Discover our wide range of instrumented treadmills from leading manufacturers such as Motek, zebris and h/p/cosmos, perfect for comprehensive and innovative research and rehabilitation. Our portfolio offers models with integrated force plates such as the Motek GRAIL or the h/p/cosmos Gaitway 3D as well as the unique pressure measuring treadmills from zebris. Immerse yourself in the innovative world of instrumented treadmills and be fascinated by the possibilities of state-of-the-art technology.
CAREN
CAREN
CAREN, the most advanced biomechanics lab, enables comprehensive research into human movement and balance.
GRAIL
GRAIL
GRAIL, the gait analysis lab of the future, sets new research and rehabilitation standards with real-time feedback for perturbations and dual-tasking.
M-Gait
M-Gait
M-Gait, the modular high-tech treadmill, offers a split-belt design with dynamic displacement, force measurement, motion capture, bodyweight support, and more.
FDM-T Instrumented Treadmill with Pressure Measurement
FDM-T Instrumented Treadmill with Pressure Measurement
Dynamic gait and running analysis with precise pressure measurement for (rehabilitation) medicine and research.
FDM-TR Mobile Instrumented Treadmill with Pressure Measurement
FDM-TR Mobile Instrumented Treadmill with Pressure Measurement
Mobile treadmills for pressure measurement and dynamic running training – enabling fast analyses and reliable evaluations.
RehaWalk® treadmill system
RehaWalk® treadmill system
RehaWalk® provides precise gait analysis and training in neurology, orthopaedics, and geriatrics with integrated pressure measurement.
Gaitway 3D
Gaitway 3D
Precise 3D force-measurement treadmill for biomechanics, diagnostics, and rehabilitation applications. Speeds up to 40 km/h, ideal with Vicon motion capture and EMG.
Mobius End-to-End
Mobius End-to-End
The treadmill allows users to choose their own step width and prevents data loss caused by double support.
Mobius Side-by-Side
Mobius Side-by-Side
The AMTI Mobius Side-by-Side system enables biomechanical studies with humans and robots. The belts can be individually controlled for targeted perturbations.