Toward the development of a color visual prosthesis

Objective. All of the human prosthetic visual systems implanted so far have been achromatic. Schmidt et al (1996 Brain 119 507-22) reported that at low stimulation intensities their subject reported that phosphenes usually had a specific hue, but when the stimulus intensity was increased, they desaturated to white. We speculate here that previous B/W prosthetic systems were unnecessarily over-stimulating the visual cortex to obtain white phosphenes, which may be why unexpected alterations in phosphenes and seizures were not an uncommon occurrence. A color prosthesis would have the advantage of being elicited by lower levels of stimulation, reducing the probability of causing epileptogenic responses. Approach. A 'hybrid' mode of stimulation is suggested, involving a combination of B/W and color stimulation, which could provide color information without reducing spatial resolution. Main results. Colors in the real world are spread along intensity and chromatic gradients. Significance. Software implementation strategies are discussed, as are the advantages and challenges for possible color prosthetic systems.

Automated summary

This study discusses the advantages of color prosthetic systems in reducing the likelihood of epileptic seizures. A 'hybrid' mode of stimulation is proposed to provide both B/W and color stimulation, to obtain color information without reducing spatial resolution. Software implementation strategies are discussed, along with the advantages and challenges of possible color prosthetic systems.