CN115364330B - Gamma brain wave central nervous system organic disease prevention and treatment glasses - Google Patents

Abstract

The application belongs to the technical field of medical instruments and equipment, and particularly relates to a pair of glasses for preventing and treating organic diseases of a gamma brain wave central nervous system. The device comprises a spectacle frame, a composite lens, a light source dot matrix, a control unit, a power supply unit and a respiration sensing mechanism; a scene module, a breath following module, an audio synchronization module and a 40Hz audio source are arranged in the control unit. According to the application, through the cooperation of the respiration sensing mechanism and the control unit, a respiration scene with the frequency of 40Hz can be formed on the lens through the light source lattice, dynamic elements in the scene can ascend or descend along with the respiration of a wearer through the regulation and control of the respiration following module, and meanwhile, the audio unit can also play out exhalation sound and inhalation sound consistent with the respiration. Therefore, when a wearer uses the glasses, the breathing rhythm and the breathing depth of the wearer can be actively observed and adjusted, the mental condition of the wearer is passively adjusted after the passive breathing rhythm and the breathing depth of the wearer are actively adjusted, and the use effect of autonomously generating gamma brain waves through 40Hz acousto-optic induction is achieved.

Description

Gamma brain wave central nervous system organic disease prevention and treatment glasses

Technical Field

The application belongs to the technical field of medical instruments and equipment, and particularly relates to a pair of glasses for preventing and treating organic diseases of a gamma brain wave central nervous system.

Background

Brain waves, also known as brain waves, are bioelectric signals that are generated when information is transferred between neuronal cells. In 1929, the german psychiatrist hans-berg (Hence berg) first published an electroencephalogram (EEG), in which there were mentioned five different brain waves of the human brain: alpha (alpha), beta (beta), gamma (gamma), delta (delta) and theta (theta) waves.

Name of the name	Frequency band/Hz	Representation of
			Delta wave	0.2-3	Sleep mode
Theta wave	3-8	Depth anti-loose
			Alpha wave	8-12	Anti-loose state
Beta wave	12-27	Alert and concentration of attention
			Gamma wave	＞27	The learning, memorizing and processing transactions are all in a better state

The brain wave related research provides favorable biological indexes for our cognitive brains or diagnosis and screening of early disease and disorder, such as early Alzheimer disease and other neurodegenerative diseases, which provides better treatment schemes for patients.

Gamma rays, namely gamma rays, are the spectrum of the section with the shortest wavelength and highest frequency in the electromagnetic spectrum, and the frequency range of the gamma rays is 10-12 Hz at the lowest and can reach more than 10-30 Hz at the highest. The new coronavirus has a size of about 100nm, the longest gamma ray wave band is only 0.1nm, and the frequency is more than trillion times per second of vibration. One of the medical applications of gamma rays is gamma knife. For purposes of illustration, gamma rays and gamma brain waves are different

A40 Hz light stimulation experiment based on a mouse model proves that senile dementia mice receive 40Hz flash light for 1 hour every day for 3-6 weeks, and the visual cortex V1, the somatosensory cortex SS1 and the sea of the miceThe flash light of several brain regions of horse CA1, forehead lobe (PFC), induces gamma brain waves of approximately the same frequency. That is, 40Hz blinking may be effective in reducing neuronal death. The Morse water maze Morris water maze experiment proves that the 40Hz light stimulation can effectively improve the spatial learning and memory capacity of the mice. [ the content of this paragraph comes from the article 40Hz sensory stimulation to significantly improve senile dementia symptoms ], the website links are:https://zhuanlan.zhihu.com/p/86374800。】

the people net life time article "usual practice meditation, brain aged slow" shows that meditation has various benefits for the old: the anti-autism and anti-senile dementia can obviously reduce slight cognitive impairment of the old, prevent occurrence of other dementia diseases and promote circulation. [ Link:http://health.people.com.cn/n1/2020/0728/c14739-31800723.html】

in 2004, the Proc. Nature Acad.Sci.USA published a study by Dr. Antoine Lutz et al, entitled "spontaneous gamma high frequency brain waves (Long-term meditators self-input high-amplitude gamma synchrony during mental practice) produced by Long-term Buddhist repairmen in mental experiments", this report shows that Long-term sitting meditation can induce gamma waves with high frequency, the frequency of which is between 25 and 42Hz, the frequency of which is between 4 and 13Hz, and the frequency of which is also as high as 80 and 120Hz. The gamma frequency is from the visual colliculus and the inferior visual colliculus.

