body by a simple taping attachment method.

The charger 30 may be for charging the optical surgery patch 100. The charger 30 may include a separate or integral charging gender 32 to simultaneously charge the plurality of optical procedure patches 10.

Subsequently, the optical procedure patch according to the embodiment of the present invention will be described in detail. Here, overlapping descriptions of the above-described optical procedure patch 100 may be omitted or simplified.

3 is a perspective view showing a light surgical patch according to an embodiment of the present invention, Figure 4 is a cross-sectional view showing the internal configuration of the light surgical patch shown in FIG.

1 to 4, the photosurgical patch 100 according to the exemplary embodiment of the present invention may include a patch body 110, a circuit board 120, a built-in battery 130, a low power optical device 140, and a detector. 150, and controller 160.

The patch body 110 may have a generally thin plate shape and may provide an inner space for protecting, arranging, and supporting the components 120, 130, 140, 150, and 160. As an example, the patch body 110 may have a first body 112a and a second body 112b which are assembled to each other to complete a thin plate-shaped body 112 having a diameter of 60 mm or less and a thickness of 20 mm or less. Can be. The first body 112a may have one surface in close contact with the human body during the procedure, and the second body 112b may have the other surface exposed during the procedure. One surface of the first body 112a may be provided with a transmission hole 112c for transmitting light, such as a low power laser or LED. The second body 112b may be provided with an operation light (not shown) to allow a user to recognize the light when the light is irradiated or when the optical surgical patch 100 is operated.

The transmission hole 112c of the first body 112a may further include a lens 113 for diffusing the irradiated light. As an example, the lens 113 may be provided to reduce the linearity of light that the laser normally has, and to diffuse and radiate a wider area into the human body. To this end, a convex lens may be used as the lens 113. Accordingly, the light passing through the transmission hole 112c may pass through the lens 113 and then diffuse and penetrate into a relatively wide human body part. . In this case, it may be suitable for the purpose of the advantageous use, that is, pain relief, lymph node stimulation, edema relief, skin irritation, etc., for the purpose of scattering and irradiating light over a relatively large area.

As another example, the lens 113 may be provided to maintain or enhance the straightness of the light. To this end, the lens 113 may be a concave lens or a general transmissive plate. Accordingly, light passing through the transmissive hole 112c is concentrated or maintained after passing through the lens 113 and thus a relatively narrow human body part. Can penetrate inside. In this case, it may be suitable for the purpose of advantageously improving blood flow, strengthening blood flow, activating cells, etc., by intensively irradiating light to a relatively narrow site.

The patch body 110 may be provided with a charging unit 116 for connecting the charger 30 to charge the built-in battery 120. The charging unit 116 may include a charging terminal 116a and a first charging lamp 116b and a second charging lamp 116c for recognizing whether the charging is completed or the remaining battery level. The first charging lamp 116b may include a green LED device indicating completion of charging, and the second charging lamp 116c may include a red LED device indicating charging.

In addition, the patch body 110 may be provided with various control buttons 118 for setting the treatment conditions of the optical surgery patch 100. For example, the control buttons 118 are on / off button 118a for turning on / off the low power optical device 140, and laser output control buttons for adjusting the laser output intensity of the low power optical device 140. 118b, and a timer button 118c for setting an operation time of the optical procedure patch 100, and the like. The user may set the control conditions of the optical procedure patch 100 by setting the control buttons 118 as described above. In the present exemplary embodiment, the user operates the optical procedure patch 100 in the form of three control buttons 118a to 118c, but the number and shape of the control buttons may be variously modified and modified. Can be.

The circuit board 120 may be disposed in the patch body 110. The circuit board 120 may be disposed to face the first body 112a relatively to the internal battery 130. The circuit board 120 may include at least one printed circuit board.

The built-in battery 130 may be a battery that can be repeatedly charged. The built-in battery 130 is charged by the charger 30, and may supply power for laser irradiation of the low output optical device 140 as internal power. The built-in battery 130 may use a lithium polymer battery to reduce the risk of explosion and fire. The built-in battery 130 may enable the optical surgery patch 100 to operate only by its own power, without a separate external power.

