Author: Keshia

M Yamagami, KM Peters, I Milovanovic, I Kuang, Z Yang, N Lu, KM Steele (2018) “Assessment of Dry Epidermal Electrodes for Long-Term Electromyography Measurements.” Sensors

Keshia JournalArticle, Projects, Publications, UbiquitousRehabilitation
Sample sEMG signal from one subject’s FCU for (left) MVIC; (middle) dynamic and (right) functional tests indicate that there were no significant differences between the Delsys (lighter grey) and ESS electrodes (darker grey) based on raw sEMG amplitude, linear envelope amplitude, or power spectral density.

Journal article in Sensors:

In collaboration with University of Texas – Austin, we evaluated a new flexible, gold-based epidermal electrode for sensing muscle activity.

Sample sEMG signal from one subject’s FCU for (left) MVIC; (middle) dynamic and (right) functional tests indicate that there were no significant differences between the Delsys (lighter grey) and ESS electrodes (darker grey) based on raw sEMG amplitude, linear envelope amplitude, or power spectral density.Background: Commercially available electrodes can only provide quality surface electromyography (sEMG) measurements for a limited duration due to user discomfort and signal degradation, but in many applications, collecting sEMG data for a full day or longer is desirable to enhance clinical care. Few studies for long-term sEMG have assessed signal quality of electrodes using clinically relevant tests. The goal of this research was to evaluate flexible, gold-based epidermal sensor system (ESS) electrodes for long-term sEMG recordings.

Methods: We collected sEMG and impedance data from eight subjects from ESS and standard clinical electrodes on upper extremity muscles during maximum voluntary isometric contraction tests, dynamic range of motion tests, the Jebsen Taylor Hand Function Test, and the Box & Block Test. Four additional subjects were recruited to test the stability of ESS signals over four days.

Results: Signals from the ESS and traditional electrodes were strongly correlated across tasks. Measures of signal quality, such as signal-to-noise ratio and signal-to-motion ratio, were also similar for both electrodes.

Conclusions: Over the four-day trial, no significant decrease in signal quality was observed in the ESS electrodes, suggesting that thin, flexible electrodes may provide a robust tool that does not inhibit movement or irritate the skin for long-term measurements of muscle activity in rehabilitation and other applications.

Go-Baby-Go project is named an awardee for the Mobility Unlimited Challenge Discovery Award!

Keshia Awards, Media, News

Toyota Mobility is sponsoring ten teams who aim to break into the assistive technology market with $50,000 of seed funding.

The Mobility Unlimited Challenge attracted nearly 100 applications worldwide, and we are proud to announce our joint team was selected!

Our team here at the University of Washington, together with Oregon State University, submitted a joint application. Highlights are included below. To learn more about Toyota’s Challenge or the other nine fellow awardees, click here.

TITLE: Enabling Independent Mobility and Social Play for Young Children with Mobility Impairments

CHALLENGE: There is a demonstrated lack of commercially-available pediatric mobility devices that promote early mobility and socialization in 1-3 year-old children with mobility impairments. The team proposes an intelligent powered mobility device that enables independent mobility and encourages social interaction and play among young children of different abilities. The device will employ artificial intelligence to ensure safety, while satisfying four key requirements of being (1) low-cost, (2) durable, (3) adaptable/customizable, and (4) aesthetically and functionally desirable by children with all abilities.

Karley Benoff named in the Husky 100!

Keshia Awards, Media, News, Orthoses, Projects , ,

We are honored to have a 2018 Husky 100 member in our lab! The Husky 100 recognizes 100 UW undergraduate and graduate students from Bothell, Seattle, and Tacoma in all areas of study who are making the most of their time at the UW. Read an excerpt of Karley’s application packet below to learn more about her involvement with HuskyADAPT, her research with orthotic design, outreach, and her studies. Congratulations, Karley!

Students lead toy hack at Expanding Your Horizons Conference

Keshia HuskyADAPT, News, Outreach, Projects

Expanding Your Horizons (EYH website) is a non-profit organization dedicated to providing gateway opportunities for female middle and high school students to become more involved in STEM activities and careers. Two of our Steele Lab teams participated. Michael Rosenberg and Momona Yamagami created a remote control car you can control using muscle activity, and engaged in hands-on learning with the young women. Members of the University of Washington’s HuskyADAPT (Accessible Design & Play Technology) team, including lab members Brianna Goodwin, Brandon Nguyen, and Karley Benoff, led a workshop yesterday on accessible design and adaptation of toys for children with varying abilities.

A total of 12 toys were adapted to incorporate a new switch mechanism to facilitate play, and 26 high school women learned about toy adaptation, soldering, and circuitry. Thank you to our HuskyADAPT team and our lab members for their dedication to outreach events!