In view of the effect of 40Hz light waves and audio on inducing gamma brain waves and the beneficial effects of the gamma brain waves on preventing and treating organic diseases of the central nervous system such as neurodegenerative diseases of Alzheimer's disease, the development of a gamma brain wave central nervous system organic disease prevention and treatment instrument is necessary, the market gap is filled, and the prevention and treatment of the organic diseases of the central nervous system are assisted in clinic.

Disclosure of Invention

The application adopts 40Hz light wave and/or sound wave as induction factors, and enables a patient to actively observe and adjust own breathing rhythm and breathing depth by constructing a scene suitable for generating gamma brain waves, and the application achieves the effect of autonomously generating the gamma brain waves through induction by passively and then actively adjusting own emotion condition.

The application provides a solution for solving the technical problems that:

a pair of gamma brain wave glasses for preventing and treating organic diseases of central nervous system is characterized in that: comprises a spectacle frame, a composite lens, a light source dot matrix, a control unit and a power supply unit; the composite lens comprises a front lens and a rear lens, and the front lens and the rear lens are fixedly connected; the light source lattice is arranged between the front lens and the rear lens; the control unit and the power supply unit are arranged on the glasses frame; the power supply unit is electrically connected to the control unit and the light source dot matrix; the light source dot matrix is electrically connected with the control unit; the light source lattice comprises a plurality of LED light sources, and the light source lattice can emit light waves with the frequency of 40Hz under the regulation and control of the control unit.

Preferably, the gamma brain wave central nervous system organic disease prevention and treatment glasses further comprise a respiration sensing mechanism, wherein the respiration sensing mechanism comprises a respiration state probe, a probe bearing part and a probe mounting belt; the probe bearing component is of a cavity structure, a plurality of air holes are formed in the cavity structure, and the breathing state probe is arranged in the cavity structure of the probe bearing component and is electrically connected to the control unit; the probe mounting belt is connected to the spectacle frame, and the probe bearing component is connected to the mounting belt; a scene module and a breath following module are arranged in the control unit; the scene module is used for constructing a breathing scene by controlling the LED light sources in the light source dot matrix, the breathing scene comprises background elements and dynamic elements, and the breathing following module is used for determining the motion state of the dynamic elements according to the breathing state transmitted by the breathing state probe; when the scene module builds a breathing scene, the luminous frequency of the LED light source in the light source dot matrix is 40Hz.

Preferably, the breath following module is configured to determine a motion state of the dynamic element according to a breath state transmitted from the breath state probe, and refers to: when the breathing state transmitted by the breathing state probe is an expiration state, the motion state of the dynamic element is rising motion; when the respiration state transmitted by the respiration state probe is the inspiration state, the motion state of the dynamic element is the descending motion. Further preferably, the dynamic element is a sphere.

Preferably, the respiration state probe is any one or any combination of a temperature sensor, an oxygen sensor and a carbon dioxide sensor.

Preferably, the gamma brain wave central nervous system organic disease prevention and treatment glasses further comprise an audio playing unit, an audio synchronization module and a 40Hz audio source are further arranged in the control unit, and the audio synchronization module is used for selecting the music types played by the audio playing unit in the 40Hz audio source according to the breathing state transmitted by the breathing state probe.

Preferably, the audio synchronization module is configured to select a music category played by the audio play unit in the 40Hz audio source according to the respiration status transmitted by the respiration status probe, which means that: when the breathing state transmitted by the breathing state probe is the breathing state, the audio synchronization module is used for matching 40Hz breathing audio for the audio playing unit; when the breathing state transmitted by the breathing state probe is the inspiration state, the audio synchronization module is used for matching 40Hz inspiration audio for the audio playing unit.

