KR20210009594A - Ear bud having nir led - Google Patents

Abstract

An object of the present invention is to provide an earbud having a near-infrared irradiating part capable of stimulating the deep part of the brain, the cerebral cortex, the facial nerve, the vagus nerve, and the like. The earbud having a near-infrared irradiating part comprises: a housing in which a sound output device and a control part are installed; a tube protruding from one side of the housing and inserted into a user′s ear canal; a sound emission port formed at one end of the tube; and a near-infrared irradiating part installed around the sound emission port at one end of the tube.

Description

Earbuds with near-infrared irradiation unit {EAR BUD HAVING NIR LED}

The present invention relates to a near-infrared irradiation unit earbud.

Traumatic brain injury (TBI), stroke, multiple sclerosis (MS), schizophrenia, autism, insomnia, post-traumatic stress disorder (PTSD), dementia and Alzheimer's disease (Alzheimer's), Parkinson's disease (Parkinson's) And in the case of the treatment using drugs for chronic brain diseases such as a number of other neurological conditions and disorders, there are many side effects and disadvantages.

One of the alternative therapies for this, brain stimulation, has been in use for some time, based on the fact that the nervous system responds to these techniques in a practical way. Many of these technologies are based on electromagnetic shock.

Brain stimulation can be broadly divided into invasive brain stimulation and non-invasive brain stimulation. As an invasive brain stimulation technique, electric stimulation through implanted eletrodes can be exemplified, and it is a method of controlling abnormal neural circuits by inserting electrodes into the brain base and applying electrical stimulation. In the case of electrode insertion brain stimulation, deep brain (thalamic, basal ganglia, hypothalamus ganglia of the brain) can be stimulated. Therefore, it is used as a treatment method to improve symptoms of abnormal motor diseases such as Parkinson's disease, essential tremors, and dystonia. There is a disadvantage in that it requires surgery to insert electrodes and stimulation generators into the body.

Non-invasive brain stimulation techniques include Transcranial Magnetic Stimulation (TMS) and Transcranial Direct-Current Stimulation (TDCS). TMS and TDCS technologies have low penetrating power and cannot stimulate the center of the brain.

In addition, ultrasound brain stimulation (Transcranial Ultrasound Stimulation) and near-infrared stimulation (Near-Infrared Stimulation (NIS)) are safe compared to invasive brain stimulation methods, and, unlike TMS and TDCS, stimulation to the deep brain is possible.

In near-infrared (NIR), mitochondrial CCO enzyme (Cytochrome C Oxidase) absorbs near-infrared rays, increasing the production of ATP (Adenosine triphosphate; the main energy source in the human body). In addition, it stimulates vascular endothelial cells and red blood cells to increase production of nitric oxide (NO, Nitric Oxide; prevents blood clotting, relaxes smooth muscles). The CCO stimulation effect is best at a wavelength of 810nm. When ATP increases, it promotes cell metabolism and energy to regenerate cells and prevent cell death. When NO increases in the body, blood vessels expand, blood flow increases, and the amount of oxygen supplied to the brain increases, thereby improving memory and cognitive functions.

These near-infrared rays can pass through the skull and penetrate the brain. It can penetrate through the skull and scalp to an average depth of 23.6mm (depth from the scalp) (when shaved). However, the near-infrared wavelength decreased the transmittance of the hair, and there was a blind spot that more than 85% of the near-infrared energy irradiated on the scalp was absorbed by the scalp and skull. In the ear canal, there are no hairs and the skull is pierced (external acoustic meatus). Therefore, when the near-infrared rays are irradiated through the external ear canal, the hair, skull, and scalp that can absorb the near-infrared rays are less affected, and if the near-infrared rays are irradiated from both directions, intensive light stimulation (focusing) is possible in the center of the brain. There is this.

On the other hand, at normal body temperature (36.5℃), the temperature distribution of the brain is 35.6 ~ 36.1℃, and when the temperature of the brain reaches 42℃, the brain tissue is denatured or destroyed by heat. It becomes dangerous if the brain temperature rises above 6℃ in the normal temperature distribution.

