PT - JOURNAL ARTICLE AU - Sharlene N Flesher AU - John E Downey AU - Jeffrey M Weiss AU - Christopher L Hughes AU - Angelica J Herrera AU - Elizabeth C Tyler-Kabara AU - Michael L Boninger AU - Jennifer L Collinger AU - Robert A Gaunt TI - Restored tactile sensation improves neuroprosthetic arm control AID - 10.1101/653428 DP - 2019 Jan 01 TA - bioRxiv PG - 653428 4099 - http://biorxiv.org/content/early/2019/05/31/653428.short 4100 - http://biorxiv.org/content/early/2019/05/31/653428.full AB - The sense of touch is critical for skillful hand control1–3, but is largely missing for people who use prosthetic devices. Instead, prosthesis users rely heavily on visual feedback, even though state transitions that are necessary to skillfully interact with objects, such as object contact, are relayed more precisely through tactile feedback4–6. Here we show that restoring tactile sensory feedback, through intracortical microstimulation of the somatosensory cortex7, enables a person with a bidirectional intracortical brain-computer interface to improve their performance on functional object transport tasks completed with a neurally-controlled prosthetic limb. The participant had full visual feedback and had practiced the task for approximately two years prior to these experiments. Nevertheless, successful trial times on a commonly used clinical upper limb assessment task were reduced from a median time of 20.9 s (13.1 - 40.5 s interquartile range) to 10.2 s (5.4 - 18.1 s interquartile range) when vision was supplemented with microstimulation-evoked cutaneous percepts that were referred to different fingers and were graded in intensity based on real-time prosthesis contact forces. Faster completion times were primarily due to a reduction in the amount of time spent attempting to grasp objects. These results demonstrate the importance of tactile sensations in upper-limb control and the utility of creating bidirectional brain-computer interfaces to restore this stream of information using intracortical microstimulation.