When people close their eyes, they can form mental images of things that exist only in their minds. Neuroscientists studying this phenomenon at medical schools in the Texas Medical Center believe that there may be a way to use these mental images to help some of the estimated 39 million people worldwide who are blind.
Scientists in the laboratories of Michael Beauchamp, Ph.D., an associate professor of neurobiology and anatomy at the The University of Texas Health Science Center at Houston (UTHealth) Medical School, and Daniel Yoshor, M.D., an associate professor of neurosurgery and neuroscience at Baylor College of Medicine, have discovered a neural mechanism for conscious perception that could aid efforts to capitalize on the brain’s image-generating ability. Findings appeared in the advance online publication of the journal Nature Neuroscience on June 3.
“While much work remains to be done, the possibilities are exciting,” said Beauchamp, the study’s lead author. “If successful, we would in essence bypass eyes that no longer work and stimulate the brain to generate mental images. This type of device is known as a visual prosthetic.”
Here is how such a device might work. Someone who is blind might wear eyeglasses containing a webcam. The tiny camera would relay information to a computer chip implanted in a person’s brain, which would activate the “mind’s eye.”
“With all the remarkable advances in computers and technology in recent years, the time is now ripe to develop a visual prosthetic. A key obstacle to progress right now is our limited understanding of how brain activity leads to visual perception. This new study is a step toward our goal of better understanding visual perception, so we are better able to make a useful visual prosthetic,” said Yoshor, the study’s senior author.
The Houston team and others working in the field of neural engineering are focused on repairing disorders of the brain and nervous system.
In the newly published study, scientists directly stimulated the brain to create the illusion of a flash of light called a phosphene. Right now, researchers can generate one flash at a time but many more will be needed to create useful images.
The occipital lobe (the part of the brain at the back of the head) is responsible for vision and mental images. The brain uses tiny electrical charges to relay information among nerve cells. By electrically stimulating the occipital lobe, the brain can be fooled into perceiving things that are not actually there.
The key finding in the new study was that electrical stimulation only results in the illusion of a flash when there is activity in another region of the brain, the temporoparietal junction. When there was much activity in this other area of the brain, participants always perceived the flashes. Conversely when there was little activity, subjects never did.
The three patients who volunteered to participate in the study ranged in age from 18 to 47 and they were being treated for epilepsy at St. Luke’s Episcopal Hospital, where Yoshor serves as chief of neurosurgery. As for a next step, Beauchamp and Yoshor plan to conduct a larger patient study and create multiple flashes of light at the same time. Twenty-seven or so simultaneous flashes might allow participants to see the outline of a letter.
Notes about this blindness research article
Study co-authors include Sarah Baum, a student in the UTHealth Graduate School of Biomedical Sciences, as well as Ping Sun and Andreas Tolias, Ph.D., both from Baylor.
Funding: The study, which is titled “Electrocorticography links human temporoparietal junction to visual perception,” was supported by grants from the United States National Institutes of Health and the Veterans Health Administration.
Contact: Rob Cahill – The University of Texas Health Science Center at Houston (UTHealth)
Source: The University of Texas Health Science Center at Houston press release
Original Research: Abstract for ““Electrocorticography links human temporoparietal junction to visual perception” by Michael S Beauchamp, Ping Sun, Sarah H Baum, Andreas S Tolias & Daniel Yoshor in Nature Neuroscience 2012 doi:10.1038/nn.3131