NIR irradiation can be a factor in increasing brain temperature. Therefore, it is possible to control the increase in temperature by repeatedly applying the NIR to the wavelength of a short pulse width. The pulse width and frequency and duration of irradiation should be adjusted, and the adjustable range should be limited to prevent temperature rise.

1 is an earphone capable of preventing and treating otitis media according to the prior art, and includes a housing 10, a speaker 20, a substrate 30, a Bluetooth module, and a control unit. A convex portion 11 protruding in the front direction of the housing 10 is formed on the upper front side of the housing 10. A sound conduit 11a extending horizontally to a predetermined length in a direction outside the front side of the convex part 11 is provided on the front outer peripheral surface of the convex part 11 to communicate with the convex part 11. Holes 11b may be radially formed at equal intervals on the front side of the convex portion 11 around the sound conduit 11a based on the sound conduit 11a.

The speaker 20 is provided in the inner middle of the convex portion 11a of the housing 10 to emit sound such as MP3 through the sound conduit 11b. Next, the substrate 30 is provided inside the convex portion 11a of the housing 10 so as to be positioned around the speaker 20. The substrate 30 may be provided with light emitting portions 31 that emit light in the direction of the hole 11c of the convex portion 11a at regular intervals.

The light-emitting unit 31 may be formed of various types such as a light-emitting diode that irradiates light in the visible or infrared band for the treatment of ear diseases such as otitis media into the user's ear through the hole 11c of the convex part 11. have.

However, the earphones capable of preventing and treating otitis media according to the prior art are not provided with the light emitting part 31 on the ear buds, but are installed on the substrate 30 provided inside the housing 10 and are reflected toward the ear buds. By providing a reflective structure, there is a disadvantage in that the manufacturing process is complicated and the manufacturing cost is increased.

Korean patent registration number 10-1912166

An object of the present invention is to provide an earbud having a near-infrared irradiation unit capable of stimulating a deep part of the brain, a cerebral cortex, a facial nerve, a vagus nerve, and the like.

The present invention is a housing in which the sound output device and the control unit are installed; A conduit protruding from one side of the housing and inserted into the user's ear canal; An acoustic discharge port formed at one end of the pipe; It provides an earbud having a near-infrared irradiation unit including; and a near-infrared irradiation unit installed around the sound emission port at one end of the pipe.

In addition, as another example of the present invention, there is provided an earbud provided with a near-infrared irradiation unit, characterized in that a partition wall is installed between the sound emission port and the near-infrared irradiation unit in a pipe.

In addition, as another example of the present invention, the near-infrared irradiation unit provides an earbud provided with a near-infrared irradiation unit, characterized in that it is installed at a position that does not interfere with transmission of sound emitted through the sound emission port.

In addition, as another example of the present invention, it provides an earbud having a near-infrared irradiation unit, characterized in that it further comprises at least one auxiliary near-infrared irradiation unit installed around the pipe of the housing.

The earbuds provided with the near-infrared irradiation unit provided by the present invention have the advantage that the near-infrared radiation irradiated by installing the near-infrared irradiation unit in the pipe inserted into the external ear canal can stimulate the deep part of the brain to avoid the skull having a high near-infrared absorption rate. In addition, there is an advantage in that it can stimulate the deep part of the brain, cerebral cortex, facial nerve, and vagus nerve by avoiding cartilage with near-infrared rays irradiated by the auxiliary near-infrared irradiation unit installed around the pipeline.

In addition, the earbuds provided with the near-infrared irradiation unit provided by the present invention have the advantage that interference does not occur because the near-infrared irradiation unit does not block the acoustic path by arranging the near-infrared irradiation unit parallel to the sound emission port.

