CN113693818A

CN113693818A - Bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation

Info

Publication number: CN113693818A
Application number: CN202111213566.9A
Authority: CN
Inventors: 丛繁滋; 丛林
Original assignee: Individual
Current assignee: Hangzhou Huixinming Biomimetic Technology Co ltd
Priority date: 2020-10-19
Filing date: 2021-10-19
Publication date: 2021-11-26

Abstract

The bionic myopia and amblyopia comprehensive therapeutic apparatus with the laser for increasing the stimulation of the peripheral visual field has the first contribution that the breakthrough for treating the myopia is cleared in the peripheral visual field of the eyeground; the second contribution is that through the application of at least one layer of lens which can enable the luminous view point to form a clear and distinguishable secondary substructure, a method that single laser is thinned and dispersed and safely, effectively stimulates or dynamically stimulates the fovea centralis and the peripheral vision of the fundus retina is found, so that the laser treatment is more effective and safer; the third contribution is that eight kinds of bionic visual training are fused with the technology, the eyeball tissue structure is further improved in a three-dimensional manner, seven kinds of forces of a visual system are comprehensively improved, and three necessary conditions for maintaining eyes are recovered; the third contribution is that the ultrasonic technology which can be used independently is combined with the laser technology to improve the self-repairing capacity of eyeball tissues, so that the laser becomes safer and the power of emmetropizing the axis of the eye is formed together; solving the current visual field problem.

Description

Bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation

Technical Field

The present invention relates to: the bionic comprehensive treatment field for increasing peripheral visual field stimulation, such as myopia, hyperopia, astigmatism, strabismus and amblyopia. More specifically, the invention provides a bionic myopia and amblyopia comprehensive therapeutic apparatus with laser, which increases the stimulation of peripheral visual field.

Background

The incidence of myopia in recent years is high, and the fourth national student physique survey in 2000 shows that the myopia rate of students in China is as follows: 20.23% of pupils, 48.18% of junior middle school students, 71.29% of senior high school students and 73.01% of college students. The file of the department of health, office of 2016 (2016)487 shows: according to the results of the national student physical health investigation in 2014, the students in 7-12 years oldSmall Study the design13-15 years oldMiddle schoolRaw and 16-18 years oldHigh SchoolRaw and aged 19-22 years oldCollege studentThe visual defect rates of (a) were 45.71%, 74.36%, 83.28% and 86.36%, respectively. The myopia of teenagers is getting more serious and the situation is very severe, which has become a social and civil problem.

Foreign situations are also not optimistic, for example, the vision defect rate of the students in the third grade of high school in Japan is 57%, the myopia rate of the graduates in high school in Singapore China is 78%, the myopia rate of the general population in the United states is one third, and the myopia rate in European areas is less but a large number of myopia groups still exist. The investigation shows three worried points, namely more and more myopia people, deeper and deeper myopia degrees and younger myopia people, which bring great inconvenience to the study and life of students.

In recent years, a light-feeding instrument composed of a weak laser is favored, and manufacturers call it: outdoor sunshine porter can supply the shortages of outdoor illumination of teenagers and children effectively in a short time, can enable children with hyperopia reserve and overdraft to be not myopic, enables children with pseudomyopia to be far away from myopia, and enables the degree of the myopic children to be effectively controlled. The red light with the wavelength of 650nm of the light instrument is a safe natural light and is close to sunlight (the growth of dopamine can be promoted by solarizing the sun more). The children with hyperopia reserve and overdraft are not near sighted, the children with pseudomyopia are far away from myopia, and the degree of the children with myopia is effectively controlled.

The laser has the advantages that the common light of the laser cannot be replaced objectively, and uncertainty exists after ten years:

the laser has: the frequency, phase, vibration direction and propagation direction are the same. The frequency, the phase, the vibration direction and the propagation direction of the laser are the same, and the laser irradiates the fundus target tissue to form polarized light resonance to form optical resultant force (different from common light in intermittence, independence and randomness, and common light does not form resonance resultant force). Further generating the biological effect such as the thermal effect, the pressure effect, the photochemical effect, the electromagnetic effect, the stimulation effect and the like corresponding to the laser. Accordingly, the device is beneficial to awakening optic nerve cells of visual cells, discharging metabolic waste in cells and blood vessels, improving the blood circulation of the fundus, thickening the atrophied and thinned choroid from new to thicker and increasing the tensile strength of the sclera.

Weiwen bin, myopia of teenagers or its close correlation with light environment [ N ]. beijing japanese newspaper, 2021-05-26(011) said: "in fact, the spectrometer is a semiconductor laser using red light with a longer wavelength, which is one of the components of natural light. The principle of the light supplying instrument is that light rays are irradiated into eyes in a specific mode, and the light irradiation time of the eyes of teenagers is effectively supplemented in a short time. It is considered that after the phototypeseter is used, the retinal blood circulation can be improved, the retinal dopamine secretion is promoted, the choroid is thickened, the elasticity of scleral fibers is enhanced, and the occurrence and the development of myopia are inhibited.

However, parents have to pay attention to the fact that the light-feeding instrument belongs to a new technology which is just introduced, the current research data are very limited, the long-term safety and effectiveness are still uncertain, and a large amount of research and follow-up visits are needed for demonstration in the future. Therefore, parents are advised to wait patiently and choose carefully for such products. (Weiwen bin: Beijing Tongren hospital auxiliary hospital chief and ophthalmology chief and ren)

Experts suggest the reason for "careful selection" we know at a glance the definition of weak laser light. Baidu encyclopedia: the main characteristic of weak laser is that it can directly irradiate biological tissue without irreversible damage, but can produce benign biological stimulation, response reaction and photochemical effect so as to regulate several functions of organism, such as nerve impulse transmission, blood function, enzyme activity, immunity and metabolism, etc. and can attain the goal of curing disease and beautifying face by means of balancing and improving the above-mentioned functions. Wherein,

the reason why the direct irradiation of the biological tissue does not cause irreversible damage is the reason of 'patience waiting and careful selection'. Wherein "no irreversible damage" indicates "damage" (lacrimation), but "reversible". What some ophthalmologists are concerned about is the cumulative decade after such injury? So there is "patience waiting, careful selection".

Some manufacturers seek to solve the above safety problem by continuously reducing the power of the laser led. However, since the dose of light administered is positively correlated with the therapeutic effect, the dose reduction is only for safety (therapeutic effect sacrifice) expediency, and is not a method for solving the fundamental problem. How can the safety of "weak laser" be ensured on the basis of ensuring the curative effect?

Secondly, why the modern ophthalmology uses the 'weak laser', and what is the 'control axis' is not the 'shrinkage axis'? The reason is that the weakest part of the sclera, the peripheral visual field part which contributes most to the elongation of the axis of the eye, is neglected by ophthalmology all over the world.

In the aspect of treating myopia, the ophthalmology around the world concentrates the action points on the fundus posterior pole (the phototypeseter also only acts on the fundus posterior pole), and the peripheral visual field which is the main part of elongation of the true axis of the eye with problems is completely disregarded. Therefore, there is no method for shortening the axis of the eye in the ophthalmic textbook, and it is considered that the axis of the eye cannot be shortened and myopia cannot be treated.

From the bionic perspective:

xuguang, first professor is named in "ophthalmic Qu Zhi optics" page 57: nearly all wild birds and beasts on land are slightly hyperopic or emmetropic (i.e., nearly all birds and beasts on land are not near sighted, highly hyperopic, astigmatic, and amblyopic).

The researchers of the invention use the bionic thinking, and find seven reasons that the human or animal in the nature can not be shortsighted by the method of calming the heart → close nature → inducing nature → road method nature for several years.

Here, only one of the most important reasons is to be mentioned: all animals are afraid of being eaten by other things, the peripheral vision field of the animals is very good, and the peripheral vision field is concerned about, pays attention to and sees by any wind blowing to weed the animals, and is afraid of the appearance of natural enemies. If the peripheral visual field is used well, the blood circulation of the sclera at the corresponding part is good (the visual cell and the sclera at the corresponding part are called as blood supply of a blood vessel), so that the sclera has strong development activity due to good blood circulation (at the young age), and the hypermetropia cannot be obtained if the sclera has strong development activity; ② after the length of the axis of the eye is developed in place, the sclera has strong tensile strength due to good blood circulation. The sclera tensile tension is strong, so the axis of the eye cannot be elongated and the myopia cannot be caused; astigmatism or decentering strabismus (the first focus of astigmatism, decentering strabismus, and abnormal retinal correspondence strabismus, all of which are localized elongations near the fovea of the fundus retina) are also not observed. Different from wild animals, people are not afraid of jumping out of other surrounding animals to eat the animals, so that a series of visual problems of human beings are caused only by paying attention to a target to be seen in front, regardless of whether the peripheral vision field is ignored completely or not, the peripheral vision field cannot be stimulated due to the fact that the peripheral vision field of the eyeground is not concerned, and blood circulation of the peripheral vision field of the eyeground is poor.

From the literature point of view:

firstly, plum is beautiful red and Qianjin Yue; anatomical basis for generation and development of Shaodabao myopia [ J]The journal of Chinese clinical anatomy, 2000, phase 01, pages 59-60, the article states: "Wallman indicates: long-time close reading is itself a particular form deprivation. Because only the center of the retina is in close readingThe fovea receives sufficient visual stimulation, while the other most parts of the retina lack sufficient stimulation and most retinal cells are less active. "use waste and waste" and blood supply and metabolism level are positively correlated, which is the internal rule of human body. It has been found through research that,peripheral retinal manifestations in early fundus changes of myopic eyes Anemia state, yellow-white color, i.e. 'non-oppressive white' phenomenon”。

Just because the blood circulation in the peripheral visual field of the ocular fundus is poor, the sclera of the corresponding portion is in a sub-healthy and weak state with insufficient nutrition supply. This may result in insufficient scleral developmental activity, or insufficient scleral tensile tension. If the development vigor of the sclera is insufficient, hypermetropia can be obtained, and if the tensile tension of the sclera is insufficient, myopia, astigmatism or other side-center staring strabismus and amblyopia caused by myopia, hypermetropia, astigmatism and strabismus can be obtained.