The low power optical device 140 may be provided on the circuit board 120 to irradiate low power light to the outside through the transmission hole 112c. Typically, low level lasers (LLLs) or LEDs (LEDs) are known to exert a variety of effects such as pain relief, improved blood flow, enhanced blood flow, cell activation, lymph node stimulation, edema relief, and skin irritation. The effect is exerted on light in a particular wavelength range. For example, in the case of low-power lasers, the effects of pain relief, lymph node stimulation, edema relief, cell activation, etc. are known to be high when irradiated to the human body for 20 minutes or more with an output of 30 mW or more at a wavelength range of about 630 nm to 680 nm. When irradiated to the human body for 20 minutes or more with an output of 30 mW or more at a wavelength range of 990 nm, it is known that the effect of improving blood flow, enhancing blood flow, and cell activation is high. Therefore, the low power optical device 140 may be a device of various wavelengths according to the purpose of use as described above.

Here, the low-power light irradiation 140 as described above emits a lot of heat to the outside during laser generation. The heat generation of the low power optical device 140 may reduce the life of the device, reduce product reliability and safety, and in particular, may cause a burn of the patient during the procedure. Accordingly, there is a need for a means capable of effectively emitting heat generated by the low power optical device 140. As such means, a separate heat sink 141 of FIG. 8 may be disposed around the low power optical device 140, but in this case, at least due to the degree of protruding onto the circuit board 120, The thickness is bound to increase. However, the optical surgery patch 100 according to the present invention may be as thin as possible for user convenience. That is, as the thickness of the optical procedure patch 100 is thicker, it is drawn more on the skin, and the heterogeneity and discomfort in contact with the skin are inevitably large, and the appearance is not good.

In order to solve the above portion, the optical surgery patch 100 according to the present invention is configured by the patch body 110 of a material having a relatively high thermal conductivity, the heat of the low power optical device 140 to the outside It can be used as a heat transfer plate for transferring heat to the human body during the heat sink or the procedure. To this end, the patch body 110 is made of stainless steel, aluminum, copper, and other various metal materials as a whole, or the skin contact surface is made of a plastic material satisfying biocompatibility, the inside of the heterogeneous material made of a metal material It can also be configured as a multi-layered body. In this case, due to the heat generated from the low power optical device 140, the optical procedure patch 100 is partially or all of the patch body 110 is heated, the appropriate heat of the patch body 110 is the human body By delivering to the patient, it is possible to carry out a heat treatment. That is, the optical procedure patch 100 as described above may be configured to simultaneously perform a thermal treatment due to self-heating of the patch body 110 together with the basic low power laser procedure.

The detector 150 may be provided for the procedure safety and proper procedure control of the optical procedure patch 100. For example, the detector 150 may include a touch sensor 152 and a temperature sensor 154. The touch sensor 152 may detect whether one surface of the optical surgery patch 100 is in contact with the user's skin when the optical surgery patch 100 is used. For this purpose, a pressure sensor, an impedance sensor, a magnetic sensor, and a capacitive sensor may be used as the preliminary touch sensor 152. Alternatively, the touch sensor 152 may be a sensor that detects the skin contact through physical or mechanical means. For example, the touch sensor 152 may be provided as a pin that normally protrudes, and may be used as a physical sensor that detects contact by being inserted into the inside when it is in close contact with the skin. Alternatively, the touch sensor 152 may be manufactured in a form provided in the injection molding as a form completely or partially embedded as printed form inserted into the package body 110.

The temperature sensor 154 may be to prevent the burn of the user during the procedure by heating the optical procedure patch 100 due to the heat generated by the low-output optical device 140. As described above, the patch body 110 according to the present invention is made of a material having a relatively high thermal conductivity, it may be configured to use the heat generated by the low-power optical device 140 for thermal treatment purposes. However, in this case, an image may be generated due to excessive heat of the optical procedure patch 110, and a safety technology may be necessary to prevent this. To this end, the temperature sensor 154 is provided with at least one or more in the patch body 110, it can detect the temperature of the patch body (110). As an example, the temperature sensor 154 is provided on the first body 112 of the patch body 110, it may be provided to detect the temperature of the first body 112 in direct contact with the human body during the procedure. have.

