Severe Weakness & Early Recovery
The robot moves the limb completely. Used in acute and subacute stages when patient has minimal or no voluntary movement. Prevents contractures and maintains ROM.

The Cyclomotus Robotic Trainer delivers high-intensity, repetitive, task-specific training for upper and lower limb recovery. By providing passive, active-assistive, and active resistance modes, it enables patients with severe weakness to perform thousands of movement repetitions — the key to neuroplasticity and motor learning after stroke, spinal cord injury, and brain injury.
Personalised, technology-driven rehabilitation in Moosapet, Hyderabad.
The robot moves the limb completely.
The robot assists only as much as needed.
The robot moves the limb completely. Used in acute and subacute stages when patient has minimal or no voluntary movement. Prevents contractures and maintains ROM.
The robot assists only as much as needed. Patient initiates movement; the robot fills in the rest. Promotes motor learning and cortical reorganization.
The robot provides resistance against patient-initiated movement. Builds strength, improves motor control, and increases cardiovascular endurance.
Robotic gait and limb training is designed for neurological patients who need high-repetition, task-specific practice to rewire motor pathways.
Early robotic training (within 2–4 weeks post-stroke) significantly improves gait speed and motor function. Ideal for patients with severe paresis who cannot walk independently.
Body-weight support and robotic guidance enable safe stepping practice even with incomplete SCI — promoting neural regeneration and functional recovery.
Cognitive-motor dual-task training in robotic devices addresses both physical and attentional deficits common after traumatic brain injury.
Children with cerebral palsy benefit from repetitive, controlled gait patterns that retrain aberrant motor patterns and improve walking efficiency.
Neuroplasticity — the brain's ability to reorganize neural pathways — is driven by repetition, intensity, and task-specificity. The Cyclomotus delivers all three: thousands of precise movement repetitions at adjustable intensity, while the patient practices the actual task of walking.
The robot enforces physiologically accurate gait kinematics (hip flexion 30–40°, knee flexion 20–30°) at near-normal speeds, ensuring every repetition trains the correct pattern.
Adjustable unloading allows severely impaired patients to practice walking safely without the fear of falling, reducing compensatory strategies.

DakshinRehab clinical pathwayfNIRS studies show increased motor cortex activation in the affected hemisphere after active robotic training — evidence of neuroplastic change.
Smooth, continuous robotic movement prevents velocity-dependent spasticity triggers common in manual-assisted gait training.
Clinical comparison
A typical hospital physiotherapy session delivers 30–50 steps of gait practice. The Cyclomotus delivers 1,000+ repetitions per session. Research by Hidler et al. and systematic reviews confirm that higher repetition counts correlate with greater neuroplastic changes and functional recovery. At DakshinRehab, our inpatient neuro-rehab program combines 3–4 hours of daily robotic, suspension, and EMG training — versus 30 minutes in standard care.
Every session records steps, symmetry, range of motion, and active contribution percentage — objective data to guide clinical decisions.
DakshinRehab in Moosapet, Hyderabad is one of the few clinics offering robotic gait training for neurological rehabilitation. No hospital referral needed — our neuro-rehab specialists assess candidacy and design personalized protocols.
“The brain does not care about intention — it cares about repetition. Give me 1,000 correct steps on a robot, and I will show you a brain that has rewired itself to walk again.”
A Robotic Training Session at DakshinRehab
Individualized robotic protocol established
Patient safely positioned and robot calibrated
High-volume, correct repetitions completed
Improved voluntary motor control documented
Objective progress recorded; plan updated
The most advanced neuro-rehabilitation technology in Moosapet
Volume matters for neuroplasticity. The Cyclomotus delivers 20× more repetitions than conventional therapy in the same timeframe.
Every step is biomechanically correct — no compensatory patterns that create secondary problems.
From 100% passive guidance to full active resistance — the robot grows with your recovery.
Real-time data on steps, symmetry, range, and effort removes guesswork from rehabilitation planning.
Body-weight support and robotic guidance allow safe walking practice even with severe weakness or balance deficits.
fNIRS and MEP studies confirm active robotic training increases cortical activation and motor evoked potential amplitudes.

Robotic gait training is safe for most neurological patients, but certain conditions require medical clearance or avoidance.
Unstable fractures or non-union in the trained limb
Severe osteoporosis with fracture risk
Uncontrolled epilepsy or recent seizures
Unhealed surgical wounds or pressure ulcers
Severe fixed contractures that prevent orthosis fitting
Cardiovascular instability (uncontrolled BP, arrhythmia)
Severe cognitive impairment preventing compliance
Acute deep vein thrombosis
Our expert physiotherapists and rehabilitation specialists at DakshinRehab bring decades of combined experience to your recovery.

Director, Human MOVEMENT specialist Ortho Neuro Physiotherapist | Stroke & Spine Rehab Specialist

CPO (Certified Prosthetist & Orthotist)
Clinical Rehabilitation Specialist | Founder, DakshinRehab

MS (General Surgery), DNB (Vascular Surgery)
Sr. Consultant Vascular & Endovascular Surgeon | Diabetic Foot & Wound Care
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Book AppointmentHow high-intensity robotic rehabilitation compares to conventional neuro-rehab approaches
Traditional therapy provides 50–100 steps per session. Robotic training delivers 1,000+ steps with precise kinematics — the repetition volume required for meaningful neuroplastic change.
Learn MorePassive movement maintains joint flexibility but does not drive neuroplasticity. Robotic active-assistive mode requires patient effort, engaging motor learning circuits for lasting functional gains.
Learn MoreHome exercises lack the precision, repetition, and safety of robotic guidance. Incorrect movement patterns practiced at home reinforce compensatory strategies rather than true recovery.
Learn More