KR20210027842A - An treatment apparatus for dry eye syndrome and a method for controlling that - Google Patents

Abstract

The present invention relates to an ophthalmic treatment device and a method for controlling the same. More specifically, the present invention provides the ophthalmic treatment device comprising: a body unit formed to be wearable on the user′s head; a light irradiation unit provided in the body unit and irradiating light of a wavelength that can be absorbed to the user′s eyelid tissue; a detection unit detecting the position information of the user′s eyelid; and a control unit controlling the light irradiation unit based on the position information of the eyelid detected by the detection unit. The present invention has an advantage of inducing constant treatment.

Description

Ophthalmic treatment device and its control method {AN TREATMENT APPARATUS FOR DRY EYE SYNDROME AND A METHOD FOR CONTROLLING THAT}

The present invention relates to an ophthalmic treatment device and a control method thereof, and more particularly, to an ophthalmic treatment device and a control method thereof for performing treatment using light while a user is worn on a head.

Dry eye syndrome is a condition in which the eyeball surface becomes dry as the tear itself or some components of the tear are insufficient, or the tear film is excessively evaporated to perform a sufficient lubrication action on the eyeball surface. These symptoms are accompanied by irritation of the eye tissue, and in severe cases can cause eye irritation.

Dry eye syndrome is mainly due to dysfunction of the meibomian gland located inside the eyelid. Specifically, as the lipid secretion path of the meibomian gland is narrowed or blocked, a fat layer cannot be properly formed in the eyeball, and this causes excessive evaporation of tears, resulting in dry eye.

Various methods have been proposed to treat such dry eye syndrome, and as one of them, a treatment device for restoring the function of the meibomian gland by irradiating light to the eyelid tissue and transmitting energy has been developed. However, since the conventional treatment device using light can only be treated with the patient's eyes closed, there is a limit in inducing constant treatment.

An object of the present invention is to provide an ophthalmic treatment device and a control method thereof capable of performing treatment in response to a situation in which a patient moves the eyelid.

In order to achieve the above object, the present invention provides a body portion formed to be wearable on a user's head, a light irradiation portion provided on the body portion and irradiating light having a wavelength absorbable into the user's eyelid tissue, and of the user's eyelid. It provides an ophthalmic treatment apparatus including a detection unit for detecting position information, and a control unit for controlling the light irradiation unit based on the position information of the eyelid detected by the detection unit.

The control unit may control to adjust at least one of an irradiation position of the treatment light, an irradiation area of the treatment light, or a cross-sectional shape of the treatment light based on the position information of the eyelid detected by the detection unit.

In addition, the light irradiation unit may irradiate light having a wavelength in an infrared region as treatment light.

The detection unit may detect information on the position of the user's eye, the size of the user's eyelid, and the real-time position of the eyelid.

As an example, the detection unit may include an imaging device that acquires an image of the front of the user's eye, and may detect the position of the eyelid based on the image acquired by the imaging device. In this case, the imaging device may acquire an infrared image by receiving light of an infrared wavelength.

As another example, the detection unit includes a light-emitting unit that irradiates the detection light to the front of the user's eye and a light-receiving unit that receives the detection light reflected from the front of the eye. The location can be detected.

In this case, the detection unit may acquire eyelid position information of a sample section among the user's eyes, and detect the position information of the eyelid based on the acquired position information of the sample section.

On the other hand, the light irradiation unit may be installed so that the position or irradiation direction of the light irradiation unit is adjustable, and the position or irradiation direction may be adjusted according to the position information of the eyelid.

Alternatively, the light irradiation unit may include a plurality of light source units, and may be configured to irradiate treatment light by selectively operating some of the plurality of light sources according to the position information of the eyelid.

Alternatively, the light irradiation unit may be configured to adjust the cross section of the irradiated treatment light under the control of the controller.

Specifically, the light irradiation unit includes a first light irradiation unit for irradiating treatment light to the upper eyelid and a second light irradiation unit for irradiating treatment light to the lower eyelid, and the first light irradiation unit and the second light irradiation unit are independently It can be configured to be operable.

And, the control unit controls the operation of the first light irradiation unit based on the position information of the upper eyelid at the start of treatment and the operation of the upper eyelid during treatment, and the second light irradiation unit based on the position information of the lower eyelid at the start of treatment. Can control the operation of

Meanwhile, the ophthalmic treatment apparatus may further include a display unit installed on the body and displaying image content to a user. In this case, the first light irradiation unit and the second light irradiation unit may be positioned above and below the display unit, and may be configured to irradiate treatment light to the user's eyelid while the display unit displays image content.

It is an object of the present invention to detect initial position information of the user's eyelid when the user wears an ophthalmic treatment device on the head, and to treat the eyelid by operating a light irradiation unit based on the detected initial position of the eyelid. Irradiating light, detecting a position change of the eyelid while the treatment light is irradiated, and adjusting the operation of the light irradiation unit so that the treatment light can be irradiated based on the detected position change information of the eyelid. It can also be achieved by a control method of the ophthalmic treatment device including the step.

Here, adjusting the operation of the light irradiation unit may adjust at least one of an irradiation position of the treatment light, an irradiation area of the treatment light, or a cross-sectional shape of the treatment light.

In the step of detecting the position change of the eyelid, the position change of the eyelid may be detected using image information obtained by the detection unit or reflection information of the detection light.

