TWI846477B - Photobiomodulation bracelet device and system using the same - Google Patents

Abstract

A photobiomodulation bracelet device including a smart monitoring module, a phototherapy irradiation module, and a wristband. The smart monitoring module is worn on an outward side of a wrist and is configured to monitor and display one or more biological features. The phototherapy irradiation module is worn on an inward side of the wrist and includes an irradiation body and at least one illuminating light source. The illuminating light source is movable to emit a selective wavelength of light to the inward side. The wristband is connected to the smart monitoring module and the phototherapy irradiation module. According to these biological features and multiple health data pre-inputted to a body of the smart monitoring module, the illuminating light source of the phototherapy irradiation module is adjusted to movably emit light at wavelengths from 420 nm to 950 nm, wherein the adjust phototherapy irradiation module includes the power of adjust the light color of the irradiation light source, a single light output duty cycle, a light output wavelength, pulse repetition rate, the number of times of irradiation, or peak pulse power.

Description

Light energy bio-regulation bracelet device and system

The present invention relates to a technical field of photo-bioconditioning, and in particular to a wristband device and system for performing photo-bioconditioning on tissues.

Low level laser therapy (LLLT) involves exposing cells or tissues to low-power visible light (400-700nm) or near infrared (NIR) light (700-1100nm) of various wavelengths. When the applied light energy is a laser diode (LD) light source, LLLT is also called "low-power laser" or "cold laser" therapy because the power density used is lower than that required to produce tissue warming. Laser diodes have become a commonly used light source, allowing healthcare providers to easily direct the beam to a target. Another light source, the light-emitting diode (LED), can also be used to produce light in a specific wavelength band, but with a wider emission pattern. In particular, white light sources and filters can produce narrow or wide spectral ranges. Furthermore, another potential light source, super luminescent diode (SLD), has also found some applications in LLLT treatment.

Regardless of the type of light source used, LLLT is believed to affect the biological changes of living tissues by inducing photochemical reactions in cells. This process is medically known as "photobiomodulation" (PBM). Although existing technologies have been applied to many wearable LLLT treatment devices, the health and therapeutic effects of these devices still have room for improvement. Their "luminous energy" cannot effectively affect the veins, arteries, meridians or acupuncture points in the wrist to stimulate the activation of oxygen-carrying red blood cells, stimulate tissue regeneration, and purify the blood, thereby achieving the purpose of photobiomodulation and health care for various organs in the body.

The purpose of this invention is to provide a light energy bio-conditioning bracelet device and its system, which can stimulate the blood of the veins, arteries, meridians and acupuncture points on the wrist to activate oxygen-carrying red blood cells, stimulate tissue regeneration, purify blood, and then use blood circulation throughout the body, thereby achieving the purpose of light energy bio-conditioning, promoting activation and health care for organs throughout the body.

Another purpose of the present invention is to provide a light energy bio-conditioning bracelet device and its system, which can adjust the operating parameters of the irradiation light source according to the measured physiological characteristics and pre-input health parameters according to the subject's own condition, so as to more appropriately respond to the needs of the subject and achieve the best disease improvement or health regulation effect.

The present invention provides a light energy bio-conditioning bracelet device to achieve the above-mentioned purpose, which is worn on a wrist of a subject (user/patient). Light energy bio-conditioning bracelet device The light energy bio-conditioning bracelet device includes an intelligent monitoring module, a phototherapy irradiation module and a wristband. The intelligent monitoring module is worn on an outer side of the wrist. The intelligent monitoring module is used to monitor and display one or more physiological characteristics. The phototherapy irradiation module is worn on an inner side of the wrist relative to the outer side. The phototherapy irradiation module includes a phototherapy irradiation body and at least one irradiation light source disposed on the phototherapy irradiation body, and the irradiation light source can movably emit a light of a selective wavelength to the inner side. The wristband connects the intelligent monitoring module and the phototherapy irradiation module. According to these physiological characteristics and multiple health parameters of the subject pre-input into the intelligent monitoring module, the at least one irradiation light source of the phototherapy irradiation module is adjusted to movably emit light with a wavelength between 420nm and 950nm.

In one embodiment, the intelligent monitoring module includes a touch screen, a microprocessor, a power unit, and one or more sensors for monitoring the physiological characteristics. The touch screen and one or more of the sensors are electrically connected to the microprocessor. The microprocessor includes a built-in communication module for interconnecting information with a cloud database. The power unit provides power to the microprocessor.

In one embodiment, the sensor includes a heart rate blood oxygen sensor, a blood pressure sensor, a body fat sensor, a pulse sensor, a body temperature sensor, a blood lipid sensor, or a pulse sensor, or a combination thereof.

In one embodiment, it further comprises a light source control chip which can be selectively installed in the intelligent monitoring module or the phototherapy irradiation module, the light source control chip comprises a plurality of operating parameters for controlling and adjusting the at least one irradiation light source, and a storage unit for storing the operating parameters, the operating parameters comprising the power of the light color, the single light output working cycle, the light output wavelength, the pulse repetition rate, the number of irradiations or the peak pulse power.