The controller 160 may receive the detection signal from the detector 150 to control the optical procedure patch 100. For example, the controller 160 receives the touch detection signal from the touch sensor 152, and when the patch body 110 is in contact with the human body during the procedure to turn on the low output optical device 140 When the patch body 110 is not in contact with the human body, the low power optical device 140 may be turned off. At this time, the

In addition, the controller 160 receives the temperature sensing signal from the temperature sensor 154, and turns off the low output optical device 140 when the temperature of the patch body 110 is out of a predetermined temperature. When the temperature of the patch body 110 satisfies a preset temperature, the low power optical device 140 may be turned on. Here, the predetermined temperature range may be a temperature range for the appropriate heat treatment. For example, the predetermined temperature range may be approximately 40 ° C. to 55 ° C. When the patch body 110 is less than approximately 40 ° C. during the procedure, the thermal treatment effect may be extremely insignificant. On the contrary, when the patch body 110 exceeds about 55 ° C. during the procedure, the user may be burned.

Hereinafter, a description will be given of a self-low power optical method using the optical procedure patch procedure set described above in detail. Here, the overlapping description of the optical procedure patch and the optical procedure patch set having the same will be omitted or simplified.

FIG. 5 is a flowchart illustrating a method of using an optical procedure patch according to an embodiment of the present invention, and FIG. 6 is a view illustrating an indication procedure of an optical procedure patch according to an embodiment of the present invention.

5 and 6, first, procedure conditions may be set and started (S110). More specifically, the user may manipulate the control buttons 118 of the optical procedure patch 100 to set the output time, intensity control, and on operation of the low output light of the optical procedure patch 100. . These procedure setting values may differ depending on the purpose of use such as pain relief, blood flow improvement, blood flow strengthening, skin regeneration, cell activation, lipolysis, and cell stimulation. In addition, the treatment condition setting values may be controlled through a smartphone app (42 in FIG. 1) associated with the optical surgery patch 100.

As a more specific example, as shown in Fig. 6 (a), when the indication (e.g., the purpose of use) is relief of pain (or tendonitis) and elbow pain of the wrist, the output adjustment button 118b is operated to The output of the low output light is set to 40 mW, the timer button 118c is set to 30 minutes, and then the on / off button 118a is operated to turn on as the condition. And, while using the patch band 20, a plurality of light surgical patches 100, to be sequentially attached to the target skin position along the treatment method and the procedure image guided through the smartphone app (42 in FIG. 1). Can be.

Here, the indication shown in Figure 6 (b) is a knee pain and sprain of the ankle, the indication shown in Figure 6 (c) is shoulder pain and fifty shoulders, the indication shown in Figure 6 (d) is stiff neck or neck stiff and painful Symptoms, indications shown in Figure 6 (e) may be sciatica and back pain. Such a smart phone app 42 will guide the user to Figure 6 (a) to Figure 6 (e) and the user, the user can perform a personalized self procedure through the procedure guide. This treatment method combines both techniques of low power light with the principle of moxibustion and acupuncture, while placing the optical procedure patches 100 on the main adaptive blood spot guided by the smartphone app 42. You can perform professional procedures yourself.

When the optical patch 100 is attached to the surgical site, it can be determined whether the optical patch 100 is in normal contact with the human body (S120). More specifically, the controller 160 receives the touch detection signal from the touch detection sensor 152 of the detector 150, and one surface of the first body 112a of the optical surgery patch 100 is normally attached to the treatment site. It can be determined whether or not. In this case, when it is determined that the patch body 110 is in normal contact with the treatment site, the controller 160 controls the circuit board 120 to operate the low output optical device as its own power of the built-in battery 140. Low-output light irradiation of 140 may be started (S130). On the contrary, when it is determined that the patch body 110 is not in contact with the treatment site, the controller 160 may wait for low power light irradiation of the low power optical device 14 (S140).