The current study situation of the thickness of the highly myopic sclera is as follows:

second, Dunnengjunjie, He Xixian, xuxu, the current research situation and progress of the thickness of highly myopic sclera [ J]Chinese eyeground disease journal, 2017,33(01):87-89 abstract name: the atrophic thinning of scleral tissue is an important step in the development of high myopia.Is close to The affected eye usually has the thickest posterior pole sclera and the thinnest equatorial sclera; it is believed that the scleral thickness is inversely related to the axial length of the eye”。

(iii) study progress of histological changes of Li Venb, Hu Bo Jie, Li Xiao Rong, high myopia [ J]Tianjin medicine, 2017,45(06): 657-: "the thickness of the sclera at the corneoscleral limbus of the eye with the axis below 26mm is about (0.50 + -0.11) mm, down to the serration limbus (0.43 + -0.14) mm,the equator part is (0.42 +/-0.15) mm, and the middle parts of the equator part and the rear pole part are (0.65 +/-l) 0.15) mm, around the optic nerve (0.86 + -0.21) mm, and finally (0.94 + -0.18) mm in the posterior poleThe thinnest of the optic disc sieve plate is (0.39 +/-0.09) mm.Uneven stretching of the highly myopic posterior sclera, average thickness reduction of the sclera from the equatorial to the posterior polar Is low in”。

Civil aviation flyer examination-the peripheral visual field health status of a person with relatively good eyes is seen:

(xi) investigation and study of retinal peripheral degeneration in civil aviation and aviation missiling [ J ] International journal of ophthalmology 2020,20(09): 1629-: among 2450 examined flying students, 575 students survived in different types of retinal peripheral degenerative changes, with diseased sites mainly concentrated around the equator of the retina with a prevalence of 23.5%.

The first article calls:in early stage of fundus change of myopia, peripheral retina is in 'non-pressed white' anemia state Phenomenon(s)

The second and third article show myopia, particularly high myopia, with the weakest elongated portion of the sclera at the equator of the eyeball, the second elongated weak portion being intermediate the equator and the posterior pole, and the sclera at the posterior pole being the thickest, so-called "with go and go". That is, modern ophthalmology directs all treatments to the posterior pole of the fundus, the most undesirable part. The separating boot is difficult to itch and takes effect.

The fourth article gives that the degenerative appearance of the retina periphery is mainly concentrated around the equator of the retina, as is the case for relatively "healthy people" in the population.

It can be seen that a breakthrough for the prevention of myopia should be in the peripheral field of the fundus (not yet noticed by the ophthalmology community).

The method for treating myopia and amblyopia by only using monochromatic weak laser is not scientific enough:

the method comprises the following steps: color is perceived by both cone and rod cells in the human eye, and there are generally three different cone cells in the human eye: the first is primarily perceived red, with its most sensitive spot around 650 nm; the second main perception of green color is that its most sensitive point is around 535 nm; the third, which primarily perceives blue, has its most sensitive spot at around 445 nm. There is only one rod cell, the most sensitive color wavelength of which is between blue and green.

From the viewpoint of recovering the natural state of human visual cells, the current technology only selects 650nm red laser to treat myopia rather than myopia. Just like people in the year only use red light flicker to treat amblyopia, later along with the improvement of people's cognition, yellow light, green light and even blue light (optical brush) are added on the basis of red light.

In addition, the components of outdoor sunlight include infrared rays, seven colors of visible light. The single 650nm red weak laser cannot completely replace outdoor sunlight to feed light to the eyeground, and multicolor light is needed to feed light to the eyeground.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention provides a bionic myopia and amblyopia comprehensive therapeutic instrument with laser, which increases the stimulation of peripheral visual field; the method comprises the following steps: the system comprises a plurality of visual mark points, a pupil distance adjusting module, a lens and one or more sound-producing elements, wherein the lens can enable a luminous viewpoint to form a clear and distinguishable secondary substructure; wherein: the visible mark points are luminous viewpoints and/or reflective viewpoints and/or refractive viewpoints; the visible light-emitting viewpoint includes: a laser-visible light-emitting viewpoint and a non-laser-visible light-emitting viewpoint; the laser-viewable light-emitting viewpoint includes: the laser comprises a laser light emitting diode, a vertical cavity surface emitting laser based on liquid crystal regulation and control, and a vertical cavity surface emitting laser based on organic light emitting diode regulation and control; the non-laser-viewable light-emitting viewpoints include: at least one of a common light emitting diode, an incandescent lamp, a liquid crystal, or an organic light emitting diode; the one or more sound generating elements on the carrier comprise: an ultrasonic transducer capable of generating ultrasonic waves and a sounding element capable of giving out prompt sounds or induction words; it is characterized in that the preparation method is characterized in that,

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

at least one lens (123-T) for forming a clearly distinguishable secondary substructure for the luminous point of view;

the bionic comprehensive therapeutic apparatus further comprises a luminous viewpoint control unit.

A bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation; the method comprises the following steps: the system comprises a plurality of visual mark points, a pupil distance adjusting module, a lens and one or more sound-producing elements, wherein the lens can enable a luminous viewpoint to form a clear and distinguishable secondary substructure; wherein: the visible mark points are luminous viewpoints and/or reflective viewpoints and/or refractive viewpoints; the visible light-emitting viewpoint includes: a laser-visible light-emitting viewpoint and a non-laser-visible light-emitting viewpoint; the laser-viewable light-emitting viewpoint includes: the laser comprises a laser light emitting diode, a vertical cavity surface emitting laser based on liquid crystal regulation and control, and a vertical cavity surface emitting laser based on organic light emitting diode regulation and control; the non-laser-viewable light-emitting viewpoints include: at least one of a common light emitting diode, an incandescent lamp, a liquid crystal, or an organic light emitting diode; the one or more sound generating elements on the carrier comprise: an ultrasonic transducer capable of generating ultrasonic waves and a sounding element capable of giving out prompt sounds or induction words; it is characterized in that the preparation method is characterized in that,

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

a plurality of visible light-emitting viewpoints (3) located at the periphery of the carrier; and,

at least one lens (123-T) for forming a distinct secondary substructure of the luminous point of view

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

a plurality of double-barrel inner side light emitting diodes (2) which are uniformly distributed from far to near and are positioned on the carrier, and

The three bionic myopia and amblyopia comprehensive therapeutic instruments with the laser for increasing the peripheral visual field stimulation are characterized by further comprising an ultrasonic transducer positioned on the carrier;

the ultrasonic transducer is arranged in a mode comprising: the ultrasonic transducer (5) is arranged at a position close to a peripheral visual field on a (3-D) (3-D') circuit board in front of eyes, the ultrasonic transducer (5) is arranged in a carrier at the near eye side (5-1) and in an eye support and eye orbit periphery, or the ultrasonic transducer (5) is arranged in an eye support at the near eye side and can be accommodated in a (123-T) slightly deformable oval silica gel sac type treatment head in a lens concave surface which can enable a luminous viewpoint to form a clear and distinguishable secondary substructure;

the bionic comprehensive therapeutic apparatus also comprises an ultrasonic control unit.

A bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation; the bionic comprehensive therapeutic apparatus comprises: a carrier;

an ultrasonic transducer located on the carrier; and/or

A laser light emitting diode on the carrier; and/or

A plurality of visible marker points located on the periphery of the carrier; and

at least one layer of lens which can make the luminous viewpoint form a clearly distinguishable secondary substructure;

the ultrasonic transducer is arranged in the near-eye support of the carrier, and the mechanical effect of the ultrasonic wave emitted by the ultrasonic transducer can perform internal massage on eyeball cells and improve the eyeball temperature through the thermal effect to generate a micro-hyperthermia physiotherapy effect;

the light emitted by the laser light emitting diode penetrates through at least one layer of lens which can enable the light emitting viewpoints to form clear and distinguishable secondary substructures, so that laser beams are dispersed into thousands of tiny light emitting viewpoints through multiple diffuse refraction or grating diffraction, meanwhile, the light spot coverage position formed by the tiny light emitting viewpoints of the laser is increased to the near peripheral vision of the eyeground or the whole eyeground peripheral vision is increased to approach, and the peripheral vision is increased to stimulate and improve the blood circulation of the eyeground peripheral vision;

the plurality of visible mark points positioned on the periphery of the carrier are matched with the lens which can enable the luminous viewpoint to form a clear and distinguishable secondary substructure to complete bionic visual training, and the bionic visual training comprises the following steps: at least one of omnibearing eye yoga movement, five-linkage binocular fusion of a vision system, peripheral visual field stimulation training, visual acuity training, super fine eyesight training, training of twinkling of two eyes respectively and training of fusing two eyes;

the bionic comprehensive therapeutic apparatus also comprises an ultrasonic control unit and a luminous control unit.

The wavelength of the light beam selected by the laser light emitting diode is between 440 nanometers and 1300 nanometers;

optionally, the selected light beam wavelength of the laser light emitting diode is between 530 nanometers and 1300 nanometers;

the laser light-emitting diode is composed of at least one of a weak blue light laser light-emitting diode, a green light laser light-emitting diode, a yellow light laser light-emitting diode, a red light laser light-emitting diode and an infrared laser light-emitting diode;

optionally, the laser light emitting diode is composed of a red laser light emitting diode;

optionally, the laser light emitting diode is composed of an infrared laser light emitting diode;

optionally, the laser light emitting diode is composed of a red light laser light emitting diode and an infrared laser light emitting diode;

optionally, the laser light emitting diode is composed of a green laser light emitting diode, a yellow laser light emitting diode, a red laser light emitting diode, and an infrared laser light emitting diode.

