Stroke survivors show gait deficits. Traditional rehab works but is labor‑intensive and hard to quantify. We built a Multifunctional Gait Training & Assistive Robot integrating lower‑limb exoskeleton, BCI, asymmetric dynamic body‑weight support, and AI for active, precise neuromodulation, rebuilding musculoskeletal and neural function. Clinical validation shows higher intensity, better outcomes, wider applicability, and strong market potential.

The Multifunctional Gait Training & Assistive Robot overcomes rehab bottlenecks by integrating CNS–peripheral motor control. It combines BCI EEG sensing, AI intention-driven exoskeleton control, real-time physiological feedback, and asymmetric dynamic body weight support to deliver active, personalized, precise neuromodulation and neuroplastic remodeling—setting a new paradigm in precision neurorehabilitation.

As population aging accelerates, stroke and spinal-cord injury cases are rising, driving rehab demand. The Multifunctional Gait Training & Assistive Robot integrates a lower-limb exoskeleton, BCI, asymmetric dynamic body-weight support, and safety control in a modular design deployable in hospitals, rehab centers, and community care. Clinical validation shows it shortens rehabilitation cycles, reduces staffing burden, cuts costs, and—backed by patents and awards—offers strong growth potential.