That is, the low power light irradiation of the low power optical device 140 is irradiated only when the light surgical patch 100 is normally in contact with the treatment site, otherwise, the low power optical device 140 may always wait in an off state. Accordingly, the light procedure patch 100 as described above allows the low output light to be irradiated only when it is normally in contact with the treatment site, thereby preventing a safety accident such as the low output light being irradiated to the eye due to the carelessness of the user.

In addition, when the low-output light is irradiated, it may be determined whether the temperature of the light procedure patch 100 satisfies a preset temperature range (S150). More specifically, the controller 160 receives the temperature sensing signal from the temperature sensor 154 of the detector 150, the temperature of the patch body 112 of the optical procedure patch 100 has a predetermined temperature range. It can be determined whether or not it is satisfied. In this case, when the temperature of the patch body 110 satisfies the preset temperature range, the controller 160 may allow the low power light irradiation of the low power optical device 140 to continue (S160). In contrast, when the temperature of the patch body 110 is out of the preset temperature range, the controller 160 may control the circuit board 120 to stop laser irradiation of the low power optical device 140. There is (S170).

That is, as described above, since the optical surgery patch 100 according to the embodiment of the present invention uses the heat generated by the low power optical device 140 as heat for thermal treatment, the temperature of the patch body 110 is excessively increased. When raised, problems such as an image may occur. Accordingly, the optical procedure patch 100 as described above allows the low-output light to be irradiated only when it does not exceed the normal temperature range, thereby increasing the safety of the procedure.

In the process of performing the low-power optical procedure as described above, it may be determined whether a predetermined procedure time has been reached (S180). For example, when 30 minutes set in the above-described step S110 is not reached, the controller 160 may return to the previous step S120 to repeat the above-described steps S120 to S170. On the contrary, when the 30 minutes set in step S110 is reached, the low output optical device 140 is turned off and then the alarm or the operation lamp (not shown) is recognized so that the user can recognize it. External display such as off can be made.

As described above, the light treatment patch set 10 according to the embodiment of the present invention includes a light treatment patch 100 for irradiating low-power light and a patch band 20 for fixing it to the treatment site, Each of the photosurgical patches 100 may be provided in a thin plate shape while having a relatively small diameter. In this case, the user selects and places the optical procedure patches 100 in combination with local areas such as pain areas, blood apertures, lymph nodes, etc., thereby alleviating pain, improving blood flow, enhancing blood flow, Various autologous procedures can be performed, such as lymph node irritation, edema relief, and skin irritation. Accordingly, the optical surgical patch and the optical surgical patch procedure set having the same according to the present invention are composed of plate-shaped optical surgical patches having a relatively small size so that the surgical procedure can be applied to a localized area, and the user can apply to the desired type and desired localized area. You can use any combination of patches to suit your needs.

In addition, the optical procedure patch and the optical procedure patch set having the same according to an embodiment of the present invention is a problem caused by adhesives and parsing agents, such as skin rashes, allergens, skin problems such as burns, etc., compared to conventional pars or pain patches. Without, pain relief, blood flow improvement, blood flow strengthening, skin regeneration, cell activation, lipolysis, and cell stimulation can be performed.

In addition, the optical surgical patch and the optical surgical patch set having the same according to the present invention, compared to the conventional pain or pain patch, the user can receive the self-operation with the same effect at no additional cost for a long time, to prevent waste of resources It can be environmentally friendly.

Hereinafter, a description will be given of an optical procedure patch according to other embodiments of the present invention described above. Here, the overlapping contents for the optical procedure patch according to the embodiment of the present invention described above may be omitted or simplified.