In one embodiment, when the light source control chip is installed in the phototherapy irradiation module, it also includes a power supply unit configured to provide power to the light source control chip.

In one embodiment, the phototherapy irradiation body includes a first insulating layer, a first metal layer, a second insulating layer, a second metal layer and at least one irradiation light source fixing structure which are sequentially stacked, the first insulating layer is attached to the inner surface, the second metal layer is arranged away from the surface of the second insulating layer, and the at least one irradiation light source fixing structure is movably arranged between the second insulating layer and the second metal layer.

In one embodiment, the at least one illumination light source fixing structure includes a slider, the illumination light source disposed on the slider, and a positioning assembly, and the first insulating layer, the first metal layer, the second insulating layer, and the second metal layer are respectively provided with through holes corresponding to each other.

In one embodiment, the second metal layer includes a plurality of slide grooves arranged along the through holes, and one side of the slide block has a lug protruding from the slide groove, the lug enables the slide block to move along one side of the slide groove, and the width of the through hole is less than or equal to the width of the slide block.

The present invention also provides a photo-energy bio-conditioning bracelet system, comprising a cloud database and a photo-energy bio-conditioning bracelet device interconnected and communicating with the cloud database, wherein the photo-energy bio-conditioning bracelet device is worn on a wrist of a subject, and the photo-energy bio-conditioning bracelet system includes: a portable mobile phone, a smart monitoring module, a phototherapy irradiation module and a wristband. The portable mobile phone includes an application. The smart monitoring module is worn on an outer surface of the wrist, and the smart monitoring module is used to monitor and display one or more physiological characteristics. The phototherapy irradiation module is worn on an inner surface of the wrist opposite to the outer surface, and the phototherapy irradiation module includes a phototherapy irradiation body and at least one irradiation light source arranged on the phototherapy irradiation body. The at least one irradiation light source can movably emit a light of a selective wavelength toward the inner side, and the light source can be selected according to the wearer's needs. The wristband is connected to the smart monitoring module and the phototherapy irradiation module. The portable mobile phone reads the physiological characteristics in the cloud database and the multiple health parameters of the subject pre-entered into the smart monitoring module stored in the cloud database through the application, thereby adjusting the at least one irradiation light source of the phototherapy irradiation module to movably emit light with a wavelength between 420nm and 950nm. When worn for a long time, the light source can be turned on and off regularly according to the needs of the user.

In one embodiment, the intelligent monitoring module includes a touch display screen, a microprocessor, a power unit, and one or more sensors for monitoring the physiological characteristics. The touch display screen and one or more of the sensors are electrically connected to the microprocessor. The microprocessor includes a built-in communication module interconnected with the cloud database information. The power unit provides power to the microprocessor.

In one embodiment, the sensor includes one or a combination of a heart rate blood oxygen sensor, a blood pressure sensor, a body fat sensor, a body temperature sensor, a blood lipid sensor, and a pulse sensor.

In one embodiment, it further comprises a light source control chip which can be selectively installed in the intelligent monitoring module or the phototherapy irradiation module, the light source control chip comprises a plurality of operating parameters for controlling and adjusting the at least one irradiation light source, and a storage unit for storing the operating parameters, the operating parameters comprising the power of the light color, the single light output working cycle, the light output wavelength, the pulse repetition rate, the number of irradiations or the peak pulse power.

In one embodiment, when the light source control chip is installed in the phototherapy irradiation module, it also includes a power supply unit configured to provide power to the light source control chip.

In one embodiment, the phototherapy irradiation body includes a first insulating layer, a first metal layer, a second insulating layer, a second metal layer and at least one irradiation light source fixing structure which are sequentially stacked, the first insulating layer is attached to the inner surface, the second metal layer is arranged away from the surface of the second insulating layer, and the at least one irradiation light source fixing structure is movably arranged between the second insulating layer and the second metal layer.

In one embodiment, the at least one illumination light source fixing structure includes a slider, the illumination light source disposed on the slider, and a positioning assembly, and the first insulating layer, the first metal layer, the second insulating layer, and the second metal layer are respectively provided with through holes corresponding to each other.

In one embodiment, the second metal layer includes a plurality of slide grooves arranged along the through holes, and one side of the slide block has a lug protruding from the slide groove, the lug enables the slide block to move along one side of the slide groove, and the width of the through hole is less than or equal to the width of the slide block.

This invention can widely and extensively irradiate the radial artery, ulnar artery, local blood vessels, acupuncture points and meridians of the wrist by configuring 9 irradiation light sources, and stimulate the blood for different purposes, such as activating oxygen-carrying red blood cells, stimulating tissue regeneration, purifying blood, etc., and then use the blood circulation throughout the body to promote the activation and health regulation of various organs of the body through light energy biological conditioning, and even achieve the effect of improving diseases.