1 is a view showing an earphone capable of preventing and treating otitis media according to the prior art;
2 is a cross-sectional view showing an earbud having a near-infrared irradiation unit according to a first embodiment of the present invention;
Figure 3 is a front view showing an earbud having a near-infrared irradiation unit according to the first embodiment of the present invention,
4 is a view showing a state that the user wears the near-infrared irradiation unit according to the first embodiment of the present invention;
5 is a cross-sectional view showing an earbud having a near-infrared irradiation unit according to a second embodiment of the present invention;
6 is a front view showing an earbud having a near-infrared irradiation unit according to a second embodiment of the present invention,
7 is a cross-sectional view showing an earbud having a near-infrared irradiation unit according to a third embodiment of the present invention;
8 is a side view showing an earbud having a near-infrared irradiation unit according to a third embodiment of the present invention;
9 is a view showing a user wearing an earbud having a near-infrared irradiation unit according to a third embodiment of the present invention;
10 is a block diagram for explaining the interworking of an earbud and a smart device having a near-infrared irradiation unit according to the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

2 is a cross-sectional view showing an earbud having a near-infrared irradiation unit according to a first embodiment of the present invention, and FIG. 3 is a front view showing an earbud having a near-infrared irradiation unit according to the first embodiment of the present invention. An earbud having a near-infrared irradiation unit according to the first embodiment of the present invention has a housing 100 forming an exterior, and an acoustic output device 200 and a control board (not shown) in the housing 100, and a near-infrared ray An irradiation unit 300 or the like is installed, and a battery (not shown) may be installed if necessary. One side of the housing 100 is provided with a conduit 120 protruding so as to be easily inserted into the user's ear canal. One end of the conduit 120 is opened to form an acoustic discharge port 130. The sound generated by the sound output device 200 is transmitted to the user's ear through the sound discharge port 130 through the pipe 120. On the other hand, one side of the opening of the conduit 120 is formed with a near-infrared emission port 140 through which the near-infrared rays are emitted. That is, the conduit 120 is partitioned by the partition wall 104, and one area is used as the sound emission port 130 and the other area is used as the near-infrared emission port 140.

The sound output device 200 and the near-infrared irradiation unit 300 may be installed on a bracket 102 provided in the housing 100. The near-infrared irradiation unit 300 is preferably an LED capable of irradiating near-infrared rays, and irradiates light in a near-infrared band in the range of 750 nm to 1300 nm. During light irradiation, the near-infrared pulse width length and frequency can be changed, and the light irradiation time can be controlled. Such light control can be performed by an application of a computer or smart device connected to the earbuds by wire or wirelessly. In addition, in order to prevent excessive temperature rise, the range of the usable pulse width length, frequency, and duration of light irradiation is limited. For example, it is possible to limit the range of the pulse width to 3 ms to 15 ms, the frequency to 10 Hz to 50 Hz, and the duration of light irradiation to a maximum of 1 minute per time.

4 is a view showing a state that a user wears the near-infrared irradiation unit according to the first embodiment of the present invention. When a user wears earbuds 1 and 2 provided with near-infrared irradiation units on both ears, the irradiated near-infrared rays may stimulate the deep brain 3. Since light is irradiated through the empty space of the skull (the ear canal), it has the advantage of being able to stimulate deeper places than when stimulating through the scalp. In addition, near-infrared stimulation increases blood flow and oxygen supply to the brain, thereby improving memory and cognitive function. If the near-infrared rays are irradiated from both earbuds (1, 2), there is an advantage that intensive light stimulation (focusing) is possible in the deep part of the brain (3).

Figure 5 is a cross-sectional view showing an earbud having a near-infrared irradiation unit according to a second embodiment of the present invention, Figure 6 is a front view showing an earbud having a near-infrared irradiation unit according to a second embodiment of the present invention It is a drawing. The earbud according to the second embodiment of the present invention is different from the first embodiment in that a near-infrared irradiation unit 300a is installed at the end of the pipe 120a. At this time, a separate partition wall is not installed in the pipe 120a, but it is installed in a position that does not interfere with sound transmission from the pipe 120a, avoiding the installation position of the sound output device 200a. In the drawing, the sound output device 200a is installed at a position capable of transmitting sound through the lower portion of the pipe 120a, and the near-infrared irradiation unit 300a is located above the cross-section of the pipe 120a.

