Your search keyword '"Grindle, GG"' showing total 45 results

1. Stability analysis of electrical powered wheelchair-mounted robotic-assisted transfer device

Author

Wang, H, Tsai, CY, Jeannis, H, Chung, CS, Kelleher, A, Grindle, GG, Cooper, RA, Wang, H, Tsai, CY, Jeannis, H, Chung, CS, Kelleher, A, Grindle, GG, and Cooper, RA

Abstract

The ability of people with disabilities to live in their homes and communities with maximal independence often hinges, at least in part, on their ability to transfer or be transferred by an assistant. Because of limited resources and the expense of personal care, robotic transfer assistance devices will likely be in great demand. An easy-to-use system for assisting with transfers, attachable to electrical powered wheelchairs (EPWs) and readily transportable, could have a significant positive effect on the quality of life of people with disabilities. We investigated the stability of our newly developed Strong Arm, which is attached and integrated with an EPW to assist with transfers. The stability of the system was analyzed and verified by experiments applying different loads and using different system configurations. The model predicted the distributions of the system’s center of mass very well compared with the experimental results. When real transfers were conducted with 50 and 75 kg loads and an 83.25 kg dummy, the current Strong Arm could transfer all weights safely without tip-over. Our modeling accurately predicts the stability of the system and is suitable for developing better control algorithms to enhance the safety of the device.

Published

2014

2. The Personal Mobility and Manipulation Appliance (PerMMA): a robotic wheelchair with advanced mobility and manipulation.

Author

Wang, H, Grindle, GG, Candiotti, J, Chung, C, Shino, M, Houston, E, Cooper, RA, Wang, H, Grindle, GG, Candiotti, J, Chung, C, Shino, M, Houston, E, and Cooper, RA

Abstract

The Personal Mobility and Manipulation Appliance (PerMMA) is a recently developed personal assistance robot developed to provide people with disabilities and older adults enhanced assistance in both mobility and manipulation, which are two fundamental components for independently activities of daily life performing, community participation, and quality of life. Technologies to assist with mobility and manipulation are among the most important tools for clinicians, end users and caregivers; however, there are currently few systems that provide practical and coordinated assistance with mobility and manipulation tasks. The PerMMA was not only developed and evaluated to provide users and caregivers enhanced mobility and manipulation options, but also as a clinical tool as well as research platform. The development and evaluation of PerMMA are presented in the paper.

Published

2012

3. Personal mobility and manipulation appliancedesign, development, and initial testing

Author

Cooper, RA, Grindle, GG, Vazquez, JJ, Xu, J, Wang, H, Candiotti, J, Chung, C, Salatin, B, Houston, E, Kelleher, A, Teodorski, E, Beach, S, Cooper, RA, Grindle, GG, Vazquez, JJ, Xu, J, Wang, H, Candiotti, J, Chung, C, Salatin, B, Houston, E, Kelleher, A, Teodorski, E, and Beach, S

Abstract

The ability to perform activities of daily living and mobility-related activities of daily living are substantial indicators of one's ability to live at home and to participate in one's community. Technologies to assist with mobility and manipulation are among the most important tools that clinicians can provide to people with disabilities to promote independence and community participation. For people with severe disabilities involving both the upper and lower extremities, there are few systems that provide practical and coordinated assistance with mobility and manipulation tasks. The personal mobility and manipulation appliance (PerMMA) was created in response to goals set forth by a team of clinicians and people with disabilities. © 2012 IEEE.

Published

2012

4. Design and development of the personal mobility and manipulation appliance

Author

Grindle, GG, Wang, H, Salatin, BA, Vazquez, JJ, Cooper, RA, Grindle, GG, Wang, H, Salatin, BA, Vazquez, JJ, and Cooper, RA

Abstract

For people with significant mobility impairments who also have both lower and upper limb disability, there are few technology solutions. The aim of this article is to describe the design and development of the Personal Mobility and Manipulation Appliance, a device that provides coordinated mobility and bimanual manipulation for people with both lower and upper limb impairment. The Personal Mobility and Manipulation Appliance is integrated from several commercial products and custom technologies, including two robotic arms mounted on a mobile robotic base. It has three primary operating modes: local user, remote user, and autonomous. It also has a cooperative control mode where two or more of the primary modes can be used simultaneously. The device was evaluated in a kitchen and was able to perform several complex tasks. Future work should focus on interface improvements and evaluations by end users. © 2011 RESNA.