10: Subject

20: Wrist

30: Outer side

40: Inner side

50: Cloud database

100: Light-energy bio-conditioning bracelet device

110: Intelligent monitoring module

112: Physiological characteristics

114: Health parameters

116: Operation parameters

120: Touch screen

122: Microprocessor

124: Power unit

126:Sensor

130: Light source control chip

200: Phototherapy irradiation module

210: Phototherapy irradiation body

220: First insulation layer

230: First metal layer

240: Second insulation layer

250: Second metal layer

252: Chute

260: Light source fixing structure

262: Slider

264: Illumination light source

266: Positioning assembly

2661: Bolts

2662: Nut

268: Lugs

270: Opening

272: Positioning hole

280: Perforation

290: Fasteners

300: Wristband

310: Cable

400: Portable cell phone

410: Application (APP)

In order to make the above contents of the present invention more clear and easy to understand, the following is a detailed description of the preferred embodiments in conjunction with the attached drawings as follows: FIG1 is a plan view schematic diagram of the light-energy bio-conditioning bracelet device of the present invention; FIG2A is a schematic diagram of an embodiment of the present invention in which the smart monitoring module is worn on an outer side of the wrist; FIG2B is a schematic diagram of an embodiment of the present invention in which the phototherapy monitoring module is worn on an inner side of the wrist; FIG3 is a block diagram of the system architecture of the light-energy bio-conditioning bracelet device of the present invention; FIG4A is a schematic diagram of an embodiment of the present invention in which the light-energy bio-conditioning bracelet device adjusts the operating parameters of the irradiation light source through a portable mobile phone; FIG4B is a schematic diagram of the present invention in which the light-energy bio-conditioning bracelet device FIG5A is a schematic diagram showing an embodiment of inputting health parameters through a portable mobile phone; FIG5B is a schematic diagram showing an embodiment of inputting health parameters through the smart monitoring module of the present invention; FIG6 is a schematic diagram showing that the irradiation light source fixing structure (irradiation light source) of the light energy bio-conditioning bracelet device of the present invention is arranged in a 3X3 matrix; FIG7 is a schematic diagram showing an exploded view of the phototherapy irradiation module of the present invention; FIG8 is a partial cross-sectional view of the phototherapy irradiation module of the present invention; FIG9 is a partial enlarged view of FIG8; and FIG10 is a diagram showing the relationship between the wavelength range of the irradiation light source of the present invention and the physiological characteristic absorption coefficient.

Please refer to the drawings, in which the same element symbols represent the same elements or similar elements. The principle of the present invention is illustrated by implementing it in an appropriate environment. The following description is based on the specific embodiments of the present invention illustrated, and it should not be regarded as limiting other specific embodiments of the present invention that are not described in detail herein.

As shown in FIG. 1, FIG. 2A and FIG. 2B, they respectively show a plan view of the light energy bio-conditioning wristband device of the present invention, a schematic diagram of an embodiment in which the smart monitoring module is worn on an outer side of the wrist, and a schematic diagram of an embodiment in which the phototherapy monitoring module is worn on an inner side of the wrist. The present invention provides a light energy bio-conditioning wristband device 100, which is worn on a main body 10, such as a wrist 20 of a user or a patient. The light energy bio-conditioning wristband device 100 includes a smart monitoring module 110, a phototherapy irradiation module 200 and a wristband 300.

As shown in Figures 1 to 2B, the smart monitoring module 110 is worn on an outer side 30 (i.e., the back of the hand) of the wrist 20. The smart monitoring module 110 is used to monitor and display one or more physiological characteristics 112, wherein the physiological characteristics 112 include heart rate (Beat per minute, BPM), blood oxygen concentration (Blood oxygen saturation level, SpO2), blood pressure, pulse, body temperature, blood lipids, or a combination thereof. The phototherapy irradiation module 200 is worn on an inner side 40 of the wrist 20 relative to the outer side 30, i.e., the other side of the back of the hand. The phototherapy irradiation module 200 includes a phototherapy irradiation body 210 and at least one irradiation light source 264 disposed on the phototherapy irradiation body 210, and the at least one irradiation light source 264 can movably emit light of a selective wavelength to the inner side 40. The wristband 300 connects the smart monitoring module 110 and the phototherapy irradiation module 200. According to the physiological characteristics 112 and the multiple health parameters 114 of the subject 10 pre-input into the smart monitoring module 110, the at least one irradiation light source 264 of the phototherapy irradiation module 200 is adjusted to movably emit light with a wavelength between 420nm and 950nm.

Please refer to FIG. 3, which shows a flow chart of the light energy bio-conditioning wristband device of the present invention. The intelligent monitoring module 110 includes a touch screen 120, a microprocessor 122, a power unit 124, and one or more sensors 126 for monitoring the physiological characteristics 112. The touch screen 120 and one or more sensors 126 are electrically connected to the microprocessor 122, respectively. The touch screen 120 preferably has a touch function. The display and touch functions of the touch screen 120 are both existing technologies and will not be elaborated here. The sensor 126 includes a heart rate blood oxygen sensor, a blood pressure sensor, a body fat sensor, a pulse sensor, a body temperature sensor, a blood lipid sensor, a pulse sensor, or a combination thereof. The microprocessor 122 includes a built-in communication module (not shown) that is interconnected with a cloud database 50. The communication module described herein is a router with Bluetooth, WIFI or other communication functions, which is not limited in this embodiment. The power supply unit 124 provides power to the microprocessor 122. The power supply unit 124 described herein can be a built-in rechargeable lithium battery or other suitable rechargeable battery, or an external power supply, such as a household mains power supply after voltage conversion or a USB mobile power supply, etc., without limitation.