7 is a view showing a light surgical patch according to another embodiment of the present invention, Figure 8 is an exploded perspective view of the light surgical patch shown in FIG. 7 and 8, the optical procedure patch 100a according to another embodiment of the present invention may include a patch body 110, a circuit board 120, an internal battery 130, a low output optical element 140a, and a detector. 150, and the controller 160, the low power optical device 140a may include a first device 142a and a second device 144a having different laser wavelength values. As an example, the first device 142a may include a low power optical device having a wavelength range of about 630 nm to 680 nm and having an output intensity of about 100 mW or less. The first element 142a may be used for the purpose of pain relief, lymph node stimulation, edema relief, cell activation, and the like. In contrast, the second device 144a may include a low power optical device having a wavelength range of about 780 nm to 990 nm and having an output intensity of about 100 mW or less. The second element 142a may be used for the purpose of improving blood flow, enhancing blood flow, and activating cells. Herein, the output strength of the first and second elements 142a and 142b may be more preferably limited to 80 mW or less for user safety. In addition, it may be desirable for personal medical device authentication that the output intensity of the first and second devices 142a and 142b is adjusted to 5 mW or less, which is an output value limited in class 3R class among the class 3 medical devices.

The number and arrangement of the first and second elements 142a and 144a may be changed or modified in various ways. The user may operate the control buttons 118 to select and control the first and second elements 142a and 144a. For example, when the optical procedure patch 100a is used for pain relief use, the user may set and use the control buttons 118 so that only the first element 142a is turned on. Alternatively, when the optical procedure patch 100a is used for the purpose of improving blood flow, the user may set and use the control buttons 118 so that only the second element 144a is turned on. If the user wants to use both purposes for pain relief and blood flow improvement at the same time, the user may use the first and second elements 142a and 144a after turning them on.

Meanwhile, in order to dissipate heat generated by the first and second elements 142a and 144a, ring-shaped heat sinks 141 surrounding each of the first and second elements 142a and 144a may be provided. Can be. In addition, the heat sinks 141 may have different materials, shapes, and thicknesses from those provided to the first element 142a and those provided to the second element 144a. For example, when the heat generation temperature of the first element 142a is high or large among the first and second elements 142a and 144a, the size of the heat sink 141 provided to the first element 142a is large. , Material, high thermal conductivity, etc. may be used.

The optical procedure patch 100a having the structure as described above may irradiate a laser having different wavelengths as one optical procedure patch 100a, compared to the optical procedure patch 100 according to an embodiment of the present invention, and thus, a single light As the procedure patch 100a, laser treatment of two wavelength bands can be performed.

9 is a view showing a light surgical patch according to another embodiment of the present invention. Referring to FIG. 9, the optical procedure patch 100b according to another embodiment of the present invention may include a patch body 110, a circuit board 120, an internal battery 130, a low output optical element 140a, and a detector 150. ), The controller 160, and the vibrator 170. The vibrator 170 may be provided to further add the purpose of use, such as improving blood flow, by transmitting fine vibration to the treatment site during the procedure. As the vibrator 170, an ultrasonic vibrator, an electromagnet motor vibrator, and the like may be used.

Here, the user may be provided to adjust the vibration intensity, the vibration period and the vibration waveform of the vibrator 170 using the control buttons 118 and the smartphone app 42. For example, the optical surgery patch 100b may have a plurality of vibration modes in which the vibration intensity or period of the vibrator 150 is different, and a user selects a desired pain procedure by the vibrator 170. Vibration massage and kneading effect can be achieved.

The optical procedure patch 100b having the above-described structure may simultaneously or separately perform a low power optical procedure and a physical energy procedure by fine vibration as one optical procedure patch 100b.

10 is a diagram illustrating a personal health care system having a healthcare platform with a light procedure patch in accordance with an embodiment of the present invention. Referring to FIG. 10, the health care system 1 according to the exemplary embodiment of the present invention is a system capable of integrating and managing such an individual procedure while performing a patient's own procedure in a general home or daily life. It may include an optical procedure patch 100, a mobile device 40, and a healthcare platform 200.