Published

2011

5. The role of assistive robotics in the lives of persons with disability

Author

Brose, SW, Weber, DJ, Salatin, BA, Grindle, GG, Wang, H, Vazquez, JJ, Cooper, RA, Brose, SW, Weber, DJ, Salatin, BA, Grindle, GG, Wang, H, Vazquez, JJ, and Cooper, RA

Abstract

Brose SW, Weber DJ, Salatin BA, Grindle GG, Wang H, Vazquez JJ, Cooper RA: The role of assistive robotics in the lives of persons with disability.Robotic assistive devices are used increasingly to improve the independence and quality of life of persons with disabilities. Devices as varied as robotic feeders, smart-powered wheelchairs, independent mobile robots, and socially assistive robots are becoming more clinically relevant. There is a growing importance for the rehabilitation professional to be aware of available systems and ongoing research efforts. The aim of this article is to describe the advances in assistive robotics that are relevant to professionals serving persons with disabilities. This review breaks down relevant advances into categories of Assistive Robotic Systems, User Interfaces and Control Systems, Sensory and Feedback Systems, and User Perspectives. An understanding of the direction that assistive robotics is taking is important for the clinician and researcher alike; this review is intended to address this need. Copyright © 2010 by Lippincott Williams and Wilkins.

Published

2010

6. Quantification of activity during wheelchair basketball and rugby at the National Veterans Wheelchair Games: A pilot study

Author

Sporner, ML, Grindle, GG, Kelleher, A, Teodorski, EE, Cooper, R, Cooper, RA, Sporner, ML, Grindle, GG, Kelleher, A, Teodorski, EE, Cooper, R, and Cooper, RA

Abstract

To date, no published data exists on distances and speeds traveled by rugby or basketball players during game play. The purpose of this study was to provide quantitative information of selected characteristics of wheelchair basketball and rugby game play. A miniaturized data logger was used to collect the distance traveled, average velocity, activity time, and number of starts and stops during basketball and rugby games. Participants were recruited prior to wheelchair basketball and rugby tournaments during the 2007 and 2008 National Veterans Wheelchair Games. Inclusion criteria were age 18 years or older and been participating in wheelchair basketball or rugby. The wheelchair rugby athletes on average traveled 2364.78±956.35 meters at 1.33±0.25 m/sec with 242.61±80.31 stops and starts in 29.98±11.79min of play per game. The wheelchair basketball athletes on average traveled 2679.52±1103.66m at 1.48±0.13 m/sec with 239.78±60.61 stops and starts in 30.28±9.59min of play per game. Previous research has not reported basketball or rugby game play variables such as these, making this data set unique. The information could be used by players and coaches to create training protocols to better prepare for game conditions. © 2009 ISPO.

Published

2009

7. Real-time model based electrical powered wheelchair control

Author

Wang, H, Salatin, B, Grindle, GG, Ding, D, Cooper, RA, Wang, H, Salatin, B, Grindle, GG, Ding, D, and Cooper, RA

Abstract

The purpose of this study was to evaluate the effects of three different control methods on driving speed variation and wheel slip of an electric-powered wheelchair (EPW). A kinematic model as well as 3D dynamic model was developed to control the velocity and traction of the wheelchair. A smart wheelchair platform was designed and built with a computerized controller and encoders to record wheel speeds and to detect the slip. A model based, a proportional-integral-derivative (PID) and an open-loop controller were applied with the EPW driving on four different surfaces at three specified speeds. The speed errors, variation, rise time, settling time and slip coefficient were calculated and compared for a speed step-response input. Experimental results showed that model based control performed best on all surfaces across the speeds.