When the bionic comprehensive therapeutic apparatus is placed in a space where a person is located and a certain distance is determined between the bionic comprehensive therapeutic apparatus and the eyes of the person, at least part of the visible marking points are located near the limit of the periphery of the visible range of the eyes of the person; or, part of the plurality of visible marking points are positioned near the limit of the periphery of the visible range of human eyes, and part of the plurality of visible marking points are positioned near the center of the visible range of human eyes;

when the carrier of the bionic comprehensive therapeutic apparatus is shaped into a double-window head-wearing type shape, 5-24 luminous viewpoints are arranged on each window of eyes; wherein, 4-16 luminous viewpoints are arranged around the window; or 1-9 luminous viewpoints are arranged at the center of the window;

the carrier of the bionic comprehensive therapeutic apparatus is formed into a double-window middle-long lens cone desktop computer, and 4-16 luminous viewpoints are arranged on the periphery of each window; 1-9 luminous viewpoints are arranged at the center of the window;

optionally, in the double-window medium-length lens barrel desktop, a pupil distance adjusting mechanism is arranged on the carrier, and a rack below the lens barrels is driven to adjust the distance between the two lens barrels through a gear set in transmission connection;

the carrier of the bionic comprehensive therapeutic apparatus is formed into a large desktop, and when two eyes see the same window, 5-160 luminous viewpoints are arranged in the window; wherein, the periphery of the window is provided with 4-80 luminous viewpoints; the center of the window is provided with 1-80 luminous viewpoints.

The lens which can make the luminous viewpoint form a clearly distinguishable secondary substructure realizes the secondary substructure by the following steps: performing matte treatment for generating diffuse refraction on the surface of the lens; or particles generating diffuse refraction are added in the lens during injection molding; or a film formed by a micro prism group generating diffuse refraction is attached to the surface of the lens; or the surface of the lens is pasted with a frosted matte film which generates diffuse refraction; or the surface of the lens is stuck with a particle film which generates diffuse refraction; or the light-emitting viewpoint forms a clear and distinguishable secondary substructure by the matching technology of the patterned lens of the laser pen and the rotating grating;

the lens capable of enabling the luminous view point to form a clearly distinguishable secondary substructure is a lens of the luminous view point or a lens arranged between the luminous view point and human eyes;

the lens of the light-emitting viewpoint itself includes: a common light emitting diode packaging end face, a lens end face except a crystal of a laser diode, and an optical fiber end face;

the optical fiber output end surface is processed to form a clearly distinguishable secondary substructure; the end face of the optical fiber is processed into a plane or a spherical surface, and the plane or the spherical surface is processed into a clearly distinguishable secondary substructure.

The ultrasonic transducer: the ultrasonic frequency is 20 kHz-1000 kHz, and the ultrasonic treatment dosage is 0.1-2.5W/cm²；

Optionally, the ultrasonic frequency is 4 kHz-1000 kHz, and the ultrasonic treatment dosage is 0.1-2.5W/cm²；

Wherein,

the (5) ultrasonic transducer is arranged on a near-peripheral visual field position on a (3-D) (3-D') circuit board in front of eyes, and because the ultrasonic massage is to massage the eyeball through air, the ultrasonic treatment dosage is 1.5-2.5W/cm^2；；

The ultrasonic transducer (5) is arranged in the carrier at the near-eye side (5-1) of the eye support and around the eye socket, and the ultrasonic massage belongs to the massage of the eye socket through the eye support, and the ultrasonic treatment dosage is 0.5-1.5W/cm^2；；

The (5) ultrasonic transducer is arranged in the near-eye side eye support and can be accommodated in (123-T) slightly-deformable elliptical silica gel sac type treatment head which can enable a luminous viewpoint to form a clear and distinguishable secondary substructure and can be slightly deformed, the slightly-deformable elliptical silica gel sac type treatment head is in close contact with the surface skin of an eyeball and the orbit, the problem of power loss of sound energy caused by air refraction is solved, and the ultrasonic treatment dosage is 0.1-0.75W/cm^2；。

When the laser light emitting diode selects more than one laser beam, the light path switching of the laser beams with different wavelengths is completed by matching an Nx 1 optical fiber coupler called an optical fiber flange plate with the on-off switching between the laser beams with different wavelengths or by using a light path switcher.

The bionic comprehensive therapeutic apparatus further comprises an ultrasonic control unit and a luminous control unit: wherein,

the ultrasonic control unit is used for controlling the ultrasonic transducer to switch among a plurality of states such as frequency, duty ratio, pulse repetition period, coding type, treatment time of the left eye and the right eye respectively and the like according to a certain sequence, and the ultrasonic control unit limits the working mode of the ultrasonic transducer by controlling a plurality of parameters, states and sequence of the ultrasonic transducer according to the condition of a user;

the light-emitting control unit is used for controlling the light-emitting viewpoints to switch between a light-emitting state and a non-light-emitting state in a certain sequence;

the laser control unit is used for refining the refinement degree of the substructure and controlling the area of the laser coverage retina through adjusting the distance between more than one lens which can enable the luminous viewpoint to form a clearly distinguishable secondary substructure; the grating close to the eye side or the lens capable of forming the secondary substructure is rotated through a stepping motor to form a tiny laser viewpoint with a dynamically rotated peripheral visual field; or the peripheral visual field tiny laser viewpoints are driven to form a dynamic visual effect through the rotary vibration of a motor with an eccentric device arranged close to the eye side; or the eyeballs are subjected to acoustic dynamic massage through the ultrasound generated by the ultrasonic transducer, and peripheral visual field tiny laser viewpoints are driven to form a dynamic visual effect;

the light-emitting control unit limits the visible running track by controlling the light-emitting sequence of the plurality of light-emitting viewpoints, and completes bionic visual training.

The ultrasonic transducer of the bionic comprehensive therapeutic apparatus is embedded in a groove at the bottom of the eye support which can swing according to the face shape: a soft silica gel ring which can be deformed under pressure and can replace a coupling agent is embedded in a groove on the eye support and the convex edge contacted with the face; the energy of the ultrasonic transducer is directly transmitted to the eyeball through air to directly carry out acoustic power massage on the eyeball, and is transmitted to the eye socket and the eyeball through the eye support and the soft silica gel ring to carry out acoustic power internal massage on the eye socket and the eyeball; meanwhile, the temperature of the inner massage tissue is increased to generate a micro-hyperthermia physiotherapy effect;

optionally, when the distance between the two lens barrels is adjusted, the ultrasonic transducer eye support capable of swinging according to the face shape drives the synchronous adjustment of the distance between the two eye supports through the eye support positioning hole on the lens barrel.

The laser covers the area of the retina and the bionic visual training, the diameter of a channel close to the eye side in a long lens cone in the double-window desktop computer is increased, and a common light-emitting diode is arranged on the inner side of the eye-close end of the lens cone through a flexible circuit board, or the distance between eyes and the eye-close end of the lens cone is reduced; the stimulation of the laser micro-luminous viewpoint and the common light micro-luminous viewpoint to the periphery of the retina and seven bionic visual training are completed.

The laser covers the area of the retina and the bionic visual training, the step design of the size and the diameter of the long and short lens barrels in the double-window desktop computer is adopted, wherein the diameter of the lens barrel close to the eye side is large, and the light-emitting diode is arranged at the large-diameter edge of the circuit board at the eye side of the step or the distance between eyes and the eye end of the lens barrel is reduced; the stimulation of the laser luminous viewpoint and the common luminous viewpoint to the periphery of the retina and seven bionic visual training are completed.

The carrier of the bionic comprehensive therapeutic apparatus is formed into a large desktop, and when two eyes see the same window, an inwards concave spherical liquid crystal screen or an inwards concave spherical organic light-emitting diode screen is arranged in the window; the spherical radii of the concave spherical liquid crystal and the concave spherical organic light emitting diode are equal to the distance from the eyeball position of the trainer to the concave spherical surface, so that the laser emitted by different parts of the concave spherical liquid crystal and the concave spherical organic light emitting diode can be directed to the eyeball.

Advantageous effects

The invention has the beneficial effects that:

the first contribution of the invention is that through at least one layer of lens which can make the luminous viewpoint form a clear distinguishable secondary substructure, the original laser beam is dispersed into thousands of laser beams; the change can not only lead the instrument to improve the capability of activating the optic nerve cells of the optic cells hundreds of times; on the basis of unchanged original light supply dose, the light supply area is increased, light is supplied uniformly, the phenomenon of excessive stimulation of local high-dose light supply is eliminated, and the weak laser light supply instrument is safer than the prior art and is more effective and safer than a low-light supply dose scheme.

A second contribution of the present invention is to fuse the concept of peripheral visual field of interest with weak laser treatment: the eyeground periphery visual field is dynamically stimulated by the laser visual luminous viewpoint of the central visual field while the peripheral visual luminous viewpoint drives the eyeballs to do omnibearing eye yoga movement up and down and left and right. By utilizing the characteristics that the laser frequency, the phase, the vibration direction and the propagation direction are the same, the laser irradiates the fundus target tissue to form polarized light resonance and form light resultant force, thereby being beneficial to awakening visual cells and optic nerve cells and discharging metabolic waste in cells and blood vessels. The blood circulation of the peripheral visual field of the eyeground is better improved, the power for shortening the axis of the eye can be formed for myopia, the power for promoting the growth and development of the axis of the eye can be formed for hyperopia, the power for balancing the peripheral visual field of the eyeground to eliminate astigmatism and the first focus of the oblique visual eyeground can be formed for astigmatism and the lateral central staring oblique vision, and the power for eliminating the cause of the amblyopia can be formed for amblyopia; the visual problem that the human neglects the peripheral vision field and the peripheral vision field can not be stimulated is solved;

the third contribution is that the self-repairing capacity of eyeball tissues is improved by combining the ultrasonic technology and the laser technology which are used independently; in the instrument, the ultrasonic power is added to form in the cell: the massage device comprises the mechanical effect of 'internal massage', the thermal effect of 'internal heat generation' and the physicochemical effect function of 'internal reaction'. The bionic laser is beneficial to quickly discharging metabolic waste in eyeball cells and blood vessels, and is beneficial to quickly activating self-repairing capability of a visual system.