In the embodiment shown in FIG. 3 , a light source control chip 130 is also included which is installed in the smart monitoring module 110, and at least one cable 310 which is respectively connected to the smart monitoring module 110 and the phototherapy irradiation module 200. The wristband 300 covers the at least one cable 310, and the smart monitoring module 110 and the phototherapy irradiation module 200 are electrically connected through the at least one cable 310. The light source control chip 130 is supplied with power through the power supply unit 124. However, in other different embodiments, the light source control chip 130 can also be selectively installed in the phototherapy irradiation module 200 to directly drive and adjust the at least one irradiation light source 264, which can be changed as needed. When the light source control chip 130 is installed in the phototherapy irradiation module 200, it also includes a power supply unit (not shown) configured to provide power to the light source control chip 130. The power supply unit described herein can be a built-in rechargeable battery or an external power supply as described in the previous embodiment, and is not limited. The light source control chip 130 includes a plurality of operating parameters 116 for controlling and adjusting the at least one irradiation light source 264, and a storage unit (not shown) for storing the operating parameters 116. This storage unit is, for example, a random access memory (RAM) or a non-volatile memory (NVM) such as a flash memory, which is not limited in this embodiment.

Please also refer to FIG. 4A and FIG. 4B , which respectively illustrate an embodiment of the present invention for remotely adjusting the operating parameters of the irradiation light source and inputting health parameters via a portable mobile phone. The microprocessor 122 of the intelligent monitoring module 110 can wirelessly upload and store the measured physiological characteristics 112 to the cloud database 50, and read the physiological characteristics 112 stored in the cloud database 50 and the health parameters 114 pre-uploaded to the subject 10, such as height, weight, age, body fat and gender, through the application program (APP) 410 in the portable mobile phone 400, and select the operating parameters 116 required to adjust the at least one irradiation light source 264, such as the power (energy) of the light color, the single light output working cycle, the light output wavelength, the pulse repetition rate, the number of irradiations or the peak pulse power, so that each irradiation light source 264 of the phototherapy irradiation module 200 can movably emit light with a wavelength between 420nm and 950nm.

In the embodiment shown in FIG. 4A , the illumination light source 264 includes three different wavelengths of lasers, LEDs or other suitable light sources, such as blue light or green light (displayed as a value of 520nm) between 420nm and 570nm, red light (displayed as a value of 635nm) between 630nm and 670nm, and near-infrared light (displayed as a value of 942nm) between 930nm and 950nm. The power of each illumination light source 264 is adjusted by, for example, a sliding operation. Similarly, each operating parameter 116 can also be adjusted in size, length or number of times by a sliding operation, but is not limited thereto. The settings of each illumination light source 264 and each operating parameter 116 also include operation by buttons, slot machines, and colors, but are not limited thereto.

The user can also select different wavelengths/colors of the irradiation light sources 264 according to the needs. In particular, when the light energy bio-conditioning bracelet device 100 is worn for a long time, the irradiation light sources 264 can be turned on and off regularly/irregularly according to the needs of the user, so as to achieve the purpose of promoting activation and health regulation through light energy bio-conditioning, and even improving diseases, and has the advantages of simple functions and convenient operation.

As shown in FIG. 4B , the health parameter 114 setting can be the next screen or the switching page of FIG. 4A , and can be adjusted as needed without limitation. Specifically, through the application 410 in the portable mobile phone 400 , the light source 264 of the light therapy irradiation module 200 can be wirelessly controlled and adjusted according to the needs of the main body 10 to movably emit light with a wavelength between 420nm and 950nm, so that the light energy can penetrate the skin and affect the veins, arteries, acupuncture points and meridians of the wrist 20, stimulate the blood to activate oxygen-carrying red blood cells, eliminate fat to purify the blood, stimulate tissue regeneration, etc., and then use the blood flow to circulate throughout the body to promote the activation and health regulation of various organs of the body through light energy biological conditioning, and even achieve the effect of improving diseases.

