KR100460464B1 - Artificial Retina Apparatus using Laser Diode Array - Google Patents

Abstract

The retinal apparatus using the laser diode array of the present invention includes a camera for performing a function of capturing an external video signal, a signal processor for receiving a video signal photographed by the camera and transmitting the image signal to the image information, and the signal The driver circuit unit performs a function of emitting each laser diode with an intensity corresponding to the corresponding pixel of the image information by using the image information received from the processor, and a plurality of laser diodes, and the light emission transmitted from the driver circuit unit. The laser diode array which emits light by a signal, an optical system and a plurality of photo diodes which perform a function of focusing a laser beam from each laser diode of the laser diode array on a photo diode corresponding to the laser diode, die Includes is disposed so as to correspond to the laser diode unit in the retinal stimulation de array.

Description

Artificial retina device using laser diode array {Artificial Retina Apparatus using Laser Diode Array}

The present invention relates to an artificial retina device, and more particularly, to an artificial retina device using a laser diode array.

In recent years, research on artificial retinas to restore visual acuity by inserting a microelectrode array into the retina for patients with damaged retinal cells has been actively conducted.

The artificial retina is the lowest layer of the optic nerve and is designed to restore vision to people who have lost their vision because of damage to the photoreceptor layer, a cell that converts light into electrical signals.

In other words, the other optic nerve is to some extent alive, but for those who only have a problem in converting light into an electrical signal to insert an electrode array near the retina and to stimulate the cell directly through it.

1 shows a cross-sectional view of the retina and a photoreceptor layer with major lesions.

As shown in FIG. 1, the neural electrical signal converted in the photoreceptor layer is signaled while passing through the optic nerve cell layer and then transmitted to the brain along the neural signal transduction pathway.

Methods for restoring vision in people with damaged retinal cells include inserting an array of electrodes in place of the photoreceptor layer, or directly stimulating optic nerve fibers that enter the brain or a ganglion cell layer that delivers signaled nerve signals. .

Among them, an attempt was made to replace retinal cells by themselves by integrating an electrode array and a photo diode array into the photoreceptor layer, but the sensitivity of the photodiode array is weak and the actual generated current stimulates the cells. Not enough to go back to failure.

Currently, a method of converting an image signal into an electric signal using an external CCD camera, a CMOS camera, and the like and transferring the electric signal into an eye through an appropriate medium has been studied.

In power biomedical electronics, power and signal transmission are very important, and there are many difficulties in developing bioelectronics due to the specificity of the electronics located in the living body.

Especially, in the retina, since the transmitted signal is a video signal, it is more difficult to develop than other bioelectronic devices because it has to satisfy the characteristic that the signal must be delivered quickly while the amount of signal to be transmitted is high compared to other types of bioelectronic devices. .

Conventionally, as a method of transmitting a signal to the artificial retina, RF coupling method, an optical link method using a laser and the like have been studied. Both the RF coupling method and the optical link method can transmit signals and power simultaneously, and are identical in that they are wireless. In a bioelectronic device, it is very difficult to send an electric current inside the body, and thus, a signal can be transmitted wirelessly.

RF coupling method uses the induced electromotive force of the primary and secondary coils located inside and outside the eyeball. In this case, complex circuits are necessary because power and signal must be separated from the current induced in the coil, and signal information must be extracted through the signal processing circuit to supply the specified power to the electrode corresponding to the specified pixel. .

If you insert a circuit that performs this signal processing inside the eye and controls the power to the desired electrode, power is needed for the operation of its own circuit, so more power must be supplied from the outside and it occurs during power control inside. There is a problem that the performance is degraded due to the heat.

Moreover, even if such a circuit is inserted into a living body, the signal processing circuit that guarantees the performance of operation in the eye should be made small and light enough to be inserted into the eye, and there is a long time to check the bio stability in the early stage of development. The problem remains.

The method of transmitting signals to the retina using the optical link method has the advantage that it does not receive electromagnetic interference compared to the RF coupling method, except that it is wireless, but this method also modulates a single laser light source to load power and signals, and to provide a single photo. It is a method that separates power and signal through signal processing process inside the eye after converting to current by using diode, so there is no big difference from RF coupling method in terms of signal processing.

In the case of using the optical link method, as in the case of using the RF coupling method, since the method of separating the power and the signal inside the eyeball has the same problem as using the RF coupling method.

The present invention is to solve the above problems, an object of the present invention using a laser diode array using a laser diode array that can restore the vision of a person with damaged retinal cells without inserting a signal processing circuit inside the eye using a laser diode array. It is to provide an artificial retina device.

1 shows a cross-sectional view of the retina and a photoreceptor layer with major lesions.

2 schematically illustrates an artificial retina device according to an embodiment of the present invention.

3 shows a laser beam focused on the photodiode of the retinal stimulation unit.

4 illustrates a state in which a laser beam is focused on a photodiode of the retinal stimulation unit.

5 shows the size of the focal area in the retina by using a ray tracing method.

6 shows the size of the focal area in the retina using the jumper function.