Published

2009

8. An experimental method for measuring the moment of inertia of an electric power wheelchair.

Author

Wang, H, Grindle, GG, Connor, S, Cooper, RA, Wang, H, Grindle, GG, Connor, S, and Cooper, RA

Abstract

This study describe an experiment measuring the moment of inertia of an electric powered wheelchair (EPW) using a torsional pendulum method. Inertia of the wheelchair is an important factor for control, which is a key issue in wheelchair driving. The experimental test platform consisted of a bottom circular wood plate, an upper metal plate, and four ropes. Materials with known moments of inertia such as the metal disk and cylinder were used to test the accuracy of the system. The EPW used in the experiment was Invacare G3 Torque SP Storm Series. The measured result of the moment inertia of the wheelchair was 5.2280 kg.m(2) and the errors of the system are less than 10% even when the object is only 25lbs. The results are consistent when compared with other approximate methods. In addition, the experimental method could be used to measure the moment of inertia of manual wheelchairs and other irregular objects.

Published

2007

9. Personal mobility and manipulation using robotics, artificial intelligence and advanced control

Author

Cooper, RA, Ding, D, Grindle, GG, Wang, H, Cooper, RA, Ding, D, Grindle, GG, and Wang, H

Abstract

Recent advancements of technologies, including computation, robotics, machine learning, communication, and miniaturization technologies, bring us closer to futuristic visions of compassionate intelligent devices. The missing element is a basic understanding of how to relate human functions (physiological, physical, and cognitive) to the design of intelligent devices and systems that aid and interact with people. Our stakeholder and clinician consultants identified a number of mobility barriers that have been intransigent to traditional approaches. The most important physical obstacles are stairs, steps, curbs, doorways (doors), rough/uneven surfaces, weather hazards (snow, ice), crowded/cluttered spaces, and confined spaces. Focus group participants suggested a number of ways to make interaction simpler, including natural language interfaces such as the ability to say "I want a drink", a library of high level commands (open a door, park the wheelchair, ...), and a touchscreen interface with images so the user could point and use other gestures. © 2007 IEEE.

Published

2007

10. Development and qualitative assessment of the GAMECycle exercise system

Author

Guo, S, Grindle, GG, Authier, EL, Cooper, RA, Fitzgerald, SG, Kelleher, A, Cooper, R, Guo, S, Grindle, GG, Authier, EL, Cooper, RA, Fitzgerald, SG, Kelleher, A, and Cooper, R

Abstract

Increased physical activity is important for reducing the risk of cardiovascular disease. However, among people with disabilities, inactivity is prevalent. In order to encourage exercise among members of this group, an exercise system combining arm ergometry with video gaming, called the GAME Cycle was previously developed. User input was received through an arm crank ergometer on a swivel, with the angular velocity of the ergometer resistance wheel controlling one axis and rotation of ergometer about the swivel controlling the other. The purpose of this study was to detail the algorithms used in this device and present novel features included in a second generation of the GAMECycle. The features include a wheel on base, a steering return mechanism, and wireless fire buttons. A focus group of clinicians (n = 8), wheelchair users (n = 8), and clinician wheelchair users (n = 2) was conducted to evaluate the features of the GAMECycle. The focus group suggested improvements to the steering mechanism and to reduce vibration in the system. However, the focus group enjoyed the GAMECycle and felt that it would encourage exercise among persons with disabilities. © 2006 IEEE.

Published

2006

11. Quantification of activity during wheelchair basketball and rugby at the National Veterans Wheelchair Games: A pilot study.

Author

Sporner ML, Grindle GG, Kelleher A, Teodorski EE, Cooper R, and Cooper RA

Published

2009

12. Evaluation of Electric and Air-Powered Shopping Scooters in Grocery Stores.

Author

Daveler BJ, Gebrosky B, Eckstein IJ, Grindle GG, Cooper R, and Cooper RA

Subjects

Humans, Male, Female, Adult, Middle Aged, Aged, Consumer Behavior, Commerce, Supermarkets, Young Adult, Electric Power Supplies