Preferably, the probe bearing component has a hollow sphere structure, the air hole is arranged on the hollow sphere structure, and the breathing state probe is arranged in the hollow sphere structure.

Preferably, the power supply unit is a lithium ion battery.

Preferably, the gamma brain wave central nervous system organic disease prevention and treatment glasses can also adopt a respiration sensing mechanism with another structure, and the respiration sensing mechanism comprises an air outlet switch, an air suction switch, a swing needle rotating shaft, a bearing component and a connecting piece; the bearing part is connected to the connecting piece, and the connecting piece is used for connecting the bearing part to the eyeglass frame; a cavity structure is arranged in the bearing component, and the air outlet switch, the air suction switch, the balance needle and the balance needle rotating shaft are all assembled in the bearing component; the swing needle rotating shaft is fixed on the bearing component, the swing needle is hinged on the swing needle rotating shaft, and the air outlet switch and the air suction switch are respectively assembled at positions corresponding to two contact points on two sides of the swing needle when the swing needle swings; a swing needle air hole is arranged on the bearing component corresponding to the region of the swing needle above the swing needle rotating shaft; a scene module and a breath following module are arranged in the control unit; the scene module is used for constructing a breathing scene by controlling the LED light sources in the light source dot matrix, the breathing scene comprises background elements and dynamic elements, and the breathing following module is used for determining the motion state of the dynamic elements according to the breathing state transmitted by the air outlet switch or the air suction switch; when the scene module builds a breathing scene, the luminous frequency of the LED light source in the light source dot matrix is 40Hz.

The beneficial technical effects are as follows:

1. according to the application, through the cooperation of the respiration sensing mechanism and the control unit, a gamma brain wave scene with the frequency of 40Hz can be formed on the lens through the light source lattice, dynamic elements in the scene can ascend or descend along with the respiration of a wearer through the regulation and control of the respiration following module, and meanwhile, the audio unit can also play out exhalation sound and inhalation sound consistent with the respiration. Therefore, when a wearer uses the glasses, the breathing rhythm and the breathing depth of the wearer can be actively observed and adjusted, the mental condition of the wearer is passively adjusted after the wearer is actively adjusted, and the effect of autonomously generating gamma brain waves through induction is achieved.

2. The front lens (outer lens) of the composite lens can be made black, the rear lens (inner lens) and the LED lamp panel are made transparent, and the use effect of the sunglasses is formed when the composite lens is worn, so that the composite lens can be used as normal glasses, and can also have medical care effect at any time, and the psychological burden of a patient is reduced.

The technical scheme and technical effects of the present application are described in detail below with reference to the drawings and the detailed description of the specification.

Drawings

Fig. 1: the structure of the preferred embodiment is schematically shown;

fig. 2: FIG. 1 is a schematic cross-sectional view of a composite lens;

fig. 3: a schematic structural diagram with a breath sensing mechanism;

fig. 4: FIG. 3 is a schematic diagram of a breath sensing mechanism;

fig. 5: a control unit functional block diagram;

fig. 6: a step diagram for realizing a breath following function;

fig. 7: a schematic diagram of a swing needle type respiration sensing mechanism structure;

identification description:

10-a spectacle frame, 20-a composite lens, 30-a light source lattice, 40-a control unit, 50-a power supply unit and 60-a respiration sensing mechanism;

210-front lens, 220-rear lens;

610-respiratory state probe, 620-probe bearing component, 6210-air hole, 630-probe mounting belt;

61-air outlet switch, 62-air suction switch, 63-balance needle, 64-balance needle rotating shaft, 65-bearing part and 66-connecting piece.

Detailed Description

Referring to fig. 1 to 6, the glasses for preventing and treating organic diseases of the gamma brain central nervous system according to the preferred embodiment of the present application comprises a glasses frame 10, a composite lens 20, a light source lattice 30, a control unit 40, a power supply unit 50 and a respiration sensing mechanism 60.

