Direct to brain bionic eye

Technology - how will it work?

The Monash Vision system will combine state of the art digital and biomedical technology with consumer-friendly glasses.

A digital camera embedded in the glasses will capture images. As your head turns, the glasses, of course, turn with you. Cutting edge digital processors will modify the images captured by the camera; a wireless transmitter will then present the image that you are "looking at" to a chip that has been implanted at the back of the brain. The chip will then directly stimulate the visual cortex of the brain with electrical signals using an array of micro-sized electrodes -the brain will learn to interpret these signals as sight.

Will it destroy the areas of natural sight I still have?

With many conditions, patients gradually lose sight in some areas of their visual field but not others. As the MVG approach does not require eye surgery, we believe that existing sight will be retained and supplemented with the direct to brain bionic eye*. The exact effectiveness of the restored sight will be determined through research and clinical programs. This is likely to vary strongly between patients depending on their medical history and individual conditions.

How will the brain implant be inserted?

Using standard neurosurgery techniques, a small area of the skull will be temporarily removed. A sterile, biologically inert chip will be placed directly on the surface of the visual cortex of the brain. The small area of the skull will then be replaced and eventually heal, providing a natural barrier to protect against infection*.

Will the bionic eye work for me?

The direct to brain bionic eye is being developed for people with vision impairment caused by a number of conditions, including glaucoma, macular degeneration and diabetic retinopathy*. It may also help people who have damage to their optic nerves or eyes resulting from trauma or disease.

MVG Technical Advancements and Tools:

- Cutting edge biomedical materials that are safe for implanting in the brain.
- Advanced digital processing technology.
- The latest in wireless transmission to reduce the risk of infection.
- Advanced microchips and digital arrays to stimulate the brain.
- State of the art commercial design and production expertise.