Abstract

Objective: The purpose of this study was to further previous research and gather additional information regarding the usage of motorized shopping scooters as well as feedback for improvements to an air-powered scooter., Methods: Online surveys were used to assess individuals' shopping characteristics and experience using the motorized scooters and to gather feedback from store employees regarding their experience. K-Means clustering analysis was used to determine user demographics who chose to use the air-powered scooter versus the electric-powered scooter while shopping., Results: A total of 127 individuals provided informed consent, 65 individuals from site 1 and 62 individuals from site 2. One hundred twenty participants met the inclusion criteria and completed the survey. K-Means clustering found that age, type of personal mobility device, shopping bill total, and frequency using a motorized shopping scooter to be significant factors in whether individuals chose to use an air-powered scooter or electric-powered scooter., Conclusions: Motorized shopping scooters are in high demand and used by a wide variety of individuals, yet electric-powered scooters are commonly unavailable because of having dead batteries or all the devices being in use. Air-powered scooters may serve as a practical replacement for the current electric-powered scooters found in grocery and retail stores., Competing Interests: Financial disclosure statements have been obtained, and no conflicts of interest have been reported by the authors or by any individuals in control of the content of this article., (Copyright © 2024 Wolters Kluwer Health, Inc. All rights reserved.)

Published

2024

13. Current State, Needs, and Opportunities for Wearable Robots in Military Medical Rehabilitation and Force Protection.

Author

Cooper RA, Smolinski G, Candiotti JL, Satpute S, Grindle GG, Sparling TL, Nordstrom MJ, Yuan X, Symsack A, Dae Lee C, Vitiello N, Knezevic S, Sugar TG, Schneider U, Kopp V, Holl M, Gaunaurd I, Gailey R, Bonato P, Poropatich R, Adet DJ, Clemente F, Abbas J, and Pasquina PF

Abstract

Despite advances in wearable robots across various fields, there is no consensus definition or design framework for the application of this technology in rehabilitation or musculoskeletal (MSK) injury prevention. This paper aims to define wearable robots and explore their applications and challenges for military rehabilitation and force protection for MSK injury prevention. We conducted a modified Delphi method, including a steering group and 14 panelists with 10+ years of expertise in wearable robots. Panelists presented current wearable robots currently in use or in development for rehabilitation or assistance use in the military workforce and healthcare. The steering group and panelists met to obtain a consensus on the wearable robot definition applicable for rehabilitation or primary injury prevention. Panelists unanimously agreed that wearable robots can be grouped into three main applications, as follows: (1) primary and secondary MSK injury prevention, (2) enhancement of military activities and tasks, and (3) rehabilitation and reintegration. Each application was presented within the context of its target population and state-of-the-art technology currently in use or under development. Capturing expert opinions, this study defines wearable robots for military rehabilitation and MSK injury prevention, identifies health outcomes and assessment tools, and outlines design requirements for future advancements., Competing Interests: Conflicts of Interest: The opinions and assertions expressed herein are those of the author(s) and do not reflect the official policy or position of the Uniformed Services University of the Health Sciences, the Department of Defense, the views of the Department of Veterans Affairs, or the United States Government. Nicola Vitiello has commercial interests in IUVO S.r.l., a spin-off company of Scuola Superiore Sant’Anna; IUVO is the exclusive licensee of the APO technology. The rest of the authors claim no conflicts of interest. Neither the authors, except for Nicola Vitiello, nor their family members have a financial interest in any commercial product, service, or organization providing financial support for this research.

Published

2024

14. Participatory action design and engineering of a manual wheelchair virtual coach including in-home and community usage.

Author

Sundaram SA, Chung CS, Gebrosky B, Brown J, Grindle GG, Deepak N, Cooper R, and Cooper RA

