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Findings from a new study published in Translational Vision Science & Technology (TVST) show the brain, not the eye, controls the cellular process that leads to glaucoma. The results may help develop treatments for one of the world's leading causes of irreversible blindness, as well as contribute to the development of future therapies for preserving brain function in other age-related disorders like Alzheimer's.
In the TVST paper, Refined Data Analysis Provides Clinical Evidence for Central Nervous System Control of Chronic Glaucomatous Neurodegeneration, vision scientists and ophthalmologists describe how they performed a data and symmetry analysis of 47 patients with moderate to severe glaucoma in both eyes. In glaucoma, the loss of vision in each eye appears to be haphazard. Conversely, neural damage within the brain caused by strokes or tumors produces visual field loss that is almost identical for each eye, supporting the idea that the entire degenerative process in glaucoma must occur at random in the individual eye -- without brain involvement.
However, the team of investigators discovered during their analysis that as previously disabled optic nerve axons -- that can lead to vision loss -- recover, the remaining areas of permanent visual loss in one eye coincide with the areas that can still see in the other eye. The team found that the visual field of the two eyes fit together like a jigsaw puzzle, resulting in much better vision with both eyes open than could possibly arise by chance.
"As age and other insults to ocular health take their toll on each eye, discrete bundles of the small axons within the larger optic nerve are sacrificed so the rest of the axons can continue to carry sight information to the brain," explains author
According to the researchers, the cellular process used for pruning small optic nerve axons in glaucoma is "remarkably similar to the apoptotic mechanism that operates in the brains of people afflicted with Alzheimer's disease."
"The extent and statistical strength of the jigsaw effect in conserving the binocular visual field among the clinical population turned out to be remarkably strong," said Sponsel. "The entire phenomenon appears to be under the meticulous control of the brain."
The TVST paper is the first evidence in humans that the brain plays a part in pruning optic nerve axon cells. In a previous study, Failure of Axonal Transport Induces a Spatially Coincident Increase in Astrocyte BDNF Prior to Synapse Loss in a Central Target, a mouse model suggested the possibility that following injury to the optic nerve cells in the eye, the brain controlled a pruning of those cells at its end of the nerve. This ultimately caused the injured cells to die.
"Our basic science work has demonstrated that axons undergo functional deficits in transport at central brain sites well before any structural loss of axons," said
"This is a groundbreaking advance in vision science. This research represents a breakthrough in our understanding of glaucoma, a disease that blinds millions of people," said Dr.
Sponsel has already seen how these findings have positively affected surgically stabilized patients who were previously worried about going blind. "When shown the complementarity of their isolated right and left eye visual fields, they become far less perplexed and more reassured," he said. "It would be relatively straightforward to modify existing equipment to allow for the performance of simultaneous binocular visual fields in addition to standard right eye and left eye testing."
Authors of the TVST paper suggest their findings can assist in future research with cellular processes similar to the one used for pruning small optic nerve axons in glaucoma, such as occurs in the brains of individuals affected by Alzheimer's.
"If the brain is actively trying to maintain the best binocular field, and not just producing the jigsaw effect accidentally, that would imply some neuro-protective substance is at work preventing unwanted pruning," said co-author of the TVST paper
The scope of this work will be expanded into the current UIWRSO research program, under the coordination of Dr.
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