Roger N. Rovekamp scite author profile

Bone density loss and muscle atrophy are among the National Aeronautics and Space Administration's (NASA) highest concerns for crew health in space. Countless hours are spent maintaining an exercise regimen aboard the International Space Station (ISS) to counteract the effect of zero-gravity. Looking toward the future, NASA researchers are developing new compact and innovative exercise technologies to maintain crew health as missions increase in length and take humans further out into the solar system. The X1 Exoskeleton, initially designed for assisted mobility on Earth, was quickly theorized to have far-reaching potential as both an in-space countermeasures device and a dynamometry device to measure muscle strength. This lower-extremity device has the ability to assist or resist human movement through the use of actuators positioned at the hips and knees. Multiple points of adjustment allow for a wide range of users, all the while maintaining correct joint alignment. This paper discusses how the X1 Exoskeleton may fit NASA's onorbit countermeasures needs.

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Centaur: NASA's Mobile Humanoid Designed for Field Work

Mehling

Strawser

Bridgwater

et al. 2007

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An integrated neuro-robotic interface for stroke rehabilitation using the NASA X1 powered lower limb exoskeleton

Nathan

Venkatakrishnan

et al. 2014

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Stroke remains a leading cause of disability, limiting independent ambulation in survivors, and consequently affecting quality of life (QOL). Recent technological advances in neural interfacing with robotic rehabilitation devices are promising in the context of gait rehabilitation. Here, the X1, NASA's powered robotic lower limb exoskeleton, is introduced as a potential diagnostic, assistive, and therapeutic tool for stroke rehabilitation. Additionally, the feasibility of decoding lower limb joint kinematics and kinetics during walking with the X1 from scalp electroencephalographic (EEG) signals -the first step towards the development of a brain-machine interface (BMI) system to the X1 exoskeleton -is demonstrated.978-1-4244-7929-0/14/$26.00 ©2014 IEEE

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Roger N. Rovekamp

Structural parameters and dynamic loading identification from incomplete measurements: Approach and validation

X1: A Robotic Exoskeleton for In-Space Countermeasures and Dynamometry

Centaur: NASA's Mobile Humanoid Designed for Field Work

An integrated neuro-robotic interface for stroke rehabilitation using the NASA X1 powered lower limb exoskeleton

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