The healthcare platform 200 may be divided into an open platform, a service platform, and a determination and analysis platform. The open platform is connected to the optical procedure patch 100 and the mobile device 40, and transmits the procedure information stored in the database while maintaining data transmission / reception status of the optical procedure patch 100, The smartphone app 42 of the mobile device 40 may be controlled to display a user interface for inputting feedback information felt after the user receives the procedure by the low power light. As such, the healthcare platform 200 is connected to a server on a wireless communication network to receive a user authentication by the smart phone app 42 so as to enable intermediary transmission of procedure information and input of feedback information. By accessing the user's excessive treatment information and feedback information about it, it may be possible to check the currently recommended personalized, analytic procedure information or general procedure information.

In addition, when accessing a database using the mobile device 40 and selecting procedure information such as an indication to be provided for self-treatment, various control items included in the selected procedure information, for example, low output light or vibration The optical procedure patch 100 can be controlled through the output, intensity, mode and time adjustment information of energy, and the user can recognize the information through the smartphone app 42.

When the users who received the optical procedure input feedback information by individual by using the procedure information provided from the healthcare platform server, the information is also classified and stored by category, and personalized or customized personalized procedure information is managed personally or individually. Alternatively, product usage management may be enabled. Furthermore, by accumulating and managing the procedure information, the user can create valuable healthcare information by integrating the results of sex, age, race, time, pain before and after the procedure, and the like.

On the other hand, the healthcare platform server is connected to the wireless communication network using the mobile device 40 and then search the data stored in the database, and can download, share, transfer the desired data, and enter a new data form Can be provided. This type of server can be controlled and stored in the operation mode or various control values, it may also be possible to build a separate independent server for this. In addition, personalized medical advisory services may be available as far as telemedicine develops. In this case, it will be possible to develop an advanced treatment-based healthcare platform through the classification of treatments by various categories, races, genders and ages, and the collection and classification of big data for pain relief and blood flow improvement procedures. In particular, the optical surgery patch 100 according to the present invention is composed of several in one product configuration, because it can be used for various body pain indications, it is composed of a design that can cover the treatment for various indications only by purchasing one product have. Accordingly, when the user enters the indication category and proceeds to the indication, the procedure information classified by the indication is divided and stored in the database, so as a single product, the pain is divided into indications or parts. It may be possible to derive the procedure information.

The healthcare platform 200 may be input by using the mobile device 40, the procedure information consisting of a personalized procedure program stored in a database, as well as an external expert for pain relief and blood flow improvement of the user It may include a program of procedures that allows medical practitioners to advise on pain rehabilitation treatment. In this case, it can be extended as a platform for providing accurate and more specialized medical services to an individual by external specialists. The healthcare platform 200 is not limited to a treatment-based healthcare platform, and when the diagnosis or inspection function for the user is added to the optical surgery patch 100, various personal diagnosis information is collected. It is also possible to develop as a healthcare platform that accommodates both diagnosis and procedure.

Accordingly, the healthcare platform according to the present invention is a form that enables the implementation of advanced medical services, such as remote care, by managing pain and improving blood flow, in addition to managing a variety of treatment-based medical information and biometric information, and furthermore, personalized A procedure-based healthcare platform can contribute to a variety of pain patients. In particular, the healthcare platform can be a form of feedback to the user again valuable healthcare information while proceeding in the form of screening, collection, analysis, and derivation while receiving the procedure conveniently and effectively in daily life. As a result, it can be a very valuable healthcare platform for patients who are difficult to go to the hospital or who are unable to go to hospital.

As described above, the healthcare platform 200 according to the present invention continuously stores, classifies, analyzes and derives the procedure information collected by the user performing the optical procedure by using the optical procedure patch 100. Feedback back to the user of the new information is valuable as a personalized procedure based healthcare platform. In particular, while the existing general diagnosis-based healthcare platform only stays on the diagnosis, the healthcare platform 200 is a treatment-based healthcare platform that actually collects big data generated while the patient is performing the self-treatment. More realistic and valuable healthcare information may be possible. If it is developed into a more standardized procedure-based healthcare platform through quantification and standardization, it may be possible to create more information-based healthcare big data than the treatment information through existing hospital equipment.