However, in the embodiment shown in FIG. 5A and FIG. 5B , the health parameter 114 of the subject 10 can also be directly input through the touch screen 120 in the intelligent monitoring module 110, and the subject 10 can select appropriate operation parameters 116 according to the individual's physical health status according to the physiological characteristics 112 measured by the sensor 126. Each irradiation light source 264 is controlled and adjusted from each control interface shown in FIG. 5A and FIG. 5B to movably emit light with a wavelength between 420nm and 950nm. The operation method of each irradiation light source 264 and each operation parameter 116 is described in the above embodiment, and will not be repeated here. In the embodiment shown in FIG. 5A , a graphical interface (not shown) for turning on/off the power of the smart monitoring module 110, the brightness, the amount of power, etc., is also included, and the operation method can be sliding or pressing a button, but is not limited to this. Therefore, the light energy bio-conditioning bracelet device 100 of this embodiment can input the health parameters 114 of the main body 10 through the smart monitoring module 110 or the portable mobile phone 400, and according to the measured physiological characteristics 112 and the physical health condition of each person, the above-mentioned operation parameters 116 can even be used according to the doctor's advice to perform more appropriate disease improvement or health regulation. It should be noted that in the embodiments shown in FIG. 4A to FIG. 5B, each operation interface/icon and operation method is only an example for illustration, but is not limited thereto.

As shown in FIG. 2B and FIG. 6 , the irradiation light source 264 preferably uses a laser diode (LD) and is preferably arranged in a 3X3 matrix, with a total of 9 laser diodes, which are respectively installed in multiple through holes 280 of the phototherapy irradiation module 200. In the embodiments shown in FIG. 2B and FIG. 6 , only a single irradiation light source fixing structure 260 (i.e., the irradiation light source 264) is used as an example for explanation. However, in other different embodiments, each irradiation light source 264 can also use a light-emitting diode (LED), a super luminescent diode (SLD) or other suitable light sources for phototherapy, and arranged in a 3X2 or 2X3 matrix, without limitation.

Please refer to FIG. 7 , which is an exploded schematic diagram of the phototherapy irradiation module of the present invention. In this embodiment, the phototherapy irradiation body 210 includes a first insulating layer 220, a first metal layer 230, a second insulating layer 240, a second metal layer 250 and at least one irradiation light source fixing structure 260 which are sequentially stacked. The first insulating layer 220 is attached to the inner side surface 40, and the second metal layer 250 is disposed away from the surface of the second insulating layer 240. The materials of the first insulating layer 220 and the second insulating layer 240 can be rubber, silicone, resin, polyurethane (PU) or other materials with electrical insulation, elasticity and ductility, without limitation. The first metal layer 230 can be aluminum, copper, iron or alloys thereof, which are materials with good heat dissipation, and the second metal layer 250 is a circuit board. Therefore, since the materials of the first insulating layer 220, the first metal layer 230, the second insulating layer 240, the second metal layer 250 are all ductile or elastic, the phototherapy irradiation body 210 can be elastically fitted on the wrist 20, which is more conducive to the light energy penetrating the skin to affect the veins, arteries, acupuncture points and meridians of the wrist 20.

The at least one illumination light source fixing structure 260 is movably disposed between the second insulating layer 240 and the second metal layer 250. The at least one illumination light source fixing structure 260 includes a slider 262, an illumination light source 264 disposed on the slider 262, and a positioning assembly 266. The first insulating layer 220, the first metal layer 230, the second insulating layer 240, and the second metal layer 250 are respectively provided with through holes 280 corresponding to each other. Please refer to FIG. 8 and FIG. 9 . The second metal layer 250 includes a plurality of slide grooves 252 arranged along the through holes 280. One side of the slide block 262 has a lug 268 protruding from the slide groove 252, wherein the lug 268 enables the slide block 262 to move along the side of the slide groove 252. Since the width of the through hole 280 is less than or equal to the width of the slide block 262, the slide block 262 is also sandwiched between the second insulating layer 240 and the second metal layer 250, so that the slide block 262 can move stably in the through hole 280. The slide block 262 also includes at least one opening 270 and a positioning hole 272. The at least one illumination light source 264 is inserted into the at least one opening 270, and the positioning assembly 266 is disposed in the positioning hole 272.

In the embodiment shown in FIG. 7 , the laser diode light source has three pins (not shown), so there are three openings 270, and the laser diode light source is inserted into the openings 270 of the slider 262, so that the laser diode light source can be electrically connected to the second metal layer 250 as the slider 262 slides. However, in other different embodiments, if the illumination light source 264 is a light-emitting diode, it has two pins, and the slider 262 has at least two openings 270, so that the light-emitting diode light source can also maintain electrical connection with the second metal layer 250 during the sliding process of the slider 262. The positioning assembly 266 includes a bolt 2661 and a nut 2662, wherein the outer diameter of the nut 2662 is larger than the diameter of the through hole 280, and the purpose of moving the irradiation light source fixing structure 260 is achieved by adjusting the tightness of the positioning assembly 266. In the embodiments shown in Figures 7 to 9, each positioning assembly 266 is illustrated by a bolt 2661 and a nut 2662; however, in other different embodiments, each positioning assembly 266 can also be a male or female buckle, etc., and is not limited.

