感觉系统
体感系统
本体感觉
微刺激
感知
编码(内存)
计算机科学
任务(项目管理)
人工智能
计算机视觉
人机交互
视觉感受
接口(物质)
感觉
信号(编程语言)
培训(气象学)
感觉线索
自然(考古学)
触觉辨别
触觉知觉
神经生理学
多传感器集成
沟通
感官替代
运动(音乐)
神经科学
人工视觉
视觉控制
触觉刺激
触觉技术
作者
Samuel Senneka,Maria C. Dadarlat
标识
DOI:10.1073/pnas.2521769123
摘要
Humans rely on both proprioceptive and visual feedback during reaching, integrating these two sensory streams to improve movement accuracy and precision. Patients using a brain-computer interface will similarly require artificial proprioceptive feedback in addition to vision to finely control a prosthesis. Intracortical microstimulation (ICMS) elicits sensory perceptions that could replace the lost proprioceptive signal. However, some learning may be required for encoding artificial sensation, as current technology does not give access to neurons with all of the desired encoding properties. We developed a freely moving mouse behavioral task in which to test learning and integration of artificial sensory information with natural vision. Mice implanted with a 16-channel microwire array in the primary somatosensory cortex were trained to navigate to randomly selected targets upon the floor of a custom behavioral training chamber. Target location was encoded with visual and/or patterned multichannel ICMS feedback. Mice received multimodal feedback from the beginning of training of the behavioral task, achieving 75% on multimodal trials after approximately 1,000 training trials. Mice also quickly learned to use the ICMS signal to locate invisible targets, achieving 75% proficiency on ICMS-only trials when tested. Critically, we found that performance with ICMS was as good or better than performance with natural vision, and that performance on multimodal trials significantly exceeded unimodal performance (vision or ICMS), demonstrating that animals rapidly learned to integrate natural vision with artificial sensation.
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