The fourth contribution is that eight kinds of bionic visual training are fused with the technology, so that the eyeball tissue structure is favorably improved, seven kinds of strength of a visual system are improved, and three necessary conditions for maintaining the eyes are comprehensively recovered.

Drawings

FIG. 1: the appearance schematic diagram of the double-window head-wearing bionic comprehensive therapeutic apparatus is shown;

FIG. 2: is a schematic diagram of the functional parts of the double-window head-wearing bionic comprehensive therapeutic apparatus;

FIG. 3: the appearance structure schematic diagram of the double-window middle-long lens cone table type bionic comprehensive therapeutic apparatus is shown;

FIG. 4: the right view schematic diagram of the appearance structure of the double-window middle-long lens cone table type bionic comprehensive therapeutic apparatus is shown;

FIG. 5: the structural schematic diagram of the optical system in the double-window middle-long lens cone desk type bionic comprehensive therapeutic apparatus is shown;

FIG. 6: the partial enlarged schematic diagram of the internal optical system structure of the double-window middle-long lens cone desk type bionic comprehensive therapeutic instrument is shown;

FIG. 7: the structural schematic diagram of the optical system structure and the interpupillary distance adjusting system structure inside the double-window medium-long lens cone desk type bionic comprehensive therapeutic apparatus is shown;

FIG. 8: the optical system structure and the pupil distance adjusting system in the double-window middle-long lens cone desk type bionic comprehensive therapeutic instrument are in different angle structure diagrams;

FIG. 9: the lens can make the luminous viewpoint form a clear and distinguishable secondary substructure and the near-eye side eye support can be embedded in the groove;

FIG. 10: the ultrasonic transducer can be embedded in the eye support groove;

FIG. 11: the ultrasonic transducer split ellipse structure schematic diagram can be embedded in the eye support groove;

FIG. 12: is a schematic diagram of a micro-deformable elliptical elastic ball with an ultrasonic transducer arranged inside.

With reference to FIGS. 1 to 12: the bionic myopia and amblyopia comprehensive therapeutic instrument comprises the following functional parts: a laser light emitting diode (1); a laser light emitting diode circuit board (1-D); a double-lens-barrel inner side light-emitting diode (2); a light emitting diode circuit board (2-D) at the inner side of the double lens barrel; a near eye side peripheral vision field light emitting diode (3); a near eye side peripheral vision light emitting diode circuit board (3-D); the numbers of the peripheral vision field light-emitting diodes are distributed in a clockwise mode from the right upper side (3-1) to (3-8); a lens (1-T) (3-T) (123-T) which can make the luminous viewpoint form a clearly distinguishable secondary substructure; a pupil distance adjusting module (4); a pupil distance adjusting stepping motor and a driving gear (4-1) thereof; a driven gear (4-2) with a positive and negative screw rod on two sides; a front and back inner buckle nut (4-3) which is connected with the lens cones at the two sides and is matched with the front and back buckle screw; an ultrasonic transducer (5); a micro-deformable elliptical silica gel capsule (5-1') capable of accommodating the ultrasonic transducer; an instrument ultrasonic transducer signal output line (5-2); an instrument ultrasonic transducer signal output port (5-3); a mandible support (6).

Detailed Description

The invention aims to solve the three defects of weak laser in the background technology, and provides a bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation to the society: the method comprises the following steps: the system comprises a plurality of visual mark points, a pupil distance adjusting module, a lens and one or more sound-producing elements, wherein the lens can enable a luminous viewpoint to form a clear and distinguishable secondary substructure; wherein: the visible mark points are luminous viewpoints and/or reflective viewpoints and/or refractive viewpoints; the visible light-emitting viewpoint includes: a laser-visible light-emitting viewpoint and a non-laser-visible light-emitting viewpoint; the laser-viewable light-emitting viewpoint includes: the laser comprises a laser light emitting diode, a vertical cavity surface emitting laser based on liquid crystal regulation and control, and a vertical cavity surface emitting laser based on organic light emitting diode regulation and control; the non-laser-viewable light-emitting viewpoints include: at least one of a common light emitting diode, an incandescent lamp, a liquid crystal, or an organic light emitting diode; the one or more sound generating elements on the carrier comprise: an ultrasonic transducer capable of generating ultrasonic waves and a sounding element capable of giving out prompt sounds or induction words; the method is characterized in that:

the first embodiment is as follows:

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

In this embodiment, a light-emitting viewpoint visible by laser is fused with a lens which can make the light-emitting viewpoint form a clearly distinguishable secondary substructure, and an original laser beam is dispersed into thousands of laser beams through at least one layer of lens which can make the light-emitting viewpoint form a clearly distinguishable secondary substructure; the change can not only lead the instrument to improve the capability of activating the optic nerve cells of the optic cells hundreds of times; on the basis of unchanged original light supply dose, the light supply area is increased, light is supplied uniformly, the phenomenon of excessive stimulation of local high-dose light supply is eliminated, and the weak laser light supply instrument is safer than the prior art and is more effective and safer than a low-light supply dose scheme.

Wherein:

the laser-viewable light-emitting viewpoint includes: the laser comprises a laser light emitting diode, a vertical cavity surface emitting laser based on liquid crystal regulation and control, and a vertical cavity surface emitting laser based on organic light emitting diode regulation and control;

when the laser light emitting diode selects more than one laser light emitting diode, the light path switching of the laser beams with different wavelengths is completed by matching the Nx 1 optical fiber coupler called an optical fiber flange plate with the on-off switching between the laser beams with different wavelengths or by using an optical path switcher.

The lens which can make the luminous viewpoint form a clear distinguishable secondary substructure is the lens of the luminous viewpoint or the lens arranged between the luminous viewpoint and human eyes;

the optical fiber output end surface is processed to form a clearly distinguishable secondary substructure; carrying out plane or spherical surface treatment on the end face of the optical fiber, and carrying out treatment on the plane or the spherical surface to form a clearly identifiable secondary substructure;

the processing of forming clearly distinguishable secondary substructures can be carried out on the lens outside the crystal of the laser diode, the end face of the optical fiber and the lens arranged in the heating device outside the laser diode: the secondary substructure is realized by: performing matte treatment for generating diffuse refraction on the surface of the lens; or particles generating diffuse refraction are added in the lens during injection molding; or a matte film generating diffuse refraction is attached to the surface of the lens; or the surface of the lens is stuck with a particle film which generates diffuse refraction.

The second embodiment is as follows:

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

This embodiment combines the concept of peripheral vision with the technique of the first embodiment: the eyeground periphery visual field is dynamically stimulated by the laser visual luminous viewpoint of the central visual field while the peripheral visual luminous viewpoint drives the eyeballs to do omnibearing eye yoga movement up and down and left and right. By utilizing the characteristics that the laser frequency, the phase, the vibration direction and the propagation direction are the same, the laser irradiates the fundus target tissue to form polarized light resonance and form light resultant force, thereby being beneficial to awakening visual cells and optic nerve cells and discharging metabolic waste in cells and blood vessels. The blood circulation of the peripheral visual field of the eyeground is better improved, the power for shortening the axis of the eye can be formed for myopia, the power for promoting the growth and development of the axis of the eye can be formed for hyperopia, the power for balancing the peripheral visual field of the eyeground to eliminate astigmatism and the first focus of the oblique visual eyeground can be formed for astigmatism and the lateral central staring oblique vision, and the power for eliminating the cause of the amblyopia can be formed for amblyopia; the visual problem that the human neglects the peripheral vision field and the peripheral vision field can not be stimulated is solved;

wherein:

a plurality of visible light-emitting viewpoints around the carrier;

when the bionic comprehensive therapeutic apparatus is placed in a space where a person is located and a certain distance is determined between the bionic comprehensive therapeutic apparatus and the human eyes, at least part of the plurality of visible mark points are positioned near the limit of the periphery of the visible range of the human eyes; or, part of the plurality of visible marking points are positioned near the limit of the periphery of the visible range of human eyes, and part of the plurality of visible marking points are positioned near the center of the visible range of human eyes;

the plurality of visible mark points and the laser visible light-emitting viewpoint which are positioned on the periphery of the carrier are matched with the lens which can enable the light-emitting viewpoint to form a clear and distinguishable secondary substructure to complete the bionic visual training through the light-emitting viewpoint control unit, and the bionic visual training comprises the following steps: at least one of omnibearing eye yoga movement, five-linkage binocular fusion of a vision system, peripheral visual field stimulation training, visual acuity training, super fine eyesight training, training of twinkling of two eyes respectively and training of fusing two eyes;

the laser visible light-emitting viewpoint comprises:

the laser comprises a laser light emitting diode, a vertical cavity surface emitting laser based on liquid crystal regulation and control, and a vertical cavity surface emitting laser based on organic light emitting diode regulation and control;

wherein,

when the laser stays on the surface of the vertical cavity surface emitting laser regulated and controlled based on the liquid crystal and the vertical cavity surface emitting laser regulated and controlled based on the organic light emitting diode;

the end face of the vertical cavity surface emitting laser at the peripheral vision field needs special treatment, and the perpendicular line of the end face should point to the eyeball.

When the vertical cavity surface emitting laser based on liquid crystal regulation and the vertical cavity surface emitting laser based on organic light emitting diode regulation are selected, the following steps can be selected: an inner concave spherical surface liquid crystal display module or an inner concave spherical surface organic light emitting diode display module;

the spherical radii of the concave spherical liquid crystal and the concave spherical organic light emitting diode are equal to the distance from the eyeball position of the trainer to the concave spherical surface, so that the laser emitted by different parts of the concave spherical liquid crystal and the concave spherical organic light emitting diode can be directed to the eyeball.

Lens of third-level substructure

The same as the first embodiment will not be described again.