In this case, the step of detecting the change in the position of the eyelid may include acquiring information on the position of the eyelid in a sample section among the user's eyes, and detecting the change in the position of the eyelid based on this.

In addition, the step of detecting the change in the position of the eyelid may detect the change in the position of the upper eyelid.

According to the present invention, since it is possible to irradiate the treatment light to a desired position in consideration of the position information of the eyelid even while the patient is moving the eyelid, treatment can be performed while the patient is performing other activities.

In particular, in recent years, an image display device in the form of goggles has been widely used, and it is possible to simultaneously perform treatment for dry eye syndrome even while using such an image display device, thereby inducing constant treatment.

1 is a perspective view showing an ophthalmic treatment device according to an embodiment of the present invention,
FIG. 2 is a block diagram showing various components provided in the body of FIG. 1;
3 is a plan view schematically showing the inside of the body portion of FIG. 1;
4 is a view showing a state of the meibom gland located on the inner side of the eyelid,
5 is a diagram showing an example of an operation of a light irradiation unit controlled by a control unit;
6 is a view showing another example of the operation of the light irradiation unit controlled by the control unit;
7 is a block diagram showing the main components of an apparatus for treating dry eye syndrome according to another embodiment of the present invention;
8 is a plan view schematically showing the inside of the body portion of FIG. 2;
9 is a view showing the operation of the first light irradiation unit and the second light irradiation unit of Figure 7;
10 is a view showing a sample area for detecting eyelid position information in the detection unit of FIG. 7;
11 is a flow chart showing a control method of the dry eye treatment apparatus of FIG. 7;
12 is a flow chart showing a control method according to another mode of the dry eye treatment apparatus of FIG. 7;
13 is a flow chart showing a control method according to another mode of the ophthalmic treatment device;
14 is a perspective view showing the configuration of a body part according to another embodiment of the ophthalmic treatment device of the present invention,
Meanwhile, FIG. 15 is a view showing a main configuration of an ophthalmic treatment apparatus according to another embodiment of the present invention.

Hereinafter, an ophthalmic treatment apparatus and a control method thereof according to an embodiment of the present invention will be described in detail with reference to the drawings. In the following description, the positional relationship of each component will be described based on the drawings in principle. The drawings may simplify the structure of the invention for convenience of description or may be exaggerated if necessary. Therefore, the present invention is not limited thereto, and it goes without saying that various devices may be added, changed, or omitted.

In addition, hereinafter, the'position' of the eyelid may be a position determined by the position of the eye when the treatment device is worn, and further may include a position that changes according to an operation of the eyelid such as blinking an eye.

In addition, the term'shape' of the eyelid may be a shape determined by a patient's unique appearance such as the size of the eye or the eyelid, and further may include a shape that changes according to the movement of the eyelid such as blinking. .

Hereinafter, in describing the ophthalmic treatment apparatus according to the present invention, a treatment apparatus for treating dry eye syndrome is mainly described, but the present invention is not limited thereto, and various ophthalmic lesions such as glaucoma and various lesions occurring on the retina are described. It should be noted that it can be applied to the treatment device to be treated.

1 is a perspective view showing an ophthalmic treatment device according to an embodiment of the present invention. As shown in FIG. 1, the ophthalmic treatment apparatus 1 according to the present embodiment includes a body part 100 provided with various components, and a wearing part 101 connected to the body part and worn on the user's head. Consists of including.

The body part 100 is configured in the shape of a goggle, and is positioned in front of the user's eyes when wearing the treatment device. Various components for performing various treatments in front of the patient's eyes and detecting the patient's condition are installed inside the body part. The inner edge of the body portion in contact with the patient's face may be provided with a buffer member to provide a good fit and block light from the outside. During the operation of the treatment device, heat is generated by an operation such as a light irradiation unit or a display unit, and such heat may dry the inner space of the body where the anterior eye is located. Accordingly, the buffer member may be made of a material capable of suppressing the discharge of moisture from the inside and helping the moisture from the outside to flow into the interior, and as an example, such a buffer member may use a Gore-Tex material. . As a separate embodiment, it is also possible to additionally include a separate humidification module provided inside the body and periodically providing moisture to a space where the anterior eye is exposed during operation of the treatment device.

The wearing part 101 is a component worn on the user's head so that the body part 100 can be fixed in front of the user's eyes. In FIG. 1, the wearing part is configured in a band structure made of an elastic material, but the wearing part may be configured in various structures in addition to this. In addition, although the body part and the wearing part are configured in the form of goggles in this embodiment, the present invention is not limited thereto, and the body part and the wearing part may be configured to have a structure in the form of glasses in which the front of the eye is not shielded (FIG. 14 Reference).

FIG. 2 is a block diagram showing various components included in the body portion of FIG. 1, and FIG. 3 is a plan view schematically showing an inner side of the body portion of FIG. 1. Hereinafter, main components provided in the body portion will be described in detail with reference to FIGS. 2 and 3.

2 and 3, on the inside of the body part, based on the light irradiation unit 200 for irradiating treatment light, the detection unit 300 for detecting position information of the eyelid, and the position information of the eyelid detected by the detection unit. It includes a control unit 400 for controlling the light irradiation unit. In this case, the light irradiation unit, the detection unit, and the like are provided in a pair of structures to correspond to both eyes and may be located at positions symmetrical to each other. However, in the following description, for convenience of description, the configuration of one side of the pair of components provided will be mainly described.