Referring to fig. 2, the composite lens 20 includes a front lens 210 and a rear lens 220, and the front lens 210 and the rear lens 220 are fastened together; the light source lattice 30 is disposed between the front lens 210 and the rear lens 220. The light source lattice 30 comprises a plurality of LED light sources, and the light source lattice 30 can emit light waves with the frequency of 40Hz under the control of the control unit 40. The specific structure of the light source lattice 30 can be an LED lamp board which is matched with the shape and the position of the lens, and the LED lamp board is provided with an LED light source in a patch or pin way. And a circuit structure of the LED light source is printed in the LED lamp panel. The front lens 210 and the rear lens 220 can be fastened by a process such as a snap connection, a screw connection or an environment-friendly adhesive. The positive and negative lines of the light source lattice 30 can be led out from the edge of the mirror frame and then connected to the control unit 40 and the power supply unit 50 through the mirror legs on both sides.

The front lens 210 of the composite lens is preferably black, the rear lens 220 and the LED lamp panel are preferably transparent, and the use effect of the sunglasses is formed when the composite lens is worn, so that the composite lens can be used as normal glasses, can also have medical care effect at any time, and reduces psychological burden of patients.

The control unit 40 and the power supply unit 50 are both provided on the frame 10, and the installation position can be changed in many ways, and the preferred installation scheme is shown in fig. 1, wherein the control unit 40 and the power supply unit 50 are respectively assembled in two ear hooks of the frame 10. The electrical connection between the light source array 30, the control unit 40 and the power supply unit 50 is accomplished by electronic circuitry fabricated within the frame 10. The control unit 40 and the power supply unit 50 may also be assembled simultaneously in the same ear-hook to shorten the wiring length therebetween. The preferred scheme is that the control unit 40 and the power supply unit 50 are made into a module, the control unit 40 adopts a PCB circuit board, the power supply unit 50 adopts a lithium ion battery, and the lithium ion battery is directly fixed on the back of the PCB circuit board, so that the compactness of the device is improved. In order to ensure the power supply effect, the size of each part of the frame 10 can be increased and thickened to meet the assembly requirements of the control unit 40, the power supply unit 50, the audio playing unit and other components.

The power supply unit 50 is electrically connected to the control unit 40, the light source dot matrix 30 and the audio playing unit; the audio playing unit, the light source lattice 30 and the control unit 40 are electrically connected.

Referring to fig. 3 and 4, respiration sensing mechanism 60 includes a respiration status probe 610, a probe carrier 620, and a probe mounting belt 630. The probe bearing part 620 has a hollow sphere structure, a cavity is formed in the probe bearing part 620, a plurality of air holes 6210 communicated with the cavity are formed in the sphere, and the breathing state probe 610 is fixed in the cavity structure of the probe bearing part 620 and is electrically connected to the control unit 40; the probe mounting strap 630 is attached to the holster 10 and the probe carrier 620 is attached to the probe mounting strap 630. The probe mounting belt 630 is an elastic and ductile belt-shaped member, both ends of which are fixed to both side portions of the frame 10, and the probe carrier 620 can be fixed between the two frames of the frame 10 by elastic restoring force of the belt-shaped member when not in use. The user's breathing state can be detected by pulling the probe carrier 620 to be fixed under the nose or between the nose and the mouth at the time of use. In some alternative embodiments, the probe carrier 620 may be configured to engage the oronasal portion of a person, and in use, the carrier 620 is positioned over and engages the oronasal portion to improve respiratory condition monitoring.

The probe carrier 620 having a hollow sphere structure may be implemented by a method in which two hemispheres are formed into a finished sphere. The inner part is firstly installed, and then the two hemispheres are fastened into a whole by adopting a bonding or welding or tightening mode.