The third concrete implementation mode:

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

In this embodiment, a cyclic process of turning on the light emitting diodes (3 to 4) (3-6") and turning on → on the laser light emitting diodes (1) (1") and turning on → on the light emitting diodes (2) (2") gradually from far to near → turning on the light emitting diodes (3 to 8) (3-2") is defined by a chip program in addition to the second embodiment, as shown in fig. 7. The process of driving the adjustment change and the pupil size change through the collection, the dispersion and the distance pulling is completed.

The fourth concrete implementation mode:

the bionic comprehensive therapeutic apparatus also comprises an ultrasonic transducer positioned on the carrier;

the ultrasonic transducer is arranged in a mode comprising:

the (5) ultrasonic transducer is arranged near the peripheral visual field on the circuit board shown in figure 2(3-D) and figure 8(3-D') in front of the eye,

The (5) ultrasonic transducer is arranged in the near-eye side (5-1) eye supporting periorbital carrier shown in fig. 9 as shown in fig. 10 and 11, or

The ultrasonic transducer (5) is arranged in the near-eye side eye support as shown in fig. 12 and can be accommodated in the (123-T) slightly deformable elliptical silica gel capsule type treatment head (5-1') in the lens concave surface which can enable the luminous viewpoint to form a clear and distinguishable secondary substructure;

In the embodiment, the ultrasonic technology is combined with the first, second and third specific embodiments, so that the self-repairing capacity of eyeball tissues is improved;

the mechanical effect and the mechanical vibration effect of the 'internal massage' are the basic effects of the ultrasound on the human body. Ultrasound propagates straight in tissue and without reflection is called traveling waves, which cause particles in the medium to compress and expand alternately, producing large accelerations or decelerations. When the distance between the ultrasonic generator chip and the reflection interface is multiple of 1/2 wave length, the direct wave and the reflected wave meet to form standing wave, the maximum amplitude is the sum of two wave amplitudes, and the minimum amplitude is the difference of two wave amplitudes. It makes different mass points in the medium receive different pressures and tensions, so that the stressed mass points move at different speeds, and friction force is generated among the mass points with different speeds. The two mechanical actions generate fine massage to cells, enhance the permeability of cell membranes, promote the flow of cytoplasm in the cells, improve the metabolic function of tissues and are beneficial to the recovery of pathological changes.

The 'internal heat' warming effect is generated by the cell friction caused by the vibration of ultrasonic waves in the body, the 'internal heat' effect accelerates the local blood circulation, improves the accumulation phenomenon of local ischemia and carbonaceous metabolites, attracts white blood cells to actively move to the center of an inflammation area, enhances the anti-injury reaction of an organism, simultaneously adjusts a biological electric field of the human body to improve the pathological change condition, eliminates the microcirculation disturbance, adjusts and balances the vegetative nervous system, promotes metabolism, enhances the repair and regeneration functions of tissues, and plays roles in diminishing inflammation, relieving pain, diminishing swelling and promoting healing.

The physical and chemical effects of the internal reaction, the mechanical effect of the ultrasonic wave and the thermal effect can promote a plurality of physical and chemical changes, and the physical and chemical effects are proved by practice to be secondary effects of the effects. The ultrasound has a dispersion effect, and can change the permeability of the membrane system, so that the composition ratio of substances in local tissues is changed, and the ion concentration and the potentials inside and outside the cell membrane are changed. The ultrasound has the decomposition and polymerization effects on the high molecular compound, so that larger molecules are decomposed into smaller molecules, the effect of the molecules is changed, and the physical and chemical processes are influenced. Ultrasound can also break chemical bonds of some substances to form more reactive free radicals, which cause polymerization. The ultrasound can convert the gel in vivo into sol state, so it can be used for treating degenerative change of muscle, tendon and ligament, improving dehydration state, and enhancing elasticity. The pH value of the general tissue fluid is increased under the action of ultrasound and is alkaline, so that the local acidosis reaction caused by inflammation can be relieved.

The ultrasonic technology is integrated with the first and second specific embodiments. The bionic visual training device is beneficial to the advantage complementation with the bionic visual training participated by laser, is beneficial to quickly discharging the metabolic waste in eyeball cells and blood vessels, and is beneficial to quickly activating the self-repairing capability of a visual system.

Wherein,

the close contact between the slightly deformable elliptical silica gel capsule type treatment head shown in fig. 12 and the surface skin of the eyeball and the orbit solves the problem of power loss caused by air refraction of sound energy, and can obviously improve the curative effect.

The fifth concrete implementation mode:

in order to solve the three defects of weak laser in the background technology, the invention provides a bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation to the society on the basis of 031287964, 2005800246320 and 2009801078354 prior art;

the bionic comprehensive therapeutic apparatus comprises: a carrier;

on the carrier; and/or

A laser-viewable marking point located on the carrier; and/or

A plurality of visible marker points located on the periphery of the carrier; or/and

the ultrasonic transducer is arranged in the near-eye support of the carrier, and when the visual training is carried out, the mechanical effect of the ultrasonic wave emitted by the ultrasonic transducer can carry out internal massage on the eyeball cells and the heat effect can improve the eyeball temperature to generate the micro-hyperthermia physiotherapy effect;

the light emitted by the laser diode penetrates through at least one layer of lens which can enable the luminous viewpoints to form clear and distinguishable secondary substructures, so that laser beams are dispersed into thousands of tiny luminous viewpoints through multiple diffuse refraction or grating diffraction, meanwhile, the light spot coverage part formed by the tiny luminous viewpoints of the laser is increased to be close to the peripheral vision of the eyeground or to be close to the peripheral vision of the whole eyeground, and the peripheral vision is increased to stimulate to improve the blood circulation of the peripheral vision of the eyeground; the covering part is added to the near peripheral vision of the eyeground, so that the near eyeground imaging quality is improved, the near eyeground can be balanced, and the first focus of astigmatic and strabismus eyeground is eliminated; secondly, the covering part is increased to approach the whole peripheral vision of the eyeground, and the power of the emmetropization is formed for the axes of the eyes of both myopia and hyperopia.

The ultrasonic transducer: the ultrasonic frequency is 500 kHz-1000 kHz, and the ultrasonic treatment dosage is 0.1-2-2.5W/cm²(ii) a Optionally, the ultrasound transducer: the ultrasonic frequency is 800 kHz-1000 kHz, and the ultrasonic treatment dosage is 0.5-0.75W/cm²；

The shape of the ultrasonic transducer is designed to be a large-diameter hollow circle of 40-55 mm;

optionally, the ultrasonic transducer is shaped as a large-diameter hollow oval 40-55mm in the transverse direction and 30-45mm in the longitudinal direction;

optionally, the ultrasonic transducer is in a shape of a large-diameter hollow oval which is formed by four arc-shaped ultrasonic transducers and has the transverse length of 40-55mm and the longitudinal length of 30-45 mm.

The visual mark points are luminous viewpoints and/or reflective viewpoints and/or refractive viewpoints;

the light-emitting viewpoint is composed of at least one of a laser diode, a light-emitting diode, an incandescent lamp or a liquid crystal; on the premise of not excluding the light-emitting diode, the light-emitting diode containing deep-level heavy metal or an organic light-emitting diode can be selected.

The light-emitting viewpoint is composed of at least one of a laser diode, a light-emitting diode, an incandescent lamp, a liquid crystal, an internally concave spherical liquid crystal or an organic light-emitting diode and an internally concave spherical organic light-emitting diode.

The laser diode selects the light beam wavelength between 440 nanometers and 1300 nanometers;

optionally, the laser diode has a selected beam wavelength between 530 nm and 1300 nm;

the laser diode is composed of at least one of a weak blue laser diode, a green laser diode, a yellow laser diode, a red laser diode and an infrared laser diode;

optionally, the laser diode is constituted by a red laser diode;

optionally, the laser diode is constituted by an infrared laser diode;

optionally, the laser diode is composed of a red laser diode and an infrared laser diode;

optionally, the laser diode is composed of a green laser diode, a yellow laser diode, a red laser diode, and an infrared laser diode;

optionally, the wavelength of the laser beam selected by the concave spherical liquid crystal and concave spherical organic light emitting diode capable of emitting laser is between 440 nanometers and 1300 nanometers.

When the laser diode selects more than one laser beam, the light path switching of the laser beams with different wavelengths is completed by matching an Nx1 optical fiber coupler called an optical fiber flange plate with the on-off switching between the laser beams with different wavelengths or by a light path switcher.

when the carrier of the bionic comprehensive therapeutic apparatus is shaped into a double-window head-wearing type shape, 1-24 luminous viewpoints are arranged on each window of eyes; wherein, the periphery of the window is provided with 1-16 luminous viewpoints; or 0-9 luminous viewpoints are arranged at the center of the window;

optionally, the double-window head-wearing bionic comprehensive therapeutic apparatus is characterized in that a pupil distance adjusting mechanism is arranged on the carrier, and a rack below the lens cones is driven to adjust the distance between the two lens cones through a gear set in transmission connection; or the gear group connected by transmission drives the gears with the positive and negative screw rods on both sides, and drives the nuts under the lens cones matched with the positive and negative screw rods to adjust the distance between the two lens cones;

the carrier of the bionic comprehensive therapeutic apparatus is formed into a double-window middle-long lens cone desktop computer, and 1-16 luminous viewpoints are arranged on the periphery of each window; 0-9 luminous viewpoints are arranged at the center of the window;

optionally, in the double-window medium-length lens barrel desktop, a pupil distance adjusting mechanism is arranged on the carrier, and a rack below the lens barrels is driven to adjust the distance between the two lens barrels through a gear set in transmission connection; or the gear group connected by transmission drives the gears with the positive and negative screw rods on both sides, and drives the nuts under the lens cones matched with the positive and negative screw rods to adjust the distance between the two lens cones;

The carrier of the bionic comprehensive therapeutic apparatus is formed into a large-scale desktop, and when two eyes see the same window, an inwards concave spherical liquid crystal screen or an inwards concave spherical organic light-emitting diode screen is arranged in the window.