So far it has been described with respect to the light surgical patch according to the present invention and a specific embodiment of the healthcare platform having the same, it is obvious that various embodiments can be modified without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof. The above-described embodiments are to be understood in all respects as illustrative and not restrictive, the scope of the invention being indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and their equivalents. All changes or modifications derived from the concept should be construed as being included in the scope of the present invention.

10: light treatment patch set
20: patch band
30: charger
40: smart phone
100: light treatment patch
110: patch body
112: plate-shaped body
113: Lens
115: operation light
116: charging unit
118: control buttons
120: circuit board
130: built-in battery
140: low power optical device
150: Detector
152: touch detection sensor
154 temperature sensor
160: controller
200: healthcare platform

Claims (6)

A plate-shaped patch body having a transmission hole for transmitting light;
A circuit board disposed inside the patch body;
An internal battery disposed in the patch body;
A wireless communication module operated by the built-in battery power;
A low power optical device electrically connected to the circuit board and emitting low power light such as a relatively low low level laser or a low power LED (LED) of 80 mW or less out of the patch body as a power of the internal battery. Low Level Light Device;
A vibrator driven on the circuit board with power of the built-in battery, the vibrator provided to apply vibration energy to a user; And
A charging terminal provided in the patch body for selective supply of electricity from an external charger to the built-in battery,
The wireless communication module is linked with a mobile device equipped with a database that collects the personal procedure information using the low-power light and the app connected to the healthcare platform to determine and analyze the procedure information to feed back to the individual,
The low output optical device,
A first element for irradiating low power light for pain relief purposes; And
Including a second device having a relatively high wavelength compared to the first device for irradiating low-power light for the purpose of improving blood flow,
The second element is disposed in the central region of the patch body, the first element is disposed along the periphery around the second element,
And the first device and the second device are designed to be irradiated simultaneously or sequentially. A light procedure patch for irradiating low power light of 100 mW or less;
A mobile device having a smartphone app (App) used in connection with the optical procedure patch and a wireless communication network; And
Including a healthcare platform server provided to transmit and receive the procedure information data of the optical technology patch,
The healthcare platform server
A database (DB) for collecting the procedure information of the optical procedure patch received from the mobile device; And
The healthcare platform controls the mobile device to control the operation of the optical procedure patch or to display the user personalized procedure information extracted as the procedure information by comparing and reviewing the procedure information collected by the database with preset reference data. . The method of claim 2,
The optical procedure patch,
A plate-shaped patch body having a transmission hole for transmitting light;
A circuit board disposed inside the patch body;
An internal battery disposed in the patch body;
Low level light, which is electrically connected to the circuit board and irradiates a relatively low low level laser or low output LED of less than 80 mW to the outside of the patch body as the power of the internal battery. Device); And
And a charging terminal provided in the patch body for selective supply of electricity from an external charger to the built-in battery. The method of claim 2,
The optical procedure patch includes at least one low power optical device for irradiating a relatively low low level laser or low power LED (LED) of 80 mW or less,
The low output optical device,
A first device having a wavelength range of 630 nm to 680 nm; And
A healthcare platform comprising a second device having a wavelength range of 780 nm to 990 nm. The method of claim 2,
The optical procedure patch includes a low power optical device for irradiating a relatively low low level laser (Low Level Laser) or low power LED (LED) of 80mW or less,
The low output optical device,
A plurality of first elements; And
Including a second device having a relatively high wavelength compared to the first device,
The second element is disposed in the central region of the patch body,
The first device is a healthcare platform disposed around the periphery of the second device. The method of claim 2,
The optical procedure patch further includes a detector for detecting information about the optical procedure,
The detector may include at least one of a touch sensor for determining whether the optical patch is in normal contact with a human body, a temperature sensor for detecting a temperature of the optical patch, and an output sensor for detecting an output of the low output light. Healthcare platform having a.

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