The gas detected by the breath state probe 610 is real-time exhaled gas when exhaled against the probe carrier 620, and the gas detected by the breath state probe 610 is real-time inhaled air when inhaled against the probe carrier 620. The temperature, oxygen content and carbon dioxide content are all very different from those of the exhaled air of the human body. Specifically, the content of oxygen in the air is larger than the content of oxygen in the air exhaled by the human body, the content of carbon dioxide in the air is smaller than the content of carbon dioxide in the air exhaled by the human body, and the temperature of the air is lower than the temperature of the air exhaled by the human body. Thus, any one or any combination of a temperature sensor, an oxygen sensor, and a carbon dioxide sensor may be employed to detect the breathing state of the wearer by detecting the temperature, oxygen content, and carbon dioxide content of the gas. Taking the oxygen content as an example, if the oxygen content of the current gas is lower than the conventional oxygen content in the air, but is relatively close to the oxygen content of the normal exhaled gas of the human body, the current breathing state is determined to be the exhaled gas state. At this time, the dynamic element is instructed to rise, and the air outlet audio is played at the same time. When the detection results are opposite, the current respiratory state is determined to be the inhaled gas state. At this time, the dynamic element is instructed to descend, and the inhalation audio is played at the same time.

For the detection of the respiratory state, the respiratory electrodes can be used for being completed, the two respiratory electrodes are arranged for the control glasses disclosed by the application and are fixed on the glasses frame 10 in a mounting mode similar to the probe bearing part 620, and when in use, the respiratory electrodes are stuck on the chest part of a wearer through the part similar to the function of a magic tape by tearing the elastic belt, so that the detection of the current respiratory state can be realized. More abundant information on respiratory conditions can be obtained using respiratory electrodes than using the detection method of the sensor, but both the structure and the control module are more complex. According to the application, as long as the detection and judgment of the respiratory state can be completed, the regulation and control effect on the gamma brain wave can be realized through the following of the respiratory state.

Referring to fig. 5 and 6, a scene module, a breath following module, an audio synchronization module and a 40Hz audio source are disposed in the control unit 40. The 40Hz audio source includes 40Hz out-gassing sound and 40Hz inhalation sound.

The plurality of LED light sources included in the light source dot matrix 30 form a pixel dot matrix on the lens, and various patterns or videos can be formed under the control of the control unit 40, similar to the advertisement large screen using the LED light sources as pixel dots for outdoor advertisement. The scene module in the application is used for constructing a breathing scene by controlling the LED pixel light sources in the light source dot matrix 30, the breathing scene comprises background elements and dynamic elements, the background elements can be small boats floating in rough seas, starry groups in quiet night sky, deserts under the birthdays, spring warmth blooming ducks floating and the like, and the dynamic elements can be any object capable of reflecting the breathing state, and the current breathing state is preferably displayed by adopting the lifting of a breathing ball. When the scene module builds a breathing scene, the luminous frequency of the LED light sources in the light source lattice 30 is 40Hz.

The breath following module is used for determining the current breath state according to the detection data transmitted by the breath state probe 610, so as to judge and instruct the motion state of the dynamic element. Taking the gas temperature data detected by the temperature sensor as an example, when the detected data is close to the gas temperature of normal exhalation of a human body and is higher than the room temperature, the current respiratory state is judged to be the respiratory state, at the moment, the dynamic element, namely the respiratory ball, is instructed to do ascending motion, and meanwhile, the audio playing unit is instructed to play 40Hz of air outlet sound. When the detected data is close to the temperature of the air and lower than the temperature of the exhaled air of a normal human body, the current breathing state is judged to be the inspiration state, at the moment, the dynamic element, namely the breathing ball, is instructed to do descending motion, and meanwhile, the audio playing unit is instructed to play the inspiration sound of 40Hz. The user experience is to hear his breathing sounds while also seeing his breathing depth and frequency. Therefore, the breathing of the patient can be actively regulated, the physical condition is brought to a state favorable for generating healthy brain waves, the 40Hz photoacoustic induction gamma brain waves are brought to spontaneous generation of the gamma brain waves, and the illness is prevented and overcome.

The technical effects are described as follows: after the device is started, a scene composed of background elements and dynamic elements is firstly generated on the lens, meanwhile, the respiration sensing mechanism 60 starts to detect the respiration state of the wearer, and when the current respiration state is detected to be the exhaled air, the dynamic elements start to rise, and meanwhile, 40Hz of the exhaled air sound is played. Whereas the dynamic element starts to drop and at the same time plays the 40Hz inspiration. The wearer can actively adjust the body condition of the wearer to a state favorable for generating gamma brain waves by listening and observing the breathing rhythm and breathing frequency of the wearer, so that the using effect of generating the gamma brain waves through 40Hz acousto-optic induction and autonomy is realized. When the user is in a state of spontaneously generating the gamma brain waves, eyes can be closed, 40Hz audio frequency and 40Hz light waves penetrating through eyelid still play a role in induction, and when the user suddenly goes into a state of being unfavorable for generating the gamma brain waves, for example, when the user thinks of falling into a wrestling in the morning, eyes can be suddenly opened, and scenes on the lenses can assist the user to recover the state favorable for generating the healthy brain waves as soon as possible.

