KR20190066507A - Device for noninvasive stimulation of brain using light - Google Patents

Abstract

The present invention relates to a device for activating the function of the brain by non-invasive stimulation of the brain using light. A laser light source having a wavelength of 600 to 980 nm is disposed in vitro and is irradiated with a constant parallax, and guides optical fibers to a scalp surface. The light is transmitted through the skull to various places on a cerebral surface and is activated through the stimulation of various cells and tissues which make up the brain, thereby improving malfunction or deterioration of various brain functions by trauma, degenerative brain disease, mental instability and the like.

Description

(Noninvasive stimulation of brain using light)

The present invention relates to a device for noninvasively irradiating a laser having a wavelength of 600 to 980 nm outside the brain to the cerebrum to stimulate various physiological / biological / biochemical reactions and thereby activate the function of brain cells and tissues.

When a laser is irradiated to a living body, light-tissue interaction occurs by being absorbed by various light absorbers present in the living body. Although the precise working principle is not yet fully understood, there are so many studies and presentations that it is not difficult to understand the overall working principle.

When light is irradiated to the living body, it is absorbed by the mitochondrial respiratory chain cytochrome c oxidase (COX). COX contains two Cu centers and two heme-ion centers, which absorb light at 600 to 830 nm. Light from 950 to 1100 nm is also absorbed, which is absorbed by another light absorber, which is thought to be nanostructured water, located in the heat or light-sensitive ion channels.

Light absorbed by COX increases the production of adenosine triphosphate (ATP), the replacement of nitric oxide (NO) from COX, reactive oxygen species (ROS), and reactive nitrogen species (RNS) in mitochondria.

ROS is involved in cell signaling, enzyme activity, nucleic acid synthesis, protein synthesis, transcription factor activity, and activates NF-κB (Nuclear factor kappa-B). NF-κB regulates the expression of genes involved in inflammation, early response (heat sock), anti-apoptosis, cell migration, and cell survival.

Light irradiation increases the expression of growth factors and causes cell proliferation. Growth factors include nerve growth factor, brain-derived neurophic factor, TGF (trasforming growth factor) -beta, vascular endothelial growth factor . The action of these growth factors contributes to the remodeling that occurs in the brain when light is irradiated to the brain.

If the brain is damaged by trauma, degenerative brain disease, mental instability, hypoxia, etc., it will restore the damaged mitochondria in the neurons to the mature neurons, Stimulates synaptic regeneration of disconnected synapses due to damage.

When brain damage occurs, brain blood vessels are damaged and endothelial cells and neurons are damaged. Light heals damaged brain blood vessels and thereby protects neurons.

Indirectly, it protects damaged neurons by activating several immune cells and stem cells contained in the blood vessels, and performing neutrophrotection to collect immune cells and stem cells activated through blood vessels or lymphatics in damaged tissues.

A number of clinical reports of a variety of complex reactions and processes have been combined to show that brain irradiation through the skull in the scalp can lead to trauma (stroke, traumatic brain disease, total cerebral ischemia, etc.), degenerative brain disease (dementia, (Depression, insomnia, anxiety, post-traumatic stress anxiety, etc.), cognitive impairment, and the like.

Although various drugs are prescribed for these diseases for the alleviation or treatment of these diseases, these diseases are not solved due to problems such as drug dependency increase, poor drug effect, recurrence of the etiology and prolonged disease.

The present invention relates to a method and a device for irradiating a laser beam having a wavelength of 600 to 980 nm from a home to a brain by a medical person in a hospital, thereby stimulating non-invasively the various traumas, degenerative brain diseases, and mental instability, Is used to relieve the symptoms or to delay the progress of the disease. It also solves an inconvenient way for users to scan a light source for long periods of time with the light in hand.

In order to achieve the above object, the present invention uses a laser having a wavelength of 600 to 980 nm as a light source. In this case, the light can be used either as a laser having a wavelength of 630 to 650 nm, 808 nm or 980 nm alone, or as a combination of 630 to 650 nm / 808, 630 to 650 nm / 980 or 808/980 nm.

The light source is installed inside the main box, the light irradiation time and the irradiation schedule are controlled through the control board, the power source is the built-in battery, and it is charged with the charger when necessary. If the battery is not charging properly, the battery indicator lights up. The heat inside the main box by the light source is dissipated by the cooling fan.

The light emitted by the laser diode is transmitted through the optical fiber to the optical guide housing and the light from the optical guide housing through the optical fiber is transmitted to the cerebral cortex from the scalp through the skull through the reflector or light guide.

The optical transmission cap is stretched or reduced to fit the size of the user's head, and then secured to the face with a fixing band.

The present invention is a sequela of various trauma, degenerative and mental obstacles, and when the brain is damaged due to various traumas, degenerative and mental disorders, when the laser beam is irradiated to the injured cerebrum, it is absorbed into the intracellular mitochondria to increase ATP, NO, ROS, The brain itself treats itself with a response (nerve regeneration, synaptic regeneration, increased blood flow, transcription factor activity, etc.) and as a result, various symptoms in the brain can be expected to be mitigated, delayed, and cured. This method is noninvasive, simple to use and simple to use, and can be used as an adjunctive therapy when there is a limit to existing drug therapy.

1 is a view showing a main box and an optical transfer cap.
FIG. 2 is a plan view of a light guide housing to be positioned at the frontal lobe and has a curved and curved planar structure without a light guide projecting thereon, and has a control band at both ends.
FIG. 3 shows a light guide protruding from a light guide housing to be located in both temporal, parietal, and occipital lobes to reduce light loss due to hair, and has a control band on both ends.
4 is a block diagram of a non-invasive stimulation device of the brain using light.

