肘关节康复机器人研究进展OA
Research progress on elbow joint rehabilitation robots
肘关节辅具为肘关节损伤的康复提供了简便的机械方式.人工智能与肘关节辅具结合,产生了肘关节康复机器人,以满足不同损伤类型患者的个性化康复需求.肘关节康复机器人主要由机械刚体结构、机械动力结构、仿生传感器和软件系统组成.康复机器人的机械刚体结构相当于人体骨骼和关节,包括连杆结构和齿轮传动系统.机械动力结构相当于人体肌肉和韧带,负责产生和控制运动所需的力和力矩,其驱动器类型主要有气动驱动器、弹性驱动器和绳驱动器.仿生传感器相当于人体感受器,主要包括光电编码器、力和力矩传感器、肌电信号传感器和温度传感器.各类软件系统(算法、控制、机器学习)构成了机器人的"神经中枢",相当于人体的大脑和脊髓,负责核心的智能决策和运动控制.肘关节康复机器人的核心技术是通过物理构件与软件系统的结合,实现对患者肘关节运动轨迹的精准跟踪,并能依据实时交互力自适应地调节辅助力度,提供被动、助力、主动及阻抗等训练模式,从而为不同康复阶段的患者提供安全、个性和智能的运动训练支持.基于仿生结构设计、精确的阻抗控制、肌电信号的助力模式和虚拟现实任务训练等核心技术,康复机器人明显提升了康复训练的舒适性、康复辅助的精准性和患者依从性.本文综述了肘关节康复机器人的研究现状,阐述其关键组成和主要康复功能的训练模式,分析其临床需求及未来发展方向,旨在为康复机器人的优化提供参考.
Elbow orthoses offer a straightforward mechanical approach for rehabili-tation following elbow joint injuries.The convergence of artificial intelligence with these orthoses has led to the development of elbow rehabilitation robots,designed to address the personalized rehabilitation requirements of patients with diverse injury profiles.A typical elbow rehabilitation robot system comprises four core components:rigid mechanical structure,an actuation system,bionic sensors,and integrated software.The rigid structure,analogous to the human skeletal system,includes linkage mechanisms and gear transmission assemblies.The actuation system,mimicking the function of muscles and ligaments,generates and modulates the necessary forces and torques for movement,employing actuators such as pneumatic,elastic and cable-driven types.Bionic sensors,serving as the robot's perceptual interface,encompass photoelectric encoders,force/torque sensors,electromyo-graphic(EMG)signal sensors,and temperature sensors.The software system,encompassing control algorithms and machine learning models,functions as the"neural center,"enables intelligent decision-making and motion control.The core technological achievement lies in the seamless integration of hardware and software to enable precise tracking of elbow joint kinematics and adaptive modulation of assistive forces based on real-time human-robot interaction.This integration supports multiple training modalities,including passive,assistive,active,and resistive modes and enables safe,personalized,and intelligent rehabilitation support across different recovery phases.By harnessing technologies like bio-inspired design,precise impedance control,EMG-based assistance,and virtual reality-integrated task training,these robotic systems improve training comfort,assistance accuracy,and patient adherence.This review outlines the current state of elbow rehabilitation robotics,details the key system components and primary training modalities,discusses clinical needs and future development trends,and aims to offer insights for the further refinement of rehabilitation robotic systems.
李明;徐方竹;王滇;徐佳琳
宁波市第六医院创伤骨科 宁波市骨科与运动康复临床医学研究中心,浙江 宁波 315040宁波大学医学部,浙江 宁波 315211宁波大学医学部,浙江 宁波 315211中国科学院宁波材料技术与工程研究所先进诊疗材料与技术实验室,浙江 宁波 315201||宁波慈溪生物医学工程研究所,浙江 宁波 315302
医药卫生
康复机器人人工智能肘关节综述
Rehabilitation robotsArtificial intelligenceElbow jointReview
《浙江大学学报(医学版)》 2026 (1)
27-35,9
宁波市科技创新2025重大专项(2022Z147)This study was supported by the Ningbo Science and Technology Innovation 2025 Major Project(2022Z147)
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