The light irradiation unit 200 is configured to irradiate treatment light to a user's eyelid corresponding to a treatment location, and includes at least one light source. The treatment light irradiated by the light irradiation unit 200 may use light having a wavelength that can be absorbed by the eyelid tissue. Further, the treatment light may be light having a wavelength in an invisible region, and as an example, may be light having a wavelength in an infrared band so as to prevent the user's vision from being obstructed by the treatment light during treatment. The treatment light irradiated by the light irradiation unit 200 is absorbed by the eyelid tissue and converted into thermal energy to treat dry eye syndrome.

4 is a view showing a state of the meibom gland located on the inner side of the eyelid. As shown in Fig. 4, the meibomian gland is a type of sebaceous gland located inside the upper and lower eyelids in contact with the eyeball. The mybom gland secretes lipids to form a fat layer on the front of the eyeball, thereby minimizing the evaporation of water in the eyeball. At this time, when the secretion of lipids is not smooth due to a dysfunction of the meibomian gland, the moisture layer of the eyeball is exposed to the outside and excessively evaporates, causing dry eye syndrome. Accordingly, the light irradiation unit of the present embodiment may provide thermal energy to the eyelid tissue by irradiating treatment light onto the eyelid tissue, thereby dissolving lipid residues or wastes formed in the secretion path to secure a discharge path. In addition, the transmitted thermal energy induces blood circulation in the eyelid tissue to improve the function of the meibomian gland, thereby treating dry eye syndrome.

The light irradiation unit 200 of this embodiment, as shown in FIG. 3, is provided inside the body part, and is disposed in front of the user's eyes while the user is wearing the treatment device. The light irradiation unit 200 may be configured using various light sources such as an LED, a laser diode, and a flash lamp. In addition, the shape of the light source may be configured in various structures such as a surface light source structure, a point light source structure capable of changing the irradiation position, and a light source array structure composed of a plurality of light sources capable of selectively blinking and controlling the irradiation position.

The treatment light irradiated to the light irradiation unit of the present embodiment may be light having a wavelength band having excellent absorption characteristics by lipids. Specifically, the wavelength of the treatment light may be in the range of 900 nm to 950 nm, or may be in the range of 1140 nm to 1260 nm. As an example, in the present embodiment, light having a wavelength of 1210 nm may be used as the treatment light.

On the other hand, the detection unit 300 is a component for detecting the user's eyelid position information. The position of the eye and the shape and size of the eyelid differ from person to person. In addition, even for the same user, the relative position of the treatment device and the eye may be different depending on the state of wearing the treatment device. Further, the position of the eyelid may be changed due to an operation such as blinking of the user's eyes during treatment. Accordingly, the treatment apparatus according to the present embodiment includes the detection unit 300 for detecting position information of the eyelid according to the above-described cause in real time, and the irradiation operation of the treatment light can be adjusted according to the detected position information.

The detection unit 300 may be configured in various ways by using various known detection methods. For example, an image of a user's eye may be acquired using an imaging device, and position information of the eyelid may be detected based on this. Alternatively, it is also possible to detect the position information of the eyelid by using the difference in reflection characteristics between the eyelid and the eyeball surface by using the detection light. Alternatively, it is possible to configure to detect the temperature distribution of a region adjacent to the user's eye, and to detect position information of the eyelid based on a difference in surface temperature between the eyelid and the eyeball.

The detection unit 300 according to the present embodiment includes, as an example, an image unit 310 including an imaging device and a processing unit 320 that analyzes image information obtained from the image unit to detect a position of the eyelid. The image unit 310 acquires an eye image of a user by irradiating photographing light. At this time, the photographing light irradiated by the image unit 310 may use infrared light in the invisible region, or it is possible to acquire an image using the light irradiated from the above-described light irradiation unit without irradiating a separate photographing light. Do. The processing unit 320 may analyze the acquired image to detect position information of the eyelid. For example, by extracting the lower boundary of the upper eyelid and the upper boundary position of the lower eyelid displayed on the image, it is possible to detect information such as the position of the eyelid, the shape of the eyelid, and the real-time operation state of the eyelid.

The treatment device 1 according to the present embodiment may check initial position information of the eyelid in a state of wearing the treatment device by the detection unit 300 described above. Here, the initial position information may include a relative position between the treatment device and the eyelid (eye) according to the wearing state. In addition, the initial location information may include information on the shape of the eyelid when the user closes the eye and the shape of the eyelid when the user opens the eye. In addition, the detection unit may check real-time position information of the eyelid according to the patient's eye blinking or other eyelid movement (eg, opening the eye wide or small) during treatment after wearing the detection unit.

Meanwhile, the controller 400 is a component that controls the operation of each component, and controls the operation of each component based on a user's setting content, a control algorithm of a previously stored database, or a signal transmitted from another component.

The control unit 400 of the present embodiment may receive the position information of the eyelid detected from the detection unit 300 described above, and control the light irradiation unit 200 to irradiate the treatment light to the eyelid position of the user based on this. Accordingly, it is possible to irradiate the treatment light to a desired treatment position in response to the physical characteristics of the user, the wearing state of the treatment device, and the eyelid movement of the user during treatment, and it is possible to minimize the irradiation of the treatment light to the eyeball.

