Abstract
The purpose of this study was to evaluate the efficacy and safety of artificial vision by using a direct optic nerve electrode (AV-DONE) in a blind patient with retinitis pigmentosa (RP). This device, comprising three wire electrodes (0.05 mm in diameter), was implanted into the optic disc of a patient with RP with no light perception vision and the device was left implanted. Six months later, visual sensations were elicited by electrical stimulation through each electrode and the thresholds for the phosphene perception elicited by pulses of 0.25-ms duration/phase and a pulse frequency of 320 Hz were 30, 5, and 70 µA for each electrode. The phosphenes, which ranged in size from that of a match head to an apple, were round, oval, or linear, primarily yellow, and focally distributed. The area of the phosphenes changed when the electrical stimulation was supplied from different electrodes. No complications arose during the follow-up period. Localized visual sensations were produced in a blind patient with advanced RP, suggesting that our system could lead to the development of a useful visual prosthesis system.
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Sakaguchi, H., Kamei, M., Fujikado, T. et al. Artificial vision by direct optic nerve electrode (AV-DONE) implantation in a blind patient with retinitis pigmentosa. J Artif Organs 12, 206–209 (2009). https://doi.org/10.1007/s10047-009-0467-2
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DOI: https://doi.org/10.1007/s10047-009-0467-2