The lens which can make the luminous viewpoint form a clearly distinguishable secondary substructure realizes the secondary substructure by the following steps: performing matte treatment for generating diffuse refraction on the surface of the lens; or particles generating diffuse refraction are added in the lens during injection molding; or a film formed by a micro prism group generating diffuse refraction is attached to the surface of the lens; or the surface of the lens is pasted with a frosted matte film which generates diffuse refraction; or the surface of the lens is stuck with a particle film which generates diffuse refraction; or the light-emitting viewpoint forms a clear and distinguishable secondary substructure by the matching technology of the patterned lens and the rotating grating of the laser pen.

optionally, the lighting control unit is configured to control the lighting viewpoints to switch between a lighting state and a non-lighting state in a certain order; wherein the partial period, each time the lighting period is 1/20 seconds to 1/10000 seconds by moving the blinking light-emitting viewpoint in a certain order; so as to activate the rapid accommodation capacity of the visual system and to enhance the stimulatory capacity of the peripheral visual field;

the mobile flicker lighting viewpoint lights for 1/25-1/1000 seconds;

the mobile flicker lighting viewpoint lights for 1/30-1/100 seconds;

The laser covers the area of the retina and the bionic visual training, the diameter of a channel close to the eye side in a long lens cone in the double-window desktop computer is increased, and a light emitting diode is arranged on the inner side of the eye-close end of the lens cone through a flexible circuit board, or the distance between eyes and the eye-close end of the lens cone is reduced; the stimulation of the laser micro-luminous viewpoint and the common light micro-luminous viewpoint to the periphery of the retina and seven bionic visual training are completed;

optionally, the laser covers the area of the retina and the bionic visual training, the step design of the size diameter of the long lens barrel in the dual-window desktop is adopted, wherein the diameter of the lens barrel close to the eye side is large, and the light emitting diode is arranged at the large-diameter edge of the step eye-side circuit board switched by the size diameter of the lens barrel, or the distance between eyes and the eye-side end of the lens barrel is reduced; the stimulation of the laser micro-luminous viewpoint and the common light micro-luminous viewpoint to the periphery of the retina and seven bionic visual training are completed.

The sixth specific implementation mode:

as shown in fig. 1 and 2, on the basis of 2005800246320 and 2009801078354, the common luminous viewpoint at the visual center position is converted into a laser diode to form the double-window head-wearing laser bionic therapeutic apparatus. Wherein: by setting in fig. 1: a manual rotating wheel on the pupil distance adjusting module (4) adjusts the distance between the lamps in the two windows; in fig. 2, the following settings are set: a laser diode (1) and a strip-shaped window (1-T) which is used for adjusting the interpupillary distance and can form a secondary substructure are arranged in the middle of the window; eight light-emitting diodes (3) are arranged at the periphery of the window, and eight strip-shaped windows (3-T) which are used for adjusting the interpupillary distance and can form a secondary substructure are arranged; the center of the circuit board window is provided with an ultrasonic transducer (5).

The technical effects of the embodiment are as follows: the laser (1) is introduced into eight kinds of bionic visual training led by eight light-emitting diodes (3) arranged at the periphery of a window, the illumination brightness of the laser can be utilized, the directivity is strong, the coherence is good, the monochromaticity can be pure, the macular region of the retina can be effectively stimulated, the blood cells in the retinal blood vessel can be increased in energy and oxygen carrying activity, the passive oxygen supply and oxygen and nutrient substance receiving capacity of retinal neurons are enhanced, the micro-warming physiotherapy effect is generated on the retina, the curative effects of the eight kinds of bionic visual training can be further improved, and the emmetropization process of eyeballs can be accelerated while the imaging quality of the eyeground is improved. And through the mechanical effect of the ultrasonic waves and the thermal effect of the ultrasonic waves emitted by the ultrasonic transducer (5), the micro-thermal physiotherapy effect is generated on the eyeballs while the inner massage is carried out on the eyeballs, so that the blood circulation of the whole eyeballs is improved.

The seventh embodiment:

the present embodiment will be described with reference to fig. 3 to 12.

The present embodiment: to further explain the embodiments one, two, three, four and five:

when the pupil distance adjusting device is used, firstly, as shown in figures 7 and 8, a pupil distance adjusting program received by the pupil distance adjusting module (4) limits a pupil distance adjusting stepping motor and a driving gear (4-1) thereof, drives a driven gear (4-2) with positive and negative screw rods on two sides to rotate, drives a nut (4-3) which is connected with lens cones on two sides and matched with the positive and negative screw rods to adjust the distance between the lens cones on two sides, and finishes pupil distance adjustment to enable the pupil distance adjusting stepping motor to be suitable for a user. As shown in fig. 7, the center of the visual field is a laser light-emitting diode (1) arranged on a laser light-emitting diode circuit board (1-D); and a plurality of double-lens-barrel inner-side light-emitting diodes (2) which are uniformly distributed from far to near and are arranged on a double-lens-barrel inner-side light-emitting diode circuit board (2-D); the peripheral vision area is arranged on near-eye side peripheral vision light emitting diodes (3) on a near-eye side peripheral vision light emitting diode circuit board (3-D), wherein the numbers of the peripheral vision light emitting diodes at different positions are distributed in a clockwise mode from the right upper side (3-1) - (3-8).

During visual training:

firstly, when only two functions of a laser light-emitting diode (1) at the center of a visual field and a lens (123-T) capable of forming a clear and distinguishable secondary substructure from a luminous viewpoint are selected, the method belongs to a specific implementation mode. The embodiment can ensure that the weak laser emitted by the laser light emitting diode (1) is distributed more uniformly, more effectively and more safely.

And secondly, when three functions of a laser light-emitting diode (1) at the center of the visual field, a near-eye side peripheral visual field light-emitting diode (3) and a lens (123-T) capable of enabling a luminous viewpoint to form a clearly distinguishable secondary substructure are selected, the method belongs to the second specific implementation mode. According to the embodiment, the on-off of the light emitting diodes (3) at different parts of the peripheral visual field can be limited through a chip program, the laser light emitting diodes (1) are long and bright while seven bionic training modes are formed, weak laser emitted by the laser light emitting diodes (1) which are more uniform, more effective and safer can stimulate the peripheral visual field of the eyeground, the blood circulation of the peripheral visual field of the eyeground is improved, and the power of orthogonalizing the length of the eye axis is formed.

And when four functions of a laser light-emitting diode (1) at the center of the visual field, a plurality of double-lens-barrel inner side light-emitting diodes (2) which are uniformly distributed from far to near, a near-eye side peripheral visual field light-emitting diode (3) and a lens (123-T) which can enable a luminous viewpoint to form a clear and distinguishable secondary substructure are selected, the three specific implementations belong to the three specific implementations.

In this embodiment, a cyclic process of turning on the light emitting diodes (3 to 4) (3-6") and turning on → on the laser light emitting diodes (1) (1") and turning on → on the light emitting diodes (2) (2") gradually from far to near → turning on the light emitting diodes (3 to 8) (3-2") is defined by a chip program based on the embodiment shown in fig. 7. The process of adjusting change and pupil size change is driven by gathering, scattering and far-near pulling, and the previous adjusting capacity, elasticity and size change functions of ciliary muscles, crystalline lenses and irises are recovered.

And fourthly, when five functions of the laser light-emitting diode (1) at the center of the visual field, a plurality of double-lens-barrel inner side light-emitting diodes (2) which are uniformly distributed from far to near, a near-eye side peripheral visual field light-emitting diode (3), a lens (123-T) which can enable the luminous viewpoint to form a clear and distinguishable secondary substructure and an ultrasonic transducer (5) are selected, the method belongs to the specific implementation of the fourth specific implementation mode.

Wherein,

the close contact between the slightly deformable elliptical silica gel capsule type treatment head and the surface skin of the eyeball and the orbit as shown in fig. 12 solves the problem of power loss caused by air refraction of sound energy, and can remarkably improve the curative effect.

When the instrument visual training is just finished, the instrument waits for half a minute, and waits for a user to insert the signal output line (5-2) of the ultrasonic transducer of the instrument in fig. 12 into the signal output port (5-3) of the ultrasonic transducer of the instrument in fig. 3, and place the micro-deformable elliptical silica gel capsule (5-1') containing the ultrasonic transducer into the concave surface of the lens (123-T) which can enable a light-emitting viewpoint to form a clear and distinguishable secondary substructure. After hearing the prompt sound, the lower jaw is placed on a lower jaw support (6) as shown in figure 4, the eyeball and the orbit are propped against a micro-deformable oval silica gel capsule (5-1') which is placed in the concave surface of a lens (123-T) which can enable the luminous viewpoint to form a clear and distinguishable secondary substructure and is used for accommodating an ultrasonic transducer, and ultrasonic massage is carried out.

Therefore, the bionic myopia and amblyopia comprehensive therapeutic apparatus with the laser is formed by the double-window middle and long lens cone, which increases peripheral visual field stimulation, and the other components and the connection relation and the specific implementation mode are as follows: the composition is increased: the instrument generates dynamic visual effects: a, selecting a laser pen technology, mounting a micro motor on a lens barrel beside a near-eye side end face mirror, and driving the lens barrel to rotate through a gear to form a light-emitting viewpoint substructure end face mirror so as to form a dynamic visual effect of a peripheral visual field; b, a vibration massage technology is selected, a micro motor with an eccentric wheel is arranged on the eye support, and a dynamic visual effect of the peripheral visual field is formed by the vibration of the micro motor on the eye socket. Forming eight kinds of bionic visual training, arranging the light emitting diode at the inner side of the near eye end of the lens cone through the flexible circuit board, and driving the eyeball to move. The stimulation of the laser micro-luminous viewpoint and the common micro-luminous viewpoint to the periphery of the retina is completed, and simultaneously eight kinds of bionic visual training are completed. The structure is deformed, as shown in fig. 5 and 6, the diameter of a channel close to the eye side of the long lens barrel in the double-window desktop is increased (to 45-50mm), or the distance between the eyeball and the lens close to the eye side is reduced, so that the light emitting diode on the flexible circuit board is helped to complete the all-directional eye yoga movement for guiding the eyeball to move to the limit position in each direction, and the laser irradiated from the front can be irradiated to the equator position of the eyeball.