Specifically, as the control unit 400 controls the operation of the light irradiation unit 200, the position to which the treatment light is irradiated is adjusted, the size and shape of the area to which the treatment light is irradiated, or the cross-sectional shape of the treatment light is adjusted. The irradiation motion of the back treatment light can be adjusted in various ways. In this case, the control of the light irradiation unit may be performed in various ways depending on the configuration and operation method of the light irradiation unit. 5 is a view showing an example of the operation of the light irradiation unit controlled by the control unit, Figure 6 is a view showing another example of the operation of the light irradiation unit controlled by the control unit.

As an example, as shown in FIG. 5, the light irradiation unit is composed of a surface light source 210, and a shutter 220 provided in front of the light source may be provided. In addition, the control unit 400 may control the position of the shutter 220 to change to adjust the area to which the treatment light is irradiated. For example, when it is detected that the user's eyes are closed as a result of detecting the position information of the eyelid, the shutter 220 may be lowered to control the treatment light to be irradiated to a wider irradiation area. On the other hand, when it is detected that the user is in an open state, the shutter 220 is raised to selectively limit the area to which the treatment light is irradiated to block the irradiation of the treatment light to the eyeball.

As another example, as shown in FIG. 6, the light irradiation unit 200 includes a light source array 230 including a plurality of light sources, and each light source may be configured to selectively blink. In addition, the control unit 400 may control to irradiate the treatment light by selectively emitting only light sources corresponding to the positional information of the eyelid among the light source array 230. In this case, the treatment light may be irradiated to various positions and various irradiation areas according to the position of the eye and the operation of the eyelid.

In the above, two examples of the control operation of the light irradiation unit by the control unit have been described, but various methods may be applied in addition to this. For example, the light irradiation unit may be configured to adjust the position and irradiation direction of the light source, and the control unit may be configured to adjust the light irradiation position and irradiation area by moving the position of the light source or changing the irradiation direction. Alternatively, the light irradiation unit may include various types of masks for determining a cross-sectional shape of light on the front surface of the light source, and the control unit may change the position and type of the mask to adjust the shape and size of the region to which the treatment light is irradiated. Furthermore, by controlling the operation of the light irradiation unit in various ways in addition to this, the treatment light may be irradiated to correspond to the positional information of the eyelid.

FIG. 7 is a block diagram showing major components of an apparatus for treating dry eye syndrome according to another embodiment of the present invention, and FIG. 8 is a plan view schematically showing the inner side of the body portion of FIG. 7. Hereinafter, an apparatus for treating dry eye syndrome according to another embodiment of the present invention will be described in detail with reference to FIGS. 7 and 8. However, for the same or similar components and technical features as compared to the above-described embodiment, detailed descriptions will be omitted in order to avoid duplication of description. In addition, as in the above-described embodiment, each component of the present embodiment, such as a light irradiation unit, a detection unit, an image unit, and a display unit, has a pair of structures that are symmetrically arranged to correspond to both eyes, but one configuration is used for convenience of explanation. It will be explained mainly.

7 and 8, the dry eye treatment apparatus according to the present embodiment includes a light irradiation unit 200, a detection unit 300, an image unit 310, and a control unit 400, as described above. Compared with the embodiment, a display unit 500 may be further included.

The display unit 500 is a component that displays image or image content, and is disposed inside the body unit 100 as shown in FIG. 8, and is disposed in the center so that it can be positioned in front of the user's eyes when worn. The display unit 500 may be configured as a display device. The user can use the content displayed on the display unit while the treatment is in progress. Alternatively, by displaying various types of information for treatment through the display unit 500, it is possible to provide treatment-related information to a user or guide an operation for treatment.

The image unit 310 is configured to include an imaging device, and is configured to acquire a user's eye image. As an example, the imager 310 may be configured to acquire an infrared image using infrared light. Accordingly, it is possible to obtain information on the location of the user's eye, the shape of the eyelid, and the like. In addition, the information obtained by the image unit 310 may be transmitted to the control unit 400 and used to control the operation of the light irradiation unit 200. In addition, the image acquired by the image unit 310 may be displayed to the user through the display unit 500, and by using this, the user's posture (eg, gaze position, movement of eye blinking, etc.) during treatment is guided. It is also possible. However, in FIG. 7, the image unit is shown as a separate block from the detection unit, but since position information of the eyelid can be obtained through the image unit, it may be understood as a sub-configuration of the detection unit.

The light irradiation unit 200 includes a first light irradiation unit 240 and a second light irradiation unit 250 as shown in FIGS. 7 and 8. As shown in FIG. 8, the first light irradiation unit 240 may be provided above the display unit 500, and the second light irradiation unit 250 may be provided below the display unit 500. In addition, the first light irradiation unit 240 may irradiate the treatment light to the upper eyelid of the eyelid, and the second light irradiation unit 250 may irradiate the treatment light to the lower eyelid.

The first light irradiation unit 240 and the second light irradiation unit 250 may adjust the treatment light irradiation operation based on the location information of the upper and lower eyelids detected by the detection unit 300. Here, the location information of the lower eyelid is determined by initial location information such as the wearing state of the treatment device, the location of the user's eye, and the shape of the eyelid, and a location change hardly occurs during treatment. In contrast, the position of the upper eyelid is changed not only by the above-described initial position information, but also by an operation such as blinking an eye during treatment. In consideration of the operation characteristics of the upper and lower eyelids, the first light irradiation unit 240 and the second light irradiation unit 250 are configured to operate independently of each other, and the first light irradiation unit 240 is a second It may be configured to have a greater degree of freedom of operation than the light irradiation unit 250.