Subjects

Female, Humans, Male, Spinal Cord Injuries, Wheelchairs

Abstract

Background: Current clinical practice guidelines (CPG) recommend periodic pressure redistribution (PR) to alter sitting pressure and reduce the risk of developing pressure injuries (PI). Individuals who have strength and trunk stability are asked to perform PR such as wheelies, leaning laterally, and forward-leaning to minimize the duration of pressure acting on the same region of the body., Objective: Our long-term objective is to build upon previous research and development to create a more effective device for improving PR training and adherence to CPG among manual wheelchair users (MWU). Through this study, we employed a participatory action design and engineering (PADE) approach in developing the hardware and user interface to increase the likelihood of eventually yielding a device effective for both MWU and clinicians., Participants: Focus Groups : Ten clinicians - 6 physical therapists, 3 occupational therapists, and one registered nurse, and 10 MWU with spinal cord injuries (SCI) who reported using their wheelchairs 40-80 h per week. Five-Day Assessment : Five male MWU with SCI who had been wheelchair users for 18.5 ± 16.2 years. Four-Week Investigation : The 7 participants with SCI were 5 males and 2 females, who had been wheelchair users for 24.7 ± 17.0 years., Methods: A PADE approach was used to improve upon a manual wheelchair virtual coaching system for people with SCI. The system comprises a seat support instrumented with force sensors, software algorithms to detect PR, and a smart phone app for user interface. The methods included three stages: multiple focus groups, a five-day evaluation phase with participants using their own wheelchairs in their homes and communities, and a 4-week assessment with improvements made based on the 5-day results by users with their own wheelchairs in their homes and communities., Results: The focus groups yielded guidance for ergonomics, user interface, charging frequency, and key dimensions and mass. The 5-day study identified mechanical, electrical, and connectivity challenges, which were resolved before the 4-week study. The 4-week trial suggested that participants performed PR less frequently than clinically recommended and provided an indication of the types of maneuvers that they performed., Conclusion: A prototype manual wheelchair virtual coaching system was developed using a PADE process. The system was able to detect and record PR in home and community environments. Following improvements identified in this study, a future version will be tested with additional users to determine whether it can improve adherence to PR guidance.

Published

2023

15. Participatory Action Design and Engineering of Powered Personal Transfer System for Wheelchair Users: Initial Design and Assessment.

Author

Satpute SA, Candiotti JL, Duvall JA, Kulich H, Cooper R, Grindle GG, Gebrosky B, Brown J, Eckstein I, Sivakanthan S, Deepak N, Kanode J, and Cooper RA

Subjects

Aged, United States, Humans, Equipment Design, Medicare, Disabled Persons, Self-Help Devices, Wheelchairs

Abstract

Caregivers that assist with wheelchair transfers are susceptible to back pain and occupational injuries. The study describes a prototype of the powered personal transfer system (PPTS) consisting of a novel powered hospital bed and a customized Medicare Group 2 electric powered wheelchair (EPW) working together to provide a no-lift solution for transfers. The study follows a participatory action design and engineering (PADE) process and describes the design, kinematics, and control system of the PPTS and end-users' perception to provide qualitative guidance and feedback about the PPTS. Thirty-six participants (wheelchair users (n = 18) and caregivers (n = 18)) included in the focus groups reported an overall positive impression of the system. Caregivers reported that the PPTS would reduce the risk of injuries and make transfers easier. Feedback revealed limitations and unmet needs of mobility device users, including a lack of power seat functions in the Group-2 wheelchair, a need for no-caregiver assistance/capability for independent transfers, and a need for a more ergonomic touchscreen. These limitations may be mitigated with design modifications in future prototypes. The PPTS is a promising robotic transfer system that may aid in the higher independence of powered wheelchair users and provide a safer solution for transfers.

Published

2023

16. Usability and Vibration Analysis of a Low-Profile Automatic Powered Wheelchair to Motor Vehicle Docking System.

Author

Lee CD, Daveler BJ, Candiotti JL, Cooper R, Sivakanthan S, Deepak N, Grindle GG, and Cooper RA

Abstract

The QLX is a low-profile automatic powered wheelchair docking system (WDS) prototype developed to improve the securement and discomfort of wheelchair users when riding in vehicles. The study evaluates the whole-body vibration effects between the proposed QLX and another WDS (4-point tiedown system) following ISO 2631-1 standards and a systematic usability evaluation. Whole-body vibration analysis was evaluated in wheelchairs using both WDS to dock in a vehicle while riding on real-world surfaces. Also, participants rated the usability of each WDS while driving a wheelchair and while riding in a vehicle in driving tasks. Both WDSs showed similar vibration results within the vibration health-risk margins; but shock values below health-risk margins. Fifteen powered wheelchair users reported low task load demand to operate both WDS; but better performance to dock in vehicles with the QLX ( p = 0.03). Also, the QLX showed better usability ( p < 0.01), less discomfort ( p' s < 0.05), and greater security compared to the 4-point tiedown while riding in a vehicle ( p' s < 0.05). Study findings indicate that both WDS maintain low shock exposure for wheelchair users while riding vehicles, but a better performance overall to operate the QLX compared to the 4-point tiedown system; hence enhancing user's autonomy to dock in vehicles independently., Competing Interests: Conflicts of Interest: The authors declare no conflict of interest.