The invention relates to the following: 2005800246320, 2009801078354 double-window head-wearing therapeutic apparatus, 031287964 double-window middle-long lens cone table type therapeutic apparatus; safety, effectiveness of ultrasound, weak laser in ophthalmic applications, and control thereof by its control unit; the optical path switching of the laser with different wavelengths, the dynamic effect of the peripheral visual field formed by the laser pen and the like are all the existing mature technologies, and the technical personnel of the middle and above can realize the optical path switching without additional creation. The present application is therefore not described in these areas, but only in terms of innovations.

Note that:

(1) associated with seven kinds of bionic visual training: bionic origin, instrument structural features and unique main functions thereof:

1. all-round eye yoga motion:

the method is natural: all animals are afraid of being eaten by other animals, namely the eyeball can stretch everywhere ceaselessly → through movement → promoting blood circulation to remove blood stasis → good blood circulation → no visual fatigue → no pseudomyopia → no more true myopia and the like. It can be used for improving eyesight by reversing the above steps.

The instrument is characterized in that: the visual mark points are located near the limit of the visual range of human eyes, and the visual mark points are completed by the luminous viewpoint control unit.

The method has the unique functions that: the omnibearing eye yoga movement utilizes the characteristic that human eyes tend to be bright to drive eyeballs to do omnibearing eyeball yoga movement close to the movement limit. The eyeground peripheral visual field is stimulated while the extraocular muscles are fully exercised, the eyeball blood circulation can be fundamentally improved, and the physiological function of rapidly repairing the sick eyeball is enhanced.

Metabolic waste discharged by the eyeballs every day is larger than that generated by the eyeballs every day, so that refraction interstitial substances are transparent, and asthenopia caused by insufficient circulation power is improved;

improving the function of extraocular muscles and improving the searching capability, the gathering capability and the positioning capability of eyeballs; balancing extraocular muscles, improving external causes of strabismus and astigmatism, and improving extraocular muscle asthenopia.

And thirdly, when peripheral light spots are found, the diameter of the equator is enlarged and the length of the eye axis is shortened. When the eye is going to the light spot, the blood circulation of the far and near peripheral vision of the scratched part is improved, and the power that the myopia, hyperopia, astigmatism fundus tends to emmetropia is formed.

2. Visual system five-linkage binocular imaging:

the method is natural: all animals were eyes-on-the-fly and eyes-on-the-fly, especially the best-sighted birds (human experts require static eyes: no ability to walk to read books, no ability to sit in a car to read books): dynamic eyes → fast moving far and near → fast changing visual angle → strong adjusting ability of visual system → the object image can always fall on the retina.

The instrument is characterized in that: the luminous viewpoints observed by the two eyes with parallel visual axes are all small-view luminous viewpoints consisting of hundreds of thousands of tiny luminous viewpoints, and the luminous viewpoints observed by the two eyes with a set consists of large-view luminous viewpoints.

The method has the unique functions that: compared with the traditional three-linkage binocular imaging, the visual five-linkage binocular imaging has the advantages that visual angle change is increased, and two links of comparison and judgment of the brain and experience data are increased. Therefore, the adjustment of ciliary muscle and the size change of pupil can be effectively driven (the traditional triple action has no visual angle change, and the brain has proper feeling and does not adjust when performing comparison judgment).

Firstly, the former elasticity and regulation function of ciliary muscle, crystalline lens and iris are improved by the change of distance and visual angle and the judgment of brain comparison

Secondly, improve the visual fatigue caused by the intraocular muscles, relieve the pressure of the elongated sclera, eliminate the distending pain caused by the elongated sclera which is not adjusted

3. Peripheral visual field stimulation training:

the method is natural: wild animals are afraid of being eaten by other animals → peripheral vision is very well used → peripheral vision blood circulation is good → scleral tensile tension is strong (or scleral developmental activity is strong) → promotion of emmetropia → maintenance of good eye condition.

The instrument is characterized in that: the luminous viewpoints of the peripheral vision field are arranged at the edge of the movement limit of the eyeball, if the eyeball always looks at the dead front and feels with the residual light, the peripheral luminous viewpoints twinkle and rotate, at the moment, the object image of the peripheral vision field just falls on the outer side of the equator of the eyeball,

here, it is just the weakest part of the sclera in the literature.

The method has the unique functions that: peripheral visual field stimulation training for stimulating the weakest part of the blood circulation in the peripheral visual field of the eyeground

In the case of myopia, a first layer of myopia,

firstly, from the optical angle, the diameter of the equator is enlarged, the length of the ocular axis is shortened, and the problem that the length of the ocular axis in the modern medicine cannot be shortened is solved;

secondly, the peripheral visual field of the eyeground is stimulated, peripheral visual cells participate in the work, the blood circulation angle of sclera of the eyeground peripheral visual field can be improved, the tensile tension of the sclera is enhanced, and the length of the axis of the eye is shortened step by step;

for hyperopia, the eyeground peripheral vision can be stimulated, the peripheral vision blood circulation angle can be improved, the sclera development vigor can be enhanced, and the axial emmetropia direction of eyes can be promoted to develop;

thirdly, for astigmatism and strabismus, the part of the fundus part which is locally elongated can be gradually normal. The local causes of the fundus oculi of astigmatism and strabismus are eliminated.

4. Visual acuity training:

the method is natural: the visual acuity of the eagle was best in all animals-the eagle could be seen from three kilometers of high above air → exactly what chicks pecked on the ground, running rats and hares.

The instrument is characterized in that: light-transmitting cover capable of forming clear and distinguishable secondary substructure on luminous viewpoint

The method has the unique functions that: the unique visual acuity training is beneficial to the improvement of the resolving power of a user for watching the visual target with a small visual angle. Meanwhile, according to the lens imaging principle, an object image after refraction of numerous tiny viewpoints in the light-emitting viewpoints of the eye yoga vision enhancer also falls behind the retina, but the focal depth is super-prolonged according to the focal depth principle because the viewpoints are small, the incident angle is tiny, and the light cone is fine, so that the image imaged behind the retina can be clearly seen on the retina without lengthening the eye axis. Therefore, the phenomenon that the eye axis is stretched backwards by the luminous viewpoint with large visual angle of the traditional therapeutic apparatus, which is worried by the qualified ophthalmologist, can not be generated.

5. Super fine eyesight training:

the method is natural: before the birds land, the birds inspect a plurality of targets and simultaneously observe whether the plurality of targets on the ground are abnormal → force a plurality of fine visual cells on the eyeground to participate in the work.

The method has the unique functions that: in the ultra-fine eyesight training, each luminous viewpoint in the eye yoga eyesight improving instrument consists of hundreds of thousands of tiny luminous viewpoints. Therefore, the luminous viewpoint in the instrument can simultaneously activate hundreds of optic cells and optic nerve cells every time the luminous viewpoint flickers.

For amblyopia patients, the training (each lamp is composed of hundreds of thousands of tiny luminous viewpoints) can efficiently activate visual cells and optic nerve cells, and can avoid complex training such as grating, optical brushing, back image and family fine eyesight training. Simultaneously, super meticulous training still can assist other training raising the efficiency:

for example: the visual field stimulation training is assisted, the strength of shortening the axis of the eyes is increased by hundreds times, and the respective flicker training of the two eyes is assisted, so that the eye-brain communication capacity is enhanced by hundreds times.

6. And (3) carrying out flicker training on two eyes respectively:

the method is natural: the two eyes of the animals are respectively used: to protect natural enemies → animals develop a habit of using two eyes separately → this habit is favorable for the fusion of left and right brains → fusion of both eyes → better stereoscopic vision.

The instrument is characterized in that: the device is completed by the instrument double-window luminous viewpoint setting and luminous viewpoint control unit.

The method has the unique functions that:

the luminous viewpoints of the left eye and the right eye are respectively subjected to flicker training, so that the opportunity and the capability of the affected eye or the weak eye to participate in training, vision and vision recovery can be increased.

Meanwhile, in the process that the left and right eye luminous viewpoints alternately flicker, the visual residual of the healthy eyes can adjust the visual desire of the weak eyes, which is beneficial to getting through the visual passage of the weak eyes, enhancing the eye-brain communication capacity of the weak eyes, being beneficial to rapidly improving the vision of the weak eyes and being beneficial to the compensation capacity of the left and right eyes and the fusion capacity of the two eyes.

And the two eyes twinkle respectively, so that asthenopia caused by insufficient eye-brain communication capacity is improved, and asthenopia caused by insufficient binocular fusion capacity is improved.

7. Training with adjustable luminance of two eyes:

The method has the unique functions that: the brightness of two eyes can be respectively adjusted for training, one eye of a normal person is a dominant eye, the other eye of the normal person is an adjunctive eye, and the training is not to mention the patient with the ametropia. The traditional instrument has two windows with the same brightness and can be trained simultaneously, so that good eyes actively participate, weak eyes passively follow or even do not follow, and further, the refractive error is more and more serious.

The brightness of the luminous viewpoints of the left eye and the right eye is respectively adjustable, and the program for increasing the training strength of the amblyopia is started while the brightness in the amblyopia window is increased, so that the amblyopia training eye becomes the dominant eye, the rapid improvement of the amblyopia vision is facilitated, the degree difference between two eyes is facilitated to be gradually reduced, and the refractive error is facilitated to be gradually eliminated.