In the prior art, the respiratory state is generally known by clinically observing the fluctuation of the thoracic cavity, but when the respiration is weaker, a method of placing cotton wool or silk threads near the nose wings of a patient is also adopted, and respiratory electrodes are also adopted on an electroencephalograph or an electrocardiograph to monitor the respiratory state. The detection of brain waves is generally performed by a dedicated electroencephalograph, and various brain wave detection electrodes or brain wave detection dedicated modules have been developed by some companies specialized in medical instruments, so that the functions of the probes or modules can be known in the jindong mall or the alembia. Such as TGAM brain wave sensor development suite, the web site links are:https://i-item.jd.com/10050817026106.html. The noninvasive brain electrical sensor can obtain the sensor information through the medical electronic company network of Shenzhen, baidu, city and American company.

Thus, the gamma brain wave central nervous system organic disease prevention and treatment glasses claimed in the present application further include an embodiment integrated with the brain wave sensor. Through integrating brain wave sensor, can draw the oscillogram of gamma brain wave on the lens in real time, remind the user to pay attention to the breathing of adjustment oneself simultaneously, let the healthy brain wave of oneself more outstanding and stable.

To ensure accuracy of the detection of the respiratory state, another principle of respiratory sensing mechanism may be employed. Referring to fig. 7, the respiration sensing mechanism includes an air outlet switch 61, an air inlet switch 62, a swing needle 63, a swing needle rotating shaft 64, a bearing member 65 and a connecting member 66. The bearing member 65 is connected to the connecting member 66, and the air outlet switch 61, the air inlet switch 62, the balance needle 63 and the balance needle rotating shaft 64 are all assembled in the bearing member 65. The air outlet switch 61 and the air inlet switch 62 can be micro contact switches or micro switches. Taking the hollow sphere-shaped bearing member 65 as an example, the needle rotating shaft 64 is assembled on one diameter of the sphere, and the needle 63 is smoothly hinged in the middle of the needle rotating shaft 64. The air outlet switch 61 and the air inlet switch 62 are symmetrically arranged on the ball cavity at positions corresponding to the front contact point and the rear contact point of the swing needle 63. The air outlet switch 61 and the air inlet switch 62 are electrically connected to the control unit. Meanwhile, the air holes are only processed on the upper hemisphere. Thus, when the gas is exhaled against the gas orifice, the balance needle 63 contacts the gas outlet switch 61 to generate a gas outlet signal, and when the gas is inhaled against the gas orifice, the balance needle 63 contacts the gas suction switch 62 to generate a gas suction signal. The control unit can hereby track the current respiration state. To ensure the sensitivity of detection, the balance needle 63 should be as slim as possible and the friction force at the hinge point should be as small as possible, and at the same time, only air holes are provided in the upper hemisphere shown in fig. 7 corresponding to the direction in which the balance needle 63 swings, i.e., the positions pointed by the arrows on both sides, so that the flow of breathing air is more concentrated.

The technical solution and effects of the present application have been described in detail with reference to the drawings and the specific embodiments of the present application, it should be noted that the specific embodiments disclosed in the specification are only preferred embodiments of the present application, and other embodiments may be developed on the basis of the above description by those skilled in the art; any simple modification and equivalent substitutions without departing from the innovative concepts of the present application are intended to be covered by the present application, falling within the protective scope of the patent.