Published

2023

17. Anthropomorphic model rigid loading indenter with embedded sensor development for wheelchair cushion standard testing.

Author

Chung CS, Grindle GG, Brown JD, Gebrosky B, Carrigan W, Nuthi P, Wijesundara MBJ, and Cooper RA

Subjects

Humans, Equipment Design, Pressure, Femur, Pressure Ulcer, Wheelchairs

Abstract

Develop an anthropomorphic model cushion rigid loading indenter with embedded sensors (AMCRLI-ES) to assess compression and shear forces at key locations such as trochanters and ischial tuberosities. The sensor design was optimized using finite element analysis. The AMCRLI-ES was designed with the same dimensions as specified in ISO 16840-2 tests. The AMCRLI-ES is divided into eight independent sections, and each section consists of one 3-axis load cell sensor to measure compression and shear forces normal to the compression direction. Six commercial cushions were tested using the AMCRLI-ES with standard ISO 16840-2 testing procedures. Statistical differences were found for energy dissipation between cushions. Statistical differences (p < 0.001) were found in all stiffness values. Test results showed that energy dissipation (ED) was correlated with hysteresis at 500 N with moderate to high Pearson product correlation r = -0.537, p = 0.022. The hysteresis at 250 N did not show a statistical correlation with ED. The AMCRLI-ES demonstrated the ability to measure compression and shear forces at key locations on the cushion including the thigh, trochanter, ischial tuberosity, and sacral area. It provides in-depth information about how the weight was distributed on the cushions., (© 2022. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2023

18. Comparison of trunk mechanics and spatiotemporal outcomes in caregivers using a robotic assisted transfer device and a mobile floor lift.

Author

Greenhalgh M, Blaauw ER, Crytzer T, Deepak N, Grindle GG, Koontz AM, and Cooper RA

Subjects

Humans, Caregivers, Cross-Sectional Studies, Pelvis, Biomechanical Phenomena, Robotic Surgical Procedures, Spinal Cord Injuries

Abstract

Objective: The purpose of this study was to compare trunk mechanics, distance covered, and average instantaneous velocity and acceleration recorded with caregivers performing transfer tasks using a research mannequin with both a prototype robotic assisted transfer device (RATD) and a mobile floor lift., Design: Cross-Sectional., Setting: Biomechanics Lab and Human Engineering Research Laboratories., Participants: Caregivers ( N  = 21)., Intervention: Robotic Assisted Transfer Device., Outcome Measures: Range of flexion-extension, lateral bend, and axial rotation; distance covered; average instantaneous velocity and acceleration., Results: Caregivers performing transfers using the RATD as compared to when using the moble floor lift reported significantly smaller range of trunk flexion-extension, lateral bending, and axial rotation, and reported lower pelvic based distance covered and slower average instantaneous velocity and acceleration (P < 0.001)., Conclusion: The design and usability of a RATD indicates design driven mobility advantages over clinical standard mobile floor lifts due to its ability to expand the workspace while further reducing risk factors for low back pain. While the concept is promising, further testing is required to address limitations and confirm the concept for clinical applications.

Published

2023

19. Clinical and Ergonomic Comparison Between a Robotic Assisted Transfer Device and a Mobile Floor Lift During Caregiver-Assisted Wheelchair Transfers.