9 is a diagram illustrating the operation of the first light irradiation unit and the second light irradiation unit of FIG. 7. Hereinafter, as an example, the structure of the first and second light irradiation units of the present embodiment will be described in detail with reference to FIG. 9.

9, the first light irradiation unit 240 and the second light irradiation unit 250 are installed so that the position of the light source can be moved independently, respectively. 9 illustrates a structure in which the first light irradiation unit 240 and the second light irradiation unit 250 are movable in the vertical direction, respectively, but may be configured to be movable in the horizontal direction as well as the vertical direction. Accordingly, when the user wears the treatment device, the control unit 400 may adjust the positions of each of the light irradiation units 240 and 250 to correspond to the initial positions of the upper and lower eyelids, respectively.

Furthermore, the first light irradiation unit 240 is configured to enable additional operation control compared to the second light irradiation unit 250. In this embodiment, as an example, as shown in FIG. 9, the first light irradiation unit 240 is configured to enable a rotational operation, and the direction in which the treatment light is irradiated is changed by the rotational operation, or the treatment light is It is configured so that the size of the covered irradiation area can be adjusted (for example, the treatment light is irradiated to a wider irradiation area, such as when the eyes are closed when rotating downward, and a more limited irradiation area, such as an open eye when rotating upward. The treatment light is irradiated). Accordingly, the first light irradiation unit 240 may adjust the irradiation content of the treatment light in response to the change in the treatment position value according to the operation of the upper eyelid during treatment through this operation.

However, it should be noted that the operation structure of the first and second light irradiation units described above is only an example, and it is possible to configure the light source structure and the control operation in various ways in addition to this.

Meanwhile, the detection unit 300 according to the present embodiment includes a light emitting unit 330 and a light receiving unit 340 as shown in FIG. 7. The light emitting unit 330 is configured to irradiate the detection light in the direction of the user's eyes, and the light receiving unit 340 receives the detection light reflected from the user's eyes. At this time, the reflective characteristics of light are different depending on the structure. In the case of the eyelid, since it is a structure with low light transmission characteristics, the reflectance of light is high, whereas the eyeball has a structure in which light can be transmitted, so the reflectance of light is low. Accordingly, the processing unit 320 may detect the position information of the eyelid based on the information received by the light receiving unit 340.

Such a detection unit may be configured so that the light-emitting unit irradiates the detection light to the entire eye area, and the light-receiving unit can receive light reflected on the entire eye area. It can be configured to detect the location information of the eyelid by using the reflective property of.

10 is a diagram illustrating a sample area for detecting eyelid position information in the detection unit of FIG. 7. First, as shown in FIG. 8, the detection unit 300 is provided on one side of the display unit 500 in a vertical direction. Among them, a light-emitting unit is provided at one end of the detection unit 300, and a light-receiving unit 340 is formed along the remaining length direction. And, as shown in Figure 10, based on the reflection information in the sample section (S) corresponding to a partial area of the user's eyes, it is to check the position of the eyelid (L) and the position (O) of the eyeball It is possible.

In addition, the processing unit 320 may detect position information of the eyelid in the entire eye section based on the position of the eyelid in the sample section S. In this case, the method of detecting the information of the entire section based on the information of the sample section in the processing unit 320 may be configured to refer to content previously stored in the database or to derive it through a predetermined algorithm. Alternatively, it is also possible to detect the entire section information corresponding to the sample section information by referring to the entire eye image information acquired by the image unit 310.

In this way, when the detection unit 300 is configured to detect the location information of the entire eyelid based on the reflection information of the sample section, the detection unit 300 can be configured compactly. However, this is an example, and the present invention is not limited thereto, and of course, it may be configured in various structures other than this.

Meanwhile, the control unit 400 controls the light irradiation unit 200 based on the position information of the eyelid detected by the detection unit 300. Specifically, the control unit 400 controls the operation of the first light irradiation unit 240 based on the position information of the upper eyelid, and controls the operation of the second light irradiation unit 250 based on the position information of the lower eyelid. At this time, when controlling the first light irradiation unit 240, the controller 400 considers the initial position information of the upper eyelid at the start of treatment and the position information according to the operation of the upper eyelid during treatment, and the second light irradiation unit 250 During control, it can be controlled by considering the location information of the lower eyelid at the start of treatment.

11 is a flowchart illustrating a control method of the apparatus for treating dry eye syndrome of FIG. 7. Hereinafter, a control method of the apparatus for treating dry eye syndrome according to the present embodiment will be described with reference to FIG. 11.

First, the user wears the dry eye treatment device on the head (S10). Accordingly, components such as the display unit 500, the light irradiation unit 200, and the detection unit 300 provided inside the body unit 100 are located in front of the user's eyes.

When the user wears the treatment device, the step of detecting the initial position of the eyelid is performed (S20). In this step, information on the position of the user's eyes (the relative position of the treatment device and the eye according to the wearing state of the treatment device and the user's appearance characteristics), and the size and shape of the upper and lower eyelids may be detected. This step may be obtained by photographing an image of the eye in the above-described imaging unit 310 and processing the image in the processing unit 320.