<Description of the symbols for the main parts of the drawings>

110: camera 120: signal processing unit

130: driving circuit unit 140: laser diode array

150: optical system 160: retinal stimulation unit

The retinal apparatus using the laser diode array of the present invention includes a camera for performing a function of photographing an external video signal, a signal processor for receiving a video signal photographed by the camera and converting the image signal into image information, and the signal A driving circuit unit which performs a function of emitting each laser diode with an intensity corresponding to a corresponding pixel of the image information by using the image information converted by the processing unit, and a plurality of laser diodes, and the light emission transmitted from the driving circuit unit A laser diode array that emits light by a signal, an optical system that performs a function of focusing a laser beam from each laser diode of the laser diode array onto a photo diode corresponding to the laser diode, and a laser diode of the laser diode array. ship It includes the plurality of photodiodes and using the electrical signal from the photodiode is composed of electrodes that functions to stimulate the optic nerve retinal stimulation unit in which.

The retinal device of the present invention utilizes a method in which a laser beam of each laser diode focuses on a photo diode on a corresponding photo diode array and an electrode integrated with the photo diode stimulates a cell.

Therefore, in the artificial retina device of the present invention, only the laser diode corresponding to each pixel of the image needs to be driven on the laser diode array to form the image on the retina.

The position information of the pixel is determined by the rows and columns of the laser diode array being driven and the signal intensity is determined by the light emission intensity of the laser diode so that the signal and the power are simultaneously transmitted. In other words, in the artificial retina device of the present invention, there is no need to install a signal processing circuit in the eye that separates and processes signals and power.

2 schematically illustrates an artificial retina device according to an embodiment of the present invention.

As shown in FIG. 2, the artificial retina device of the present invention includes a camera 110, a signal processing unit 120, a driving circuit unit 130, a laser diode array 140, an optical system 150, and a retinal stimulation unit 160. Include.

The camera 110 performs a function of capturing an external image signal and may use a CCD camera or a CMOS camera.

The signal processor 120 receives external image information captured by a CCD camera or a CMOS camera and converts the image information into image information.

The driving circuit unit 130 performs a function of emitting each laser diode at an intensity corresponding to a corresponding pixel of the image information by using the image information received from the signal processing unit.

The laser diode array 140 is composed of a plurality of laser diodes and emits light in accordance with image information by light emission signals transmitted from the driving circuit unit.

The optical system 150 performs a function of focusing a laser beam from each laser diode of the laser diode array on a photo diode corresponding to the laser diode.

The optical system 150 measures the refractive indices of the cornea and eye of the patient using equipment such as an automatic corneal refractometer, and then looks at the laser diode array as the object plane and the photodiode array in the retina as the image plane. The laser beam is designed to focus on the photodiode array.

The retinal stimulation unit 160 is composed of a plurality of photodiodes and electrodes connected to each photodiode. The photodiode is designed to correspond to the laser diode of the laser diode array.

The laser diode and the photodiode may correspond one-to-one, or several photodiodes may correspond to one laser diode.

3 and 4 show the laser beam is focused on the photodiode of the retinal stimulation unit.

As shown in Figs. 3 and 4, the laser beam emitted from the laser diode is designed to be focused on the photodiode corresponding to each laser diode. In this case, the method of focusing the laser beam from the laser diode on the photodiode may be designed such that one laser beam is focused on one photodiode as in the case of FIG. 3, and as in the case of FIG. It can also be designed to focus on multiple photodiodes.

5 and 6 show the size of the focal area in the retina by using the ray tracing method and the jump function.

5 and 6 are simulation results assuming a vertical cavity surface emitting laser (hereinafter, referred to as a VCSEL), which is one of the array-type laser diodes.

When using a single spherical lens, each VCSEL (10 ° divergence angle) of a grid-shaped VCSEL array with a center interval of 100 µm for an image of 20 X 20 pixels is a grid-shaped photo with a center interval of 50 µm. It can be seen that the corresponding point of the diode array is focused without crosstalk.

FIG. 5 shows a focal area every two pixels along a diagonal direction in which the optical system performs poorly in the first quadrant of the photodiode array symmetrical with respect to the center. For example, the sixth area is the 11th pixel with respect to the center. Indicates.

FIG. 6 shows a jump function for the 11th pixel, and it can be seen that the optical link is possible even with a simple optical system for an image of about 20 X 20 pixels.

Although the invention has been described in connection with the preferred embodiments mentioned above, other various modifications and changes may be made without departing from the spirit and scope of the invention. Accordingly, the appended claims are intended to include modifications and variations that fall within the true scope of the invention.

As such, according to the present invention, since the signal processing circuit portion is not required to be inserted into the eye, the structure of the artificial retina device can be simplified, and since the signal processing circuit portion is external to the body, a small amount of power may be supplied to the human body. The advantage is that there is no thermal problem due to the control operation.

Claims (4)

A camera that performs a function of photographing an external video signal, A signal processor for receiving a video signal captured by the camera and converting the image signal into image information; A driving circuit unit configured to emit light of each laser diode at an intensity corresponding to a corresponding pixel of the image information by using the image information converted from the signal processor; A laser diode array composed of a plurality of laser diodes and emitting light by a light emission signal transmitted from the driving circuit unit; An optical system that performs a function of focusing a laser beam from each laser diode of the laser diode array on a photo diode corresponding to the laser diode; Retinal stimulation part consisting of a plurality of photodiodes arranged to correspond to the laser diode of the laser diode array and an electrode for stimulating the optic nerve by using an electrical signal from the photodiode Artificial retina device using a laser diode array comprising a. The method of claim 1, And the laser diode array is a vertical cavity surface emitting laser. The method of claim 1, The laser diode and the photodiode is an artificial retinal device using a laser diode array, characterized in that one-to-one correspond. The method of claim 1, At least two photodiodes correspond to one of the laser diodes artificial retina device using a laser diode array.