7 is a side view showing an earbud having a near-infrared irradiation unit according to a third embodiment of the present invention, and FIG. 8 is a front view showing an earbud having a near-infrared irradiation unit according to a third embodiment of the present invention. Earbuds having a near-infrared irradiation unit according to the third embodiment of the present invention have a near-infrared irradiation unit (300b) installed at the end of the conduit (120b), and when worn, the user's cerebral, deep brain, facial nerve, or vagus nerve An additional near-infrared irradiation unit 310b is installed at a position capable of stimulation.

9 is a view showing a state that a user wears an earbud having a near-infrared irradiation unit according to a third embodiment of the present invention. As shown in the figure, the near-infrared radiation irradiated by the near-infrared irradiation unit 300b optically stimulates the deep part of the brain as in the first embodiment, and the additional near-infrared irradiation unit 310b, respectively, depending on the installation position, the vagus nerve, the cerebral cortex, It stimulates the facial nerves and the like. At this time, it is preferable that the additional near-infrared irradiation unit 310b is located in a portion not in contact with the cartilage to increase the transmission rate of the near-infrared ray.

The vagus nerve is the tenth pair of cranial nerves from the soft water, the largest of the parasympathetic nerves, and plays a role in controlling unconscious body functions such as breathing, digestion, and heart rate. Vagus verve stimulation is also used to treat depression, and other mental disorders such as dementia, schizophrenia, and autism have also been tried.

The facial nerve is a complex nerve in which motor and sensory nerves work together. It is involved in the movement of facial muscles, peripheral muscles of the eyeball, muscles around the mouth and lips, and muscles in charge of the middle ear, and regulates the secretion of lacrimal and salivary glands by engaging in taste fibers. .

The cerebral cortex is a collection of nerve cells located on the cerebral surface, and is responsible for important functions such as memory, concentration, thinking, language, awakening, and consciousness. When stimulating the cerebral cortex, it is effective in treating depression, obsessive-compulsive disorder, and chronic pain, and improving memory and cognition by increasing blood flow.

10 is a block diagram for explaining interworking of an earbud having a near-infrared irradiation unit and a smart device according to the present invention. As shown in the figure, the earbuds having a near-infrared irradiation unit may be operated in conjunction with a smart device 600 having a microcontroller 400 and a short-range wireless communication unit 500. For example, data such as light irradiation time, near-infrared pulse width, and frequency are pre-stored in the smart device 600, and wireless communication is performed by the short-range wireless communication unit 500 through, for example, Bluetooth communication. When data is selected in the smart device 600, the user selects data information from the smart device 600 through the short-range wireless communication unit 500, and the microcontroller 400 receives the data information selected by the smart device 600 from the short-range wireless communication unit 500. 600), the near-infrared irradiation unit 300 controls the near-infrared irradiation unit 300 by receiving the data information selected by the user. In addition, according to an embodiment, data such as light irradiation time, near-infrared pulse width, and frequency are previously stored in the microcontroller 400, and wireless communication is performed by, for example, Bluetooth communication by the short-range wireless communication unit 500. While the user inputs specific data from the smart device 600, the microcontroller 400 receives the data information input by the user from the smart device 600 through the short-range wireless communication unit 500, and selects the user from among the previously stored data. The near-infrared irradiation unit 300 irradiates light according to the data input by the user by controlling the near-infrared irradiation unit 300 according to the information of the data input by the smart device 600.

Claims (4)

A housing in which an acoustic output device and a control unit are installed;
A conduit protruding from one side of the housing and inserted into the user's ear canal;
A sound discharge port formed at one end of the pipe; And
Earbuds having a near-infrared irradiation unit including a; near-infrared irradiation unit installed around the sound emission port at one end of the pipe. The method of claim 1,
Earbuds having a near-infrared irradiation unit, characterized in that the partition wall is installed between the sound emission port and the near-infrared irradiation unit in the pipe. The method of claim 1,
Earbuds having a near-infrared irradiation unit, characterized in that the near-infrared irradiation unit is installed at a position that does not interfere with transmission of sound emitted through the sound emission port. The method of claim 1,
Earbuds having a near-infrared irradiation unit, characterized in that it further comprises; one or more additional near-infrared irradiation units installed around the conduit of the housing.

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