In this embodiment, the through holes 280 are preferably arranged in a 3×3 matrix, so that the number of the illumination light sources 264 and the illumination light source fixing structure 260 is 9, respectively, and are arranged in the through holes 280. In the embodiments of Figures 6 to 9, only a single illumination light source fixing structure 260 (illumination light source 264) is shown for illustration. However, in other different embodiments, the through holes 280 can also be arranged in a 3×2 or 2×3 matrix, which can be adjusted according to needs. In the embodiment shown in FIGS. 6 to 9 , the three illumination light sources 264 arranged in the first row can emit blue light or green light between 420nm and 570nm, the three illumination light sources 264 arranged in the second row can emit red light between 630nm and 670nm, and the three illumination light sources 264 arranged in the third row can emit near-infrared light between 930nm and 950nm. The illumination light sources 264 arranged in the first row, the second row, and the third row can adjust the moving illumination wrist 20. It should be noted that the 9 light sources 264 can widely and extensively illuminate the radial artery, ulnar artery, local blood vessels, acupuncture points and meridians of the wrist 20, stimulating the blood for different purposes, such as activating oxygen-carrying red blood cells, stimulating tissue regeneration, purifying blood, etc., and then use the blood circulation throughout the body to promote the activation and health regulation of various organs of the body through light energy biological conditioning, and even achieve the effect of improving diseases.

In addition, the phototherapy irradiation body 210 also includes a plurality of fasteners 290, such as rivets, screws, bolts, nuts or a combination thereof, and each fastener 290 passes through and fastens the first insulating layer 220, the first metal layer 230, the second insulating layer 240 and the second metal layer 250 respectively.

The relationship between the wavelength of different irradiation light sources 264 and the tissue absorption coefficient is further described below, as shown in FIG10. Studies have shown that when the wavelength of the irradiation light source 264 is between 420nm and 470nm for blue light or between 520nm and 570nm for green light, the light energy can be absorbed by oxyhemoglobin, thus activating oxyhemoglobin, allowing more oxygen to be brought to various tissues and organs along with blood circulation. When the wavelength is between 630nm and 670nm for red light, it can promote the production of cell energy (adenosine triphosphate, ATP), stimulate tissue regeneration, metabolism, repair and protection, and not only prevent various diseases, but also promote the improvement of vitality and maintain a better state of spirit, energy and youthful beauty. When the wavelength is between 930nm and 950nm, near-infrared light (invisible light) can decompose the fat in the blood to achieve the function of purifying the blood.

Please refer to FIG. 3, FIG. 4A, FIG. 5A and FIG. 6 together. The light energy bio-conditioning bracelet device 100 of this embodiment can selectively or replaceably use each irradiation light source 264 of different wavelengths to emit light with a wavelength between 420nm and 950nm, so as to achieve the light therapy effect required by the main body 10. Specifically, for example, blue light with a wavelength between 420nm and 470nm is arranged in the first row, red light with a wavelength between 630nm and 670nm is arranged in the second row, and near-infrared light (invisible light) with a wavelength between 930nm and 950nm is arranged in the third row. The main body 10 can select according to the operation parameters 116 of different light colors/wavelengths, for example, select a single blue light to present blue light, whose light energy can be absorbed by oxygenated hemoglobin and has the function of activating oxygenated hemoglobin. Selecting a single red light to present red light, its light energy can promote the production of cellular energy ATP and stimulate tissue regeneration. Selecting a single near-infrared light to present colorless invisible light, its light energy can decompose blood fat to achieve the function of purifying blood. Selecting blue light and red light to present purple light, its light energy can simultaneously Achieve the function of activating oxygenated hemoglobin, promoting the production of cellular energy ATP, stimulating tissue regeneration, etc. Selecting blue light and near-infrared light to present blue light, its light energy can achieve the function of activating oxygenated hemoglobin and decomposing blood fat to achieve the function of purifying blood. Selecting red light and near-infrared light to present red light, its light energy can achieve the function of promoting the production of cellular energy ATP, stimulating tissue regeneration and decomposing blood fat, etc. Selecting all three light colors, blue light, red light and near infrared light, can produce purple light, and its light energy can achieve all the above effects.

However, in another embodiment, the light energy bio-conditioning bracelet device 100 may also selectively or alternatively use green light with a wavelength between 520nm and 570nm, red light with a wavelength between 630nm and 670nm, and near-infrared light with a wavelength between 930nm and 950nm. The main body 10 can be selected according to the operating parameters 116 of different light colors/wavelengths, for example, a single green light is selected to present green light, and its light energy can be absorbed by oxygenated hemoglobin and has the function of activating oxygenated hemoglobin. A single red light is selected to present red light, and its light energy can promote the production of cellular energy ATP and stimulate tissue regeneration. A single near-infrared light is selected to present colorless and invisible light, and its light energy can decompose fat in the blood to achieve the function of purifying the blood. Selecting green light and red light will produce yellow light, and its light energy can activate oxygenated hemoglobin and decompose blood fat to purify blood. Selecting green light and near-infrared light will produce green light, and its light energy can activate oxygenated hemoglobin and decompose blood fat to purify blood. Selecting red light and near-infrared light will produce red light, and its light energy can promote the production of cellular energy ATP, stimulate tissue regeneration and decompose blood fat. Selecting all three colors above will produce yellow light, and its light energy can achieve all the above effects.