(2) The etiology of astigmatism-forming power, and its treatment:

1. the power of astigmatism generation, the eyes for near distance or super-near distance need to be highly focused for seeing → time is long → extraocular muscle is poorly focused for seeing → intraocular muscle is poorly regulated for seeing → object image is located behind retina beside fovea → fundus peripheral visual field is locally elongated → local deformation occurs when seeing a large object such as a doorframe and a window frame which need to see the whole by means of peripheral visual field at the moment → the brain does not allow the phenomenon (false alarm) to occur → the cornea is pulled by extraocular muscle for compensating the defect of fundus deformation → the deformation disappears when seeing the doorframe again at the moment; however, when the human eye looks at a small object at a distance → the light is transmitted through the deformed cornea → refracted into the central fovea of the retina without deformation → a phenomenon of a front-back ghost occurs; the brain does not tolerate ghosting → again the cornea is pulled back. Moreover, the adjustment speed never keeps up with the switching speed of the distance view and the near view, so that the vision fatigue of the astigmatic person is heavy.

2. A method of instrumental treatment of astigmatism,

during training, attention is paid to the tiny light-emitting viewpoints in the center of the lamp, and the tiny light-emitting viewpoints at the periphery of the lamp can help balance the visual field at the near part of the eyeground, so that the visual field is restored to a plane, and the first focus of astigmatism of the eyeground is eliminated.

② omnibearing eyeball yoga movement. The whole process from finding to pointing the visual axis to the luminous viewpoint is to balance the peripheral visual field far away from the eyeground and near, and simultaneously improve the quick searching capability, the gathering capability, the positioning capability and the balancing capability of the extraocular muscles; balancing the extraocular muscles is the cause of eliminating extraocular muscles that form astigmatism;

once both the fundus and the extraocular muscles return to a state of equilibrium, the cornea recovers naturally, and astigmatism is eliminated naturally.

(3) Weak laser:

the weak laser has the greatest characteristic that the direct irradiation of biological tissues can not cause irreversible damage, but can generate benign biological stimulation, response reaction and photochemical effect, so that various functions of the organism, such as nerve impulse transmission, blood function, enzyme activity, immunity, metabolism and the like, are regulated, and the aims of treating diseases and beautifying are achieved by balancing and improving the functions. Currently, weak laser therapy has been widely used clinically, such as weak laser external acupuncture point irradiation, weak laser acupuncture, weak laser blood irradiation, and the like. This emerging physical therapy (weak laser medical therapy) has gained widespread acceptance in recent years by physicians and patients, as described by the us laser medical specialist walbash in the book "use of laser in medicine and biology": "laser biostimulation may be the hallmark of a new application of laser in medicine, which is more valuable than the application of laser to destroy and dissect tissue".

The laser illumination brightness is high, the directionality is strong, the coherence is good, the monochromaticity is pure, the retina macular area can be effectively stimulated, blood cells in a retina blood vessel can increase energy and oxygen carrying activity, the passive oxygen supply and oxygen and nutrient receiving capacity of retina neurons are enhanced, the retina is subjected to a micro-thermal physical therapy effect, the eyeground imaging quality is improved, and meanwhile, the emmetropization process of eyeballs is accelerated. And through the mechanical effect of the ultrasonic wave and the thermal effect of the ultrasonic wave emitted by the ultrasonic transducer 5, the micro-thermal physiotherapy effect is generated on the eyeball while the intraocular cells are massaged, so that the blood circulation of the whole eyeball is improved.

Claims

1. A bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation; the method comprises the following steps: the system comprises a plurality of visual mark points, a pupil distance adjusting module, a lens and one or more sound-producing elements, wherein the lens can enable a luminous viewpoint to form a clear and distinguishable secondary substructure; wherein: the visible mark points are luminous viewpoints and/or reflective viewpoints and/or refractive viewpoints; the visible light-emitting viewpoint includes: a laser-visible light-emitting viewpoint and a non-laser-visible light-emitting viewpoint; the laser-viewable light-emitting viewpoint includes: the laser comprises a laser light emitting diode, a vertical cavity surface emitting laser based on liquid crystal regulation and control, and a vertical cavity surface emitting laser based on organic light emitting diode regulation and control; the non-laser-viewable light-emitting viewpoints include: at least one of a common light emitting diode, an incandescent lamp, a liquid crystal, or an organic light emitting diode; the one or more sound generating elements on the carrier comprise: an ultrasonic transducer capable of generating ultrasonic waves and a sounding element capable of giving out prompt sounds or induction words; it is characterized in that the preparation method is characterized in that,

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

2. A bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation; the method comprises the following steps: the system comprises a plurality of visual mark points, a pupil distance adjusting module, a lens and one or more sound-producing elements, wherein the lens can enable a luminous viewpoint to form a clear and distinguishable secondary substructure; wherein: the visible mark points are luminous viewpoints and/or reflective viewpoints and/or refractive viewpoints; the visible light-emitting viewpoint includes: a laser-visible light-emitting viewpoint and a non-laser-visible light-emitting viewpoint; the laser-viewable light-emitting viewpoint includes: the laser comprises a laser light emitting diode, a vertical cavity surface emitting laser based on liquid crystal regulation and control, and a vertical cavity surface emitting laser based on organic light emitting diode regulation and control; the non-laser-viewable light-emitting viewpoints include: at least one of a common light emitting diode, an incandescent lamp, a liquid crystal, or an organic light emitting diode; the one or more sound generating elements on the carrier comprise: an ultrasonic transducer capable of generating ultrasonic waves and a sounding element capable of giving out prompt sounds or induction words; it is characterized in that the preparation method is characterized in that,

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

3. A bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation; the method comprises the following steps: the system comprises a plurality of visual mark points, a pupil distance adjusting module, a lens and one or more sound-producing elements, wherein the lens can enable a luminous viewpoint to form a clear and distinguishable secondary substructure; wherein: the visible mark points are luminous viewpoints and/or reflective viewpoints and/or refractive viewpoints; the visible light-emitting viewpoint includes: a laser-visible light-emitting viewpoint and a non-laser-visible light-emitting viewpoint; the laser-viewable light-emitting viewpoint includes: the laser comprises a laser light emitting diode, a vertical cavity surface emitting laser based on liquid crystal regulation and control, and a vertical cavity surface emitting laser based on organic light emitting diode regulation and control; the non-laser-viewable light-emitting viewpoints include: at least one of a common light emitting diode, an incandescent lamp, a liquid crystal, or an organic light emitting diode; the one or more sound generating elements on the carrier comprise: an ultrasonic transducer capable of generating ultrasonic waves and a sounding element capable of giving out prompt sounds or induction words; it is characterized in that the preparation method is characterized in that,

the bionic comprehensive therapeutic apparatus comprises: a carrier;

a laser-visible light emitting viewpoint (1) located on the carrier; and,

4. The apparatus of claim 1, 2 or 3, further comprising an ultrasonic transducer on the carrier;

the ultrasonic transducer is arranged in a mode comprising: the ultrasonic transducer (5) is arranged at the near peripheral visual field on a (3-D) (3-D') circuit board in front of eyes, the ultrasonic transducer (5) is arranged in a carrier at the near eye side (5-1) and in a carrier at the periphery of an eye socket, or the ultrasonic transducer (5) is arranged in the eye socket at the near eye side and can be accommodated in a (123-T) slightly deformable oval silica gel capsule type treatment head in a lens concave surface which can enable a luminous viewpoint to form a clear and distinguishable secondary substructure;

5. A bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation; the bionic comprehensive therapeutic apparatus comprises: a carrier;

an ultrasonic transducer (5) located on the carrier; and/or

A laser light emitting diode (1) located on the carrier; and/or

A plurality of visible marking points (3) located at the periphery of the carrier; and

6. The bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation according to claim 1, 2, 3, 4 or 5, wherein the wavelength of the light beam selected by the laser light emitting diode is between 440 nm and 1300 nm;

7. The bionic therapeutic apparatus for myopia and amblyopia with laser for increasing stimulation of peripheral visual field according to claim 1, 2, 3, 4 or 5, wherein the plurality of visible marking points, when the bionic therapeutic apparatus is placed in the space of human and is determined to be a certain distance away from human eyes, at least part of the plurality of visible marking points are located near the limit of the periphery of the visual range of human eyes; or, part of the plurality of visible marking points are positioned near the limit of the periphery of the visible range of human eyes, and part of the plurality of visible marking points are positioned near the center of the visible range of human eyes;

8. The bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation according to claim 1 or 2 or 3 or 4 or 5,

9. The bionic myopia and amblyopia comprehensive therapeutic instrument with laser for increasing peripheral visual field stimulation according to claim 1 or 2 or 3 or 4 or 5,

Wherein,

the (5) ultrasonic transducer is arranged at the near peripheral visual field on a (3-D) (3-D') circuit board in front of the eye, and the ultrasonic treatment dosage is 1.5-2.5W/cm^2；；

The ultrasonic transducer (5) is arranged in a carrier at the near-eye side (5-1) of the carrier and around the eye support orbit, and the ultrasonic treatment dosage is 0.5-1.5W/cm^2；；

The ultrasonic transducer (5) is arranged in the near-eye side eye support and can be accommodated in a (123-T) slightly deformable elliptical silica gel capsule type treatment head which can enable a luminous viewpoint to form a lens concave surface with a clear and distinguishable secondary substructure, and the ultrasonic treatment dosage is 0.1-0.75W/cm^2；。

10. The bionic short sight and amblyopia combined therapeutic apparatus with laser for increasing peripheral visual field stimulation as claimed in claim 1, 2, 3, 4 or 5, wherein when said laser LEDs select more than one, the switching of the optical paths of the laser beams with different wavelengths is accomplished by the Nx 1 optical fiber coupler called the optical fiber flange plate in cooperation with the on/off switching between the laser beams with different wavelengths or by the optical path switcher.

11. The bionic therapeutic apparatus for myopia and amblyopia with laser for increasing peripheral visual field stimulation according to claim 1, 2, 3, 4 or 5, wherein said bionic therapeutic apparatus further comprises an ultrasonic control unit and a luminous control unit:

wherein,

the light-emitting control unit is used for controlling the light-emitting viewpoints to switch between a light-emitting state and a non-light-emitting state in a certain sequence; and the visible running track is limited by controlling the light-emitting sequence of the plurality of light-emitting viewpoints, so that the bionic visual training is completed.