The present invention irradiates the laser in the direction of the cerebral cortex from the outside of the body, thereby causing a disorder in function, thereby activating the brain in various pathological states, thereby alleviating, delaying, and healing the disorder. It utilizes a unique characteristic that activates its own function when a living body including the brain responds to light. In doing so, it can be used as an adjunctive therapy in cases where the drug is dependent on long - term medication for relief or treatment of this pathology and, in many cases, drug - dependent or when the drug is no longer active.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 1 shows a non-invasive stimulation device of the brain using light.

The present invention

A main box 10 in which a light source and an operation part are incorporated, and a light transmission cap 30 in which the ends of the light guide are gathered.

In the main box, there are a light source, an optical fiber unit 11 and an operation unit 20.

The laser diode 12 as a light source can use a laser having a wavelength of 630 to 650 nm, 808 nm and 980 nm alone or in combination of 630 to 650 nm / 808, 630 to 650 nm / 980 and 808/980 nm, Box.

The light from the laser diode passes through a lens (13) located in front of the laser diode and then enters a contact (14) located in front of the lens. At the end of the connector, there is an optical fiber 15, and the light passing through the connector enters the optical fiber.

Since there are many laser diodes in the main box and therefore the number of optical fibers is the same, a main body can be complicated with optical fibers. To avoid this, the optical fibers are again divided into five bundles. These five bundles are equal to the number of the light guide housings 31 to be located at various positions on the head.

The light guide housing is located at the frontal, temporal, parietal, and occipital lobes. However, these five bundles in the main box are again bundled together and wrapped in a coaxial cable 16.

The operation unit 20 of the main box is provided with a power switch 21 to turn on / off the device. The continuous or pulse repetition rate and the light irradiation parallax in each light source can be adjusted through the control board 22 and the light irradiation time can be set by the timer 23. When each light source irradiates it with a parallax, light irradiation takes place in a relay manner, and it is like a user scrolls a light source in a hand and scans over the head.

The power supply can be built-in battery or can be connected to an external power supply. If the battery power is low, the battery indicator (24) lights up.

Since the inside of the main box is heated by the light source and the control board, the cooling fan 25 is operated while the power is on to cool the internal heat.

When the remaining battery power is low and the battery indicator lights up, connect the charger 26 to the external power source to charge the battery.

The coaxial cable has a certain length and its end goes to the optical transfer cap 30. The five bundles of optical fibers in the coaxial cable in the optical transmission cap are again divided into bundles and distributed to the light guide housing 31 on the frontal, temporal, parietal, and occipital lobes.

Each light beam arriving at the light guide housing and the light from the end thereof are reflected on the reflector 32 in the case of the frontal lobe to be irradiated on the scalp of the forehead. With the exception of baldness, the scalp is usually covered with hair, so light is absorbed in the hair. In order to avoid this, the other part except for the frontal lobe is irradiated on the light guide 33 which is reflected by the reflector and has a sharp tip, and the end of the light guide is brought into contact with the scalp to reduce light loss by the hair.

Since the size of the head is different for each user of the optical transmission cap, the user adjusts the adjustment band 40 in the light transmitting cap to fit the head, and the fixing band 41 is mounted on the bottom of the chin To prevent movement.

10: main box 11: light source and optical five part
12: laser diode 13: lens
14: Connect 15: Optical Five
16: Coaxial cable 20: Operation part
21: power switch 22: control board
23: Timer 24: Battery indicator
25: charger 26: cooling fan
30: optical transmission cap 31: light guide housing
32: reflector 33: light guide
40: Adjusting band 41: Fixing band

Claims (9)

And non-invasively irradiating the laser light to the cerebral cortex so that the damaged brain function is activated. The non-invasive stimulation apparatus for a brain using the light according to claim 1,
A main box and an optical transfer cap;
The main box has a light source and a light transmission unit and an operation unit;
Non-invasive stimulation of the brain using light with a light guide housing, a control band and a fixation band for the optical transfer cap. Claim 1 is a non-invasive stimulation apparatus for a brain using light having a wavelength of 808/980 nm as a light source. In claim 2, the light source and the optical transmission unit include a laser diode, a lens for collecting light, an optical connector for connecting the optical fiber for transmitting the collected light, and a coaxial cable for bundling all the optical fibers from the optical connector. Noninvasive stimulation device. The non-invasive brain stimulation apparatus according to claim 2, wherein the operation unit includes a power switch, a control board, a timer, a battery indicator, a cooling fan, and a charger. The optical fibers bundled with the coaxial cable are guided to the optical guide housing;
Wherein the light emitted from the optical fiber is reflected by a reflector provided in the optical guide housing and is transmitted directly or through a light guide to the cerebral cortex from the scalp. The light non-invasive stimulation apparatus of claim 1, wherein the light transmission cap is appropriately adjusted to fit the patient's head using a control band and is fixed to the face with a fixing band. In claim 2, the light guide housing has a frontal lobe, a temporal lobe, a parietal lobe, and an occipital lobe;
Wherein the tip of the light guide housing at both temporal, parietal, and occipital lobes protrudes like a tip of a comb due to the light guide. In claim 5, the control board adjusts the pulse length of the light to make the light pulse a continuous or constant pulse;
Characterized in that the light irradiation takes place in a relay manner with a constant parallax.

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