Claims (5)

1. A pair of gamma brain wave glasses for preventing and treating organic diseases of central nervous system is characterized in that:

comprises a spectacle frame (10), a composite lens (20), a light source lattice (30), a control unit (40) and a power supply unit (50); the compound lens (20) comprises a front lens (210) and a rear lens (220), and the front lens (210) and the rear lens (220) are fixedly connected; the light source lattice (30) is arranged between the front lens (210) and the rear lens (220); the control unit (40) and the power supply unit (50) are arranged on the spectacle frame (10); the power supply unit (50) is electrically connected to the control unit (40) and the light source lattice (30); the light source dot matrix (30) is electrically connected with the control unit (40); the light source lattice (30) comprises a plurality of LED light sources, and the light source lattice (30) can emit light waves with the frequency of 40Hz under the regulation and control of the control unit (40);

the gamma brain wave central nervous system organic disease prevention and treatment glasses also comprise a respiration sensing mechanism, wherein the respiration sensing mechanism comprises an air outlet switch (61), an air suction switch (62), a swing needle (63), a swing needle rotating shaft (64), a bearing part (65) and a connecting piece;

the carrier (65) is connected to the connector for connecting the carrier (65) to the frame (10); a cavity structure is arranged in the bearing component (65), and the air outlet switch (61), the air suction switch (62), the balance needle (63) and the balance needle rotating shaft (64) are all assembled in the bearing component (65);

the swing needle rotating shaft (64) is fixed on the bearing component (65), the swing needle (63) is hinged on the swing needle rotating shaft (64), and the air outlet switch (61) and the air suction switch (62) are symmetrically assembled at positions corresponding to two contact points on two sides of the swing needle (63) when the swing needle swings; a needle swing air hole is formed in the bearing part (65) corresponding to the area, above the needle swing rotating shaft (64), of the needle swing (63); the air outlet switch (61) and the air suction switch (62) are electrically connected to the control unit (40);

when the air is exhausted towards the air hole of the swing needle, the air outlet switch (61) can generate an expiration signal under the action of the swing needle (63); when the air is sucked towards the balance needle air hole, the air suction switch (62) can generate an air suction signal under the action of the balance needle (63);

a scene module and a breath following module are arranged in the control unit (40); the scene module is used for constructing a breathing scene by controlling the LED light sources in the light source dot matrix (30), the breathing scene comprises background elements and dynamic elements, and the breathing following module is used for determining the motion state of the dynamic elements according to the breathing state transmitted by the air outlet switch (61) or the air suction switch (62); when the scene module builds a breathing scene, the luminous frequency of the LED light source in the light source lattice (30) is 40Hz;

the breath following module is used for determining the motion state of the dynamic element according to the breath state transmitted by the air outlet switch (61) or the air suction switch (62), and means that: when the breathing state transmitted by the air outlet switch (61) is an expiration state, the motion state of the dynamic element is ascending motion; when the breathing state transmitted by the inspiration switch (62) is the inspiration state, the motion state of the dynamic element is the descending motion.

2. The gamma brain wave central nervous system organic disease prevention and treatment glasses according to claim 1, wherein: the dynamic element is a sphere.

3. The gamma brain wave central nervous system organic disease prevention and treatment glasses according to claim 1, wherein:

the gamma brain wave central nervous system organic disease prevention and treatment glasses further comprise an audio playing unit, an audio synchronization module and a 40Hz audio source are further arranged in the control unit (40), and the audio synchronization module is used for selecting the music types played by the audio playing unit in the 40Hz audio source according to the breathing state transmitted by the air outlet switch (61) or the air suction switch (62).

4. The gamma brain wave central nervous system organic disease preventing and treating glasses according to claim 3, wherein:

the audio synchronization module is used for selecting the music types played by the audio playing unit in the 40Hz audio source according to the breathing state transmitted by the air outlet switch (61) or the air suction switch (62), and the music types are as follows:

when the breathing state transmitted by the air outlet switch (61) is an expiration state, the audio synchronization module matches 40Hz expiration audio for the audio playing unit; when the breathing state transmitted by the air suction switch (62) is an air suction state, the audio synchronization module matches 40Hz air suction audio for the audio playing unit.

5. The gamma brain wave central nervous system organic disease prevention and treatment glasses according to claim 1, wherein: the power supply unit (50) is a lithium ion battery.