Further, in the step of detecting the initial position, it is also possible to obtain reference information so that the position information of the entire eyelid can be detected from the position information of the eyelid in the sample section (S). This means that while the user performs the blinking operation (while the upper eyelid is operating along the entire movable section), the image unit acquires a plurality of images, and based on this, the correlation between the eyelid position in the sample section and the entire eyelid position is derived. I can. Alternatively, while performing the blinking operation, the image unit acquires a plurality of images, and the light-emitting unit and the light-receiving unit acquire reflection information of the sample section, thereby deriving the correlation.

When the initial position of the eyelid is detected, the control unit 400 controls the light irradiation unit 200 to irradiate the treatment light (S30). At this time, the control unit 400 moves the first light irradiation unit 240 to a corresponding position based on the initial position of the upper eyelid, and moves the second light irradiation unit 250 to a corresponding position based on the initial position of the lower eyelid. After moving, the treatment light can be irradiated. The treatment light irradiated from each light irradiation unit is composed of light of an infrared wavelength that can be absorbed by the eyelid tissue, and the treatment light is irradiated to the upper and lower eyelid surfaces, respectively, to begin treatment of dry eye syndrome.

While the above-described treatment is in progress, the detection unit 300 performs a step of continuously detecting a change in the position of the eyelid (S40). In this step, the detection unit 300 monitors the change in the position of the eyelid using information received by the light receiving unit 340 by reflecting the detection light irradiated from the light emitting unit 330 on the tissue. At this time, the change in the position of the eyelid may be based on the reflection information of the detection light in the sample section S as described above, and it is possible to detect the change in the position of the entire eyelid.

In addition, when a change in the position of the eyelid is detected, the controller 400 may control the operation of the light irradiation unit 200 to correspond to the changed position of the eyelid. At this time, in the above-described detection step (S40), the position change due to the operation of the upper eyelid may be detected, and the control unit 400 maintains the operation of the second light irradiation unit 250, and the first light irradiation unit ( 240) can be adjusted. Accordingly, the controller 400 may adjust the irradiation area covered by the treatment light by rotating the first light irradiation unit by a predetermined angle according to the changed position information of the upper eyelid.

In this way, while the treatment light is irradiated, the position change of the eyelid is monitored in real time, the irradiation position of the treatment light is adjusted, and the treatment is terminated when the treatment end point arrives by a preset mode and user's manipulation (S60).

12 is a flowchart illustrating a control method according to another mode of the apparatus for treating dry eye syndrome of FIG. 7. Hereinafter, a control method according to a mode different from that of FIG. 11 will be described in detail with reference to FIG. 12.

While the control mode shown in FIG. 11 is a method of controlling the light irradiation unit by detecting the position information of the eyelid in real time, in this control mode, the position information of the eyelid is detected for each predetermined time period, and accordingly, the light irradiation position of the light irradiation unit Can be configured to adjust. In the case of such a control mode, by simplifying the control contents, unnecessary control in the use mode in which there is little change in the position of the eyelid (eg, while viewing contents through the display unit) can be minimized.

As shown in FIG. 12, when the user wears the dry eye syndrome treatment apparatus on the head (S110), first, a step of detecting the position of the eyelid using the detection unit 300 is performed (S120). The location information detected in this step may include information on the location of the user's eyes, and the sizes and shapes of the upper and lower eyelids. Further, the location information detected in this step may include location change information according to the user's eyelid motion during a preset detection time (eg, 3 seconds to 5 seconds).

In addition, the control unit 400 may determine a position to which the treatment light is irradiated based on the position information of the eyelid during the set detection time. At this time, the location to which the treatment light is irradiated may be determined according to a preset algorithm, and such an algorithm may be configured in various ways. As an example, the controller 400 may determine the irradiation position of the treatment light based on the average value of the position of the eyelid during the detection time. In this case, the light irradiation position may be determined except for information on fast motion of the eyelid such as blinking of an eye. As another example, the control unit 400 may determine the light irradiation position by extracting the position where the eyelid stays the longest during the detection time. As another example, the control unit 400 determines the light irradiation position so that the treatment light is irradiated only to the area where the eyelid is always located during the detection time (for example, a common minimum area among the changing position information of the upper eyelid during the detection time). It is also possible to do it.

In this way, when the treatment light irradiation position in consideration of the position of the eyelid is determined through the step of detecting the eyelid position, the control unit 400 controls the light irradiation unit 200 to irradiate the treatment light (S130).

In this way, the operation of detecting the position information of the eyelid and determining the irradiation position of the treatment light based thereon may be repeatedly performed according to a predetermined detection period (eg, 5 minutes). Accordingly, it is determined whether the detection period has arrived (S140), and when the detection period has arrived, the detection unit and the control unit may perform the above-described eyelid position detection step again (S120), thereby correcting the irradiation position of the treatment light. At this time, while performing the step of detecting the eyelid position again, the light irradiation unit maintains a state of irradiating the treatment light to the existing irradiation position. When the light irradiation position is determined again through the eyelid position detection step, the control unit 400 may control the light irradiation unit 200 to adjust the irradiation position of the treatment light to irradiate the treatment light (S130).

