Wearable assistive robotics have the potential to address an unmet medical need of reducing disability in individuals with chronic hand impairments due to neurological trauma. Despite myriad prior works, few patients have seen the benefits of such devices. Following application experience with tendon-actuated soft robotic gloves and a collaborator's orthosis with novel flat-spring actuators, we identified two common assumptions regarding hand orthosis design. The first was reliance on incomplete studies of grasping forces during activities of daily living as a basis for design criteria, leading to poor optimization. The second was a neglect of increases in muscle tone following neurological trauma, rendering most devices non-applicable to a large subset of the population. To address these gaps, we measured joint torques during activities of daily living with able-bodied subjects using dexterity representative of orthosis-aided motion. Next, we measured assistive torques needed to extend the fingers of individuals with increased flexor tone following TBI. Finally, we applied this knowledge to design a cable actuated orthosis for assisting finger extension, providing a basis for future work focused on an under-represented subgroup of patients.

Creator

• Nycz, Christopher Julius

Contributors

• Fischer, Gregory S.
• Troy, Karen
• Li, Zhi
• Fichera, Loris

Degree

• PhD

Unit

• Robotics Engineering

Publisher

• Worcester Polytechnic Institute

Language

• English

Identifier

• etd-081018-104916

Keyword

• orthoses
• medical robotics
• stroke
• wearable robtoics
• traumatic brain injury
• hand biomechanics
• assistive devices
• exoskeletons
• grasping

Advisor

• Fischer, Gregory S.

Committee

• Li, Zhi
• Fichera, Loris
• Troy, Karen L.

Defense date

• 2018-07-27

Year

• 2018

Date created

• 2018-08-10

Resource type

• Dissertation

Rights statement

• In Copyright