In addition to the above-mentioned operating parameters 116 of different light colors/wavelengths, energy/power output, irradiation time/number of times or peak pulse power output can also be matched. Energy/power output options include 50%, 70%, 100%, and are not limited. Irradiation time/number of times options include 15 minutes/cycle, etc., and are not limited. Pulse output options include frequencies of 10Hz, 40Hz, and 60Hz, and are not limited. The above-mentioned operating parameters 116 options can be adjusted and switched according to the different needs and purposes of the main body 10, and can be adjusted as needed without limitation.

As shown in Figures 1 to 3, the present invention also provides a light-energy bio-conditioning bracelet system, comprising a cloud database 50 and a light-energy bio-conditioning bracelet device 100 interconnected and communicating with the cloud database 50, wherein the light-energy bio-conditioning bracelet device 100 is worn on a wrist 20 of a subject 10.

Please refer to FIG. 4A to FIG. 10 , the light energy bio-conditioning bracelet system includes a portable mobile phone 400, a smart monitoring module 110, a light therapy irradiation module 200 and a wristband 300. The portable mobile phone 400 includes an application 410. The smart monitoring module 110 is worn on an outer side 30 of the wrist 20. The smart monitoring module 110 is used to monitor and display one or more physiological characteristics 112, and also has functions similar to a watch or bracelet interface. The functions of the watch or bracelet interface are existing technologies and will not be elaborated here. The phototherapy irradiation module 200 is worn on an inner side 40 of the wrist 20 relative to the outer side 30. The phototherapy irradiation module 200 includes a phototherapy irradiation body 210 and at least one irradiation light source 264 disposed on the phototherapy irradiation body 210. The at least one irradiation light source 264 can movably emit light of a selective wavelength to the inner side 40. The wristband 300 is connected to the intelligent monitoring module 110 and the phototherapy irradiation module 200. The portable mobile phone 400 reads the physiological characteristics 112 in the cloud database 50 and the multiple health parameters 114 of the subject 10 pre-entered in the smart monitoring module 110 stored in the cloud database 50 through the application 410, thereby adjusting the at least one irradiation light source 264 of the phototherapy irradiation module 200 to movably emit light with a wavelength between 420nm and 950nm. The modules/components, connection relationships, functions and effects in the light energy bio-conditioning bracelet device 100 are the same as those in the aforementioned embodiment and will not be repeated here.

The light energy bio-conditioning bracelet device and its system provided by the present invention are installed on the wrist with a low-energy laser diode or light-emitting diode or other light source, so that the light energy can penetrate the skin and affect the veins, arteries, meridians and acupuncture points of the wrist, stimulate the activation of oxygen-carrying red blood cells, stimulate tissue regeneration, and purify the blood, and then use the blood flow to circulate throughout the body to perform light energy bio-conditioning, promote activation and health care functions for various tissues and organs of the body. Specifically, by selectively or interchangeably using different wavelengths of each irradiation light source 264 to emit a light color selection between 420nm and 950nm, it is achieved to promote cell repair and metabolism, eliminate aging cells, and resist aging and rejuvenation, so as to maintain a better state of youth, energy and beauty. Furthermore, the present invention utilizes the physiological characteristics 112 measured by the intelligent monitoring module 110 and the pre-input health parameters 114, so that the subject 10 can adjust the operating parameters 116 of the irradiation light source 264 according to its own condition, thereby being able to more appropriately respond to the needs of the subject 10 and achieve the best disease improvement or health regulation effect.

100: Light-energy bio-conditioning bracelet device

110: Intelligent monitoring module

200: Phototherapy irradiation module

300: Wristband

Claims (16)