As described above, in this control mode, the step of performing the treatment by detecting the position of the eyelid at a predetermined detection period and adjusting the irradiation position of the treatment light based on this is repeatedly performed according to a predetermined period, and the treatment is terminated when the treatment end point arrives. (S150).

However, in FIG. 12, it has been described that the step of detecting the position of the eyelid and the step of adjusting the position of irradiation of the treatment light are performed multiple times according to a predetermined period, but after detecting the position of the eyelid in the above-described manner at the start of treatment, It is also possible to control to irradiate the treatment light to the determined light irradiation location throughout the entire treatment phase.

In the case of using the ophthalmic treatment apparatus according to the present embodiment, since the user can perform dry eye treatment in the process of using the image content through the display unit 500, it is possible to induce constant treatment. At this time, by controlling the irradiation position of the treatment light in consideration of the location information of the eyelid, it is possible to minimize irradiation of the treatment light to the eyeball. In particular, by separately providing a light irradiation unit for irradiating the treatment light to the upper and lower eyelids and controlling them independently, it is possible to accurately irradiate the treatment light.

Meanwhile, in the above-described embodiment, a function of performing a treatment while a user uses image content using a display unit is mainly described, but the present invention is not limited thereto. As another example, the user is configured to irradiate the treatment light to the entire anterior segment area while the eyes are closed, and the detection unit monitors the position change of the user's eyelids and, when the user is recognized as opening the eyes, the treatment light is directed to the user's eyes. In order to prevent irradiation, it is possible to control to end irradiation of the treatment light or to change the irradiation direction of the treatment light. Hereinafter, this control mode will be described in more detail with reference to FIG. 3.

13 is a flow chart showing a control method according to another mode of the ophthalmic treatment device. As shown in FIG. 13, a step (S210) of a user wearing an ophthalmic treatment device is performed, and a step of detecting an initial position of the eyelid is performed (S220). In this case, the initial position of the eyelid may be a relative positional relationship between the body portion and the anterior eye portion when the user wears the treatment device.

After performing the above step, the control unit 400 performs a step of irradiating the treatment light by operating the treatment light irradiation unit 200 (S230). In the present embodiment, the irradiation of the treatment light may be performed on the entire anterior segment with the user's eyes closed, as described above. In this step, since treatment is performed in a state in which the area of the eyelid to which the treatment light is irradiated is maximized, it may correspond to an intensive treatment mode, and because it is possible to perform treatment in a user's sleep state, it may correspond to a sleep mode.

The treatment light irradiation step may be performed for a preset time, and while the treatment light is irradiated, the detection unit 300 may continuously monitor position information (including movement information) of the eyelid (S240). When it is determined that the eye is opened while the eyelid is opened through the monitoring step (S250), the control unit 400 controls the treatment light irradiation unit to prevent irradiation of the treatment light into the eyeball (S260). In this case, the control unit 400 may control the treatment light irradiation unit 200 to temporarily stop irradiation of the treatment light, and may control the position to which the treatment light is irradiated to the outside of the eyeball.

In addition, when it is confirmed that the user has closed his/her eyes again through eyelid position monitoring, the treatment light irradiation may be performed, and the treatment may be terminated when the treatment light irradiation is completed for a preset time (S270).

The control mode according to FIG. 13 may be one control mode that can be selected from the ophthalmic treatment apparatus of FIG. 7 described above, and may also be performed using the ophthalmic treatment apparatus of FIG. 2.

Meanwhile, FIG. 15 is a view showing a main configuration of an ophthalmic treatment apparatus according to another embodiment of the present invention. Hereinafter, an ophthalmic treatment apparatus according to another embodiment of the present invention will be described with reference to FIG. 15. However, for the same or similar components and technical features as compared to the above-described embodiment, detailed descriptions will be omitted in order to avoid duplication of description. In addition, as in the above-described embodiment, each component such as the light irradiation unit of the present embodiment is made of a pair of structures symmetrically arranged to correspond to both eyes, but one component will be described centering on one component for convenience of description.

The above-described embodiments are a configuration that detects eyelid position information and adjusts the irradiation position of the treatment light based on this so as to minimize irradiation of the treatment light into the eyeball even when the position of the eyelid is different and the position of the eyelid is moved. In contrast, in the present embodiment, it is possible to minimize the irradiation of the wavelength of the treatment light into the eyeball by wearing the blocking part on the anterior eye.

Specifically, the treatment apparatus according to the present embodiment, compared with the above-described embodiments, is configured to include a body portion 100, a light irradiation portion 200, and the control unit 400, and additionally includes a blocking portion 600. It can be configured to include.

At this time, the blocking part 600 is provided in the form of a contact lens, as shown in FIG. 15, and is configured to be worn by the user on the anterior eye surface. In this case, the light irradiation unit 200 irradiates the treatment light having a wavelength absorbed by the eyelid tissue, and the blocking unit 600 may be configured so that light corresponding to the wavelength of the treatment light does not pass. Further, the blocking unit is configured to transmit light having a wavelength in the visible ray band, so that the user can secure a view even when wearing the blocking unit. As an example, the treatment light is composed of light having a wavelength of 1210 nm, and the blocking unit 600 is coated with a material capable of reflecting light of a wavelength of 1210 nm while transmitting light of a wavelength of the visible light band. It can be a structure. However, the configuration of such a blocking unit is only an example, and it goes without saying that it can be changed by applying a structure of various conventional blocking units.