Author

Greenhalgh M, Blaauw E, Deepak N, St Laurent M, Cooper R, Bendixen R, Grindle GG, Koontz AM, and Cooper RA

Subjects

Caregivers, Electromyography, Ergonomics, Humans, Muscle, Skeletal physiology, Robotic Surgical Procedures, Wheelchairs

Abstract

Background: The robotic assisted transfer device was developed as an updated lift technology to reduce adjustments in posture while increasing capabilities offered by transfer devices. The purpose of this study was to compare the trunk biomechanics of a robotic assisted transfer device and a mechanical floor lift in the transfer of a care recipient by a caregiver during essential transfer tasks., Methods: Investigators enrolled 28 caregiver/care recipient dyads to complete 36 transferring tasks. Surface electromyography for the back muscles and motion data for trunk range of motion were collected for selected surfaces, phase, and direction tasks using a robotic assisted transfer device and a mechanical floor lift., Results: Robotic assisted transfer device transfers required significantly smaller range of trunk flexion (P < 0.001), lateral bend (P < 0.001), and axial rotation (P = 0.01), in addition to smaller distance covered (P < 0.001), average instantaneous velocity (P = 0.01), and acceleration (P < 0.001) compared with a mobile floor lift. The robotic assisted transfer device transfers required significantly smaller peak erector spinae (left: P = 0.001; right: P < 0.001) and latissimus dorsi (right: P < 0.001) and integrated erector spinae left (P = 0.001) and latissimus dorsi right (P = 0.01) electromyography signals compared with the floor lift., Conclusions: The robotic assisted transfer device provides additional benefits to mobile floor lifts which, coupled with statistically lower flexion, extension, and rotation, may make them an appealing alternative intervention., Competing Interests: Financial disclosure statements have been obtained, and no conflicts of interest have been reported by the authors or by any individuals in control of the content of this article., (Copyright © 2021 Wolters Kluwer Health, Inc. All rights reserved.)

Published

2022

20. Air-powered shopping carts in grocery stores: a pilot study.

Author

Daveler B, Gebrosky B, Eckstein I, Cooper R, Grindle GG, and Cooper RA

Subjects

Humans, Middle Aged, Pilot Projects, Reproducibility of Results, Supermarkets, Quality of Life, Self-Help Devices

Abstract

Purpose: Motorized shopping carts found at grocery and retail stores provide mobility for those who have difficulty walking through the store or pushing a regular cart. The purpose of this study was to understand the usage of motorized carts in grocery stores and pilot test an air-powered cart to determine its feasibility as a replacement for electric-powered carts as well as identify areas for improvement and preferred users., Methods: Users were asked to complete an online survey that assessed their shopping characteristics and experience using the motorized cart. K-Means clustering determined user demographics who chose to use the air-powered carts versus the electric-powered carts. Open-ended comments for improvements were also collected., Results: A total of 65 participants were provided informed consent, 60 participants met inclusion criteria and completed the survey. A majority of the air-powered ( N  = 29, 91%) and electric-powered ( N  = 11, 73%) cart users had a positive experience. Clustering found age and type of mobility device owned were significant whether participants chose the air-powered or electric-powered carts. Most suggested improvements for the air-powered carts were better braking, higher speed and a bigger basket while a longer battery life was most suggested for electric-powered carts., Conclusions: Motorized shopping carts are used by a wide variety of individuals. Individuals aged 54 or younger and do not own a mobility device chose to use air-powered more than electric-powered carts. The functional capabilities of the air-powered carts demonstrated their potential to serve as practical replacements for electric-powered carts found in grocery and retail stores.Implications for rehabilitationThe availability and reliability of motorized shopping carts at retail stores are integral for individuals with physical impairments to complete their shopping needs.The development of novel assistive devices such as air-powered carts provides improved experiences and quality of life.Integrating end-user feedback during the design of assistive technologies is paramount for meeting actual needs.

Published

2022

21. Comparing the performance of ultralight folding manual wheelchairs using standardized tests.

Author

Gebrosky B, Bridge A, O'Donnell S, Grindle GG, Cooper R, and Cooper RA

Subjects

Cost-Benefit Analysis, Equipment Design, Equipment Failure Analysis, Humans, Quality of Life, Wheelchairs

Abstract

Objective: To evaluate ultralight folding manual wheelchairs (UFMWs) in order to produce comparative data on their strength, durability, stability and cost-benefit, and to determine progress of wheelchairs by comparing these results to results of past studies., Design: Engineering testing using American National Standards Institute (ANSI) and Rehabilitation Engineering and Assistive Technology Society of North America (RESNA) standards., Setting: Laboratory testing of UFMW stability, and static, impact and fatigue strength performance with three devices using ANSI/RESNA standardized tests., Participants: The three wheelchair models were