Lee, Y-C., Li, Y-C., LIN, K-C.*, Chen C-L., Wu, Y-H., Kuo, C-C., Yeh, Y-P., & Liu, T-X.Y-C., Li, Y-C., LIN, K-C.*, Chen C-L., Wu, Y-H., Kuo, C-C., Yeh, Y-P., & Liu, T-X.LeeLi, Yi-ChunYi-ChunLiKEH-CHUNG LINChen, Chia-LingChia-LingChenYI HSUAN WUKuo, ChihchiehChihchiehKuoYeh, Yi-PingYi-PingYehLiu, Ting-XuanTing-XuanLiu2022-02-102022-02-102021-09-081745-6215https://scholars.lib.ntu.edu.tw/handle/123456789/593983The sequence of establishing a proximal stability or function before facilitation of the distal body part has long been recognized in stroke rehabilitation practice but lacks scientific evidence. This study plans to examine the effects of proximal priority robotic priming and impairment-oriented training (PRI) and distal priority robotic priming and impairment-oriented training (DRI).enBilateral motor priming; Distal priority; Impairment-oriented training; Proximal priority; Randomized controlled trial; Robotic therapy; Stroke; Upper extremity rehabilitation[SDGs]SDG3adult; aged; Article; cerebrovascular accident; clinical article; clinical effectiveness; comparative effectiveness; controlled study; follow up; human; motor function test; motor performance; musculoskeletal disease assessment; prediction; randomized controlled trial; rating scale; single blind procedure; training; treatment planning; cerebrovascular accident; randomized controlled trial (topic); robot assisted surgery; robotics; upper limb; Humans; Randomized Controlled Trials as Topic; Robotic Surgical Procedures; Robotics; Single-Blind Method; Stroke; Upper Extremityjournal article10.1186/s13063-021-05561-6344969382-s2.0-85114460565WOS:000693804800003https://scholars.lib.ntu.edu.tw/handle/123456789/582445