According to this embodiment, even if the treatment light irradiated from the light irradiation unit is irradiated to the eyeball as well as the eyelid tissue, it is possible to prevent the treatment light from being irradiated into the eyeball by the blocking unit located in front of the eyeball. In this case, it is possible to omit the configuration of the detection unit and simply implement the configuration of the light irradiation unit by simply providing the blocking unit.

In the above, the ophthalmic treatment apparatus according to the present invention has been described based on some embodiments, but the specific configurations of each component such as the light irradiation unit and the detection unit have been described by way of example of some configurations among various examples that can be changed. This can be done by applying the configuration. In addition, if a person has ordinary knowledge in the technical field to which the present invention belongs, the present invention can be modified or changed in various ways without departing from the scope of the technical features of the present invention defined in the appended claims. Reveal.

Claims (21)

A body portion formed to be worn on the user's head;
A light irradiation unit provided on the body and irradiating light having a wavelength absorbable into the eyelid tissue of the user;
A detection unit that detects location information of the user's eyelid; And
Ophthalmic treatment apparatus comprising a; a control unit for controlling the light irradiation unit based on the position information of the eyelid detected by the detection unit. The method of claim 1,
The control unit controls to adjust at least one of an irradiation position of the treatment light, an irradiation area of the treatment light, or a cross-sectional shape of the treatment light based on position information of the eyelid detected by the detection unit. The method of claim 1,
The detection unit detects information on the position of the user's eye, the size of the user's eyelid, and the real-time position of the eyelid. The method of claim 1,
The light irradiation unit is an ophthalmic treatment device, characterized in that for irradiating the light of the wavelength in the infrared region. The method of claim 1,
The detection unit includes an imaging device for acquiring an image of the front of the user's eye, and detecting the position of the eyelid based on the image acquired by the imaging device. The method of claim 5,
The imaging device is an ophthalmic treatment apparatus, characterized in that for obtaining an infrared image by receiving light of an infrared wavelength. The method of claim 1,
The detection unit includes a light emitting unit that irradiates the detection light to the front of the user's eye and a light receiving unit that receives the detection light reflected from the front of the eye, and detects the position of the eyelid based on the reflection characteristic of the detection light according to the position. Ophthalmic treatment device, characterized in that to. The method of claim 1,
The detection unit obtains the position information of the eyelid of the sample section of the user's eyes, and detects the position information of the eyelid based on the obtained position information of the sample section. The method of claim 1,
The light irradiation unit is installed so that the position or irradiation direction of the light irradiation unit is adjustable, and the position or irradiation direction is adjusted according to the position information of the eyelid. The method of claim 1,
The light irradiation unit includes a plurality of light source units, and selectively operates some of the plurality of light sources according to position information of the eyelid to irradiate treatment light. The method of claim 1,
The light irradiation unit is configured to adjust the cross section of the treatment light irradiated by the control of the control unit. The method of claim 1,
The light irradiation unit includes a first light irradiation unit irradiating treatment light to the upper eyelid and a second light irradiation unit irradiating treatment light to the lower eyelid, and the first light irradiation unit and the second light irradiation unit operate independently. Ophthalmic treatment device, characterized in that configured to be possible. The method of claim 12,
The control unit controls the operation of the first light irradiation unit based on the position information of the upper eyelid at the start of treatment and the operation of the upper eyelid during treatment, and the second light irradiation unit is based on the position information of the lower eyelid at the start of treatment. Ophthalmic treatment device, characterized in that to control the operation. The method of claim 11,
It is installed on the body portion, further comprising a display for displaying the image content to the user,
The first light irradiation unit and the second light irradiation unit are positioned above and below the display unit, respectively, and irradiate treatment light to the eyelid of the user while the display unit displays image content. Device. Detecting initial position information of the user's eyelid when the user wears the ophthalmic treatment device on the head;
Irradiating treatment light to the eyelid by operating a light irradiation unit based on the detected initial position of the eyelid;
Detecting a position change of the eyelid while the treatment light is irradiated; And
Controlling the operation of the light irradiation unit so that the treatment light is irradiated based on the detected position change information of the eyelid. The method of claim 15,
The controlling of the operation of the light irradiation unit includes controlling at least one of an irradiation position of the treatment light, an irradiation area of the treatment light, or a cross-sectional shape of the treatment light. The method of claim 15,
The control method of the dry eye syndrome treatment apparatus, characterized in that the treatment light has a wavelength of an infrared band that can be absorbed by the eyelid tissue. The method of claim 15,
The detecting of the position change of the eyelid comprises detecting the position change of the eyelid using image information obtained from a detection unit or reflection information of the detection light. The method of claim 15,
The detecting of the position change of the eyelid comprises acquiring the position information of the eyelid in a sample section of the user's eyes, and detecting the position change of the eyelid based thereon. The method of claim 15,
The step of detecting the position change of the eyelid includes detecting the position change of the upper eyelid. A body portion formed to be worn on the user's head;
A light irradiation unit provided on the body and irradiating light having a wavelength absorbable into the eyelid tissue of the user; And
Dry eye layer treatment apparatus comprising a; provided to be wearable on the surface of the user's eyeball, a blocking unit that blocks the light irradiated from the light irradiation unit from being irradiated to the inside of the eyeball.

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