Bionic eye also called a Bio Electronic eye is the electronic device that replaces functionality of a part or whole of the eye. It is still at a very early stage of development, but if successful, it could restore vision to people who have lost sight during their lifetime. The principle of Bionic eye is very similar to that of a bionic ear. Bionic eyes and Bionic ears both work by stimulating nerves, which are activated by electrical impulses.
In both cases the patient has a small device implanted to the body that can receive radio signals and transmit those signals to nerves. The healthy human eye has millions of biological solar cells in the retina, called the rods and cones that convert light into electrical signals, which are sent along the optic nerve to the brain where images are formed.
In cases where the retina fails, the nerves behind the retina, which carry electrical impulses, still function. Many people are blind because of the malfunctioning rods and cones. Retinitis pigmentosa and macular degeneration tends to be hereditary and may strike at an early age, while macular degeneration mostly affects elderly.
Currently researchers around the world are exploring ways of restoring sight to the people with retinal degeneration in two methods. One method uses a small video camera-equipped device to capture images, encode them and sent them into eye implant (a silicon chip inserted into the eyeball) via a laser beam that also powers the chip’s solar cell.
Photo sensors convert the light and images into electrical impulses, which charge a plate that stimulates the nerves and transmit the visual information to the brain. The laser and camera can be easily be mounted on eyeglasses without having to wear bulky headgear.
In another method, microchips replace the eye’s malfunctioning natural sensor with an artificial sensor (silicon retina), manufactured on a piece of silicon. When the chip is implanted into the back of the eye and strikes those solar cells, the light is converted into electric signals that travel via the optic nerve to the brain and are interpreted as an image.
Development continues to gauge the compatibility of silicon with living tissue as silicon is toxic to the human body and reacts unfavorably with fluids in the eye, and to make the microchip as non-invasive to the eye as possible. Preliminary tests are on going on the ceramic detectors for biocompatibility, and they appear to be totally stable.
In both cases the patient has a small device implanted to the body that can receive radio signals and transmit those signals to nerves. The healthy human eye has millions of biological solar cells in the retina, called the rods and cones that convert light into electrical signals, which are sent along the optic nerve to the brain where images are formed.
In cases where the retina fails, the nerves behind the retina, which carry electrical impulses, still function. Many people are blind because of the malfunctioning rods and cones. Retinitis pigmentosa and macular degeneration tends to be hereditary and may strike at an early age, while macular degeneration mostly affects elderly.
Currently researchers around the world are exploring ways of restoring sight to the people with retinal degeneration in two methods. One method uses a small video camera-equipped device to capture images, encode them and sent them into eye implant (a silicon chip inserted into the eyeball) via a laser beam that also powers the chip’s solar cell.
Photo sensors convert the light and images into electrical impulses, which charge a plate that stimulates the nerves and transmit the visual information to the brain. The laser and camera can be easily be mounted on eyeglasses without having to wear bulky headgear.
In another method, microchips replace the eye’s malfunctioning natural sensor with an artificial sensor (silicon retina), manufactured on a piece of silicon. When the chip is implanted into the back of the eye and strikes those solar cells, the light is converted into electric signals that travel via the optic nerve to the brain and are interpreted as an image.
Development continues to gauge the compatibility of silicon with living tissue as silicon is toxic to the human body and reacts unfavorably with fluids in the eye, and to make the microchip as non-invasive to the eye as possible. Preliminary tests are on going on the ceramic detectors for biocompatibility, and they appear to be totally stable.
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