A light-energy bio-conditioning bracelet device is worn on a wrist of a subject, and the light-energy bio-conditioning bracelet device comprises: A smart monitoring module is worn on an outer side of the wrist, and the smart monitoring module is used to monitor and display one or more physiological characteristics; A phototherapy irradiation module is worn on an inner side of the wrist relative to the outer side, the phototherapy irradiation module comprises a phototherapy irradiation body and at least one irradiation light source disposed on the phototherapy irradiation body, the irradiation light source can movably emit light of a selective wavelength to the inner side; and a wristband is connected to the smart monitoring module and the phototherapy irradiation module, wherein the at least one irradiation light source of the phototherapy irradiation module is adjusted to movably emit light of a wavelength between 420nm and 950nm according to the physiological characteristics and the multiple health parameters of the subject pre-input into the smart monitoring module. A light-energy bio-conditioning bracelet device as described in claim 1, wherein the intelligent monitoring module includes a touch screen, a microprocessor, a power unit, and one or more sensors for monitoring the one or more physiological characteristics, the touch screen and one or more of the sensors are electrically connected to the microprocessor, the microprocessor includes a built-in communication module for interconnecting information with a cloud database, and the power unit provides power to the microprocessor. A light energy bio-conditioning bracelet device as described in claim 2, wherein the sensor comprises one or a combination of a heart rate blood oxygen sensor, a blood pressure sensor, a body fat sensor, a pulse sensor, a body temperature sensor, a blood lipid sensor, and a pulse sensor. The photo-energy bio-conditioning bracelet device as described in claim 1 also includes a light source control chip that can be selectively installed in the smart monitoring module or the phototherapy irradiation module, and the light source control chip includes multiple operating parameters for controlling and adjusting the at least one irradiation light source, and a storage unit for storing these operating parameters, and these operating parameters include light color power, single light output working cycle, light output wavelength, pulse repetition rate, number of irradiations or peak pulse power. The photo-energy bio-conditioning bracelet device as described in claim 4, wherein when the light source control chip is installed in the phototherapy irradiation module, it also includes a power unit configured to provide power to the light source control chip. A photo-energy bio-conditioning bracelet device as described in claim 1, wherein the phototherapy irradiation body comprises a first insulating layer, a first metal layer, a second insulating layer, a second metal layer and at least one irradiation light source fixing structure stacked in sequence, the first insulating layer is attached to the inner surface, the second metal layer is arranged away from the surface of the second insulating layer, and the at least one irradiation light source fixing structure is movably arranged between the second insulating layer and the second metal layer. As described in claim 6, the at least one illumination light source fixing structure includes a slider, the illumination light source disposed on the slider, and a positioning assembly, and the first insulating layer, the first metal layer, the second insulating layer, and the second metal layer are respectively provided with through holes corresponding to each other. As described in claim 7, the second metal layer includes a plurality of slide grooves arranged along the through holes, and one side of the slider has a lug protruding from the slide groove, and the lug enables the slider to move along one side of the slide groove, and the width of the through hole is less than or equal to the width of the slider. A light-energy bio-conditioning bracelet system includes a cloud database and a light-energy bio-conditioning bracelet device interconnected and communicating with the cloud database, wherein the light-energy bio-conditioning bracelet device is worn on a wrist of a subject, and the light-energy bio-conditioning bracelet system includes: A portable mobile phone including an application program; A smart monitoring module worn on an outer side of the wrist, the smart monitoring module is used to monitor and display one or more physiological characteristics; A phototherapy irradiation module is worn on an inner side of the wrist relative to the outer side, the phototherapy irradiation module comprises a phototherapy irradiation body and at least one irradiation light source disposed on the phototherapy irradiation body, the irradiation light source can movably emit light of a selective wavelength to the inner side; and a wristband is connected to the smart monitoring module and the phototherapy irradiation module, wherein the portable mobile phone reads the physiological characteristics in the cloud database and the multiple health parameters of the subject stored in the cloud database and pre-input into the smart monitoring module through the application, thereby adjusting the at least one irradiation light source of the phototherapy irradiation module to movably emit light with a wavelength between 420nm and 950nm. A light energy bio-conditioning bracelet system as described in claim 9, wherein the intelligent monitoring module includes a touch screen, a microprocessor, a power unit, and one or more sensors for monitoring the one or more physiological characteristics, the touch screen and one or more of the sensors are electrically connected to the microprocessor, the microprocessor includes a built-in communication module for interconnecting information with the cloud database, and the power unit provides power to the microprocessor. A light energy bio-conditioning bracelet system as described in claim 10, wherein the sensor comprises one or a combination of a heart rate and blood oxygen sensor, a blood pressure sensor, a body fat sensor, a pulse sensor, a body temperature sensor, and a blood lipid sensor. The photo-energy bio-conditioning bracelet system as described in claim 9 also includes a light source control chip that can be selectively installed in the smart monitoring module or the phototherapy irradiation module, and the light source control chip includes multiple operating parameters for controlling and adjusting the at least one irradiation light source, and a storage unit for storing these operating parameters, and these operating parameters include light color power, single light output working cycle, light output wavelength, pulse repetition rate, number of irradiations or peak pulse power. The light energy bio-conditioning bracelet system as described in claim 12, wherein when the light source control chip is installed in the light therapy irradiation module, it also includes a power unit configured to provide power to the light source control chip. A photo-energy bio-conditioning bracelet system as described in claim 9, wherein the phototherapy irradiation body comprises a first insulating layer, a first metal layer, a second insulating layer, a second metal layer and at least one irradiation light source fixing structure stacked in sequence, the first insulating layer is attached to the inner surface, the second metal layer is arranged away from the surface of the second insulating layer, and the at least one irradiation light source fixing structure is movably arranged between the second insulating layer and the second metal layer. As described in claim 14, the at least one irradiation light source fixing structure includes a slider, the irradiation light source disposed on the slider, and a positioning assembly, and the first insulating layer, the first metal layer, the second insulating layer, and the second metal layer are respectively provided with through holes corresponding to each other. As described in claim 15, the second metal layer includes a plurality of slide grooves arranged along the through holes, and one side of the slide block has a lug protruding from the slide groove, and the lug enables the slide block to move along one side of the slide groove, and the width of the through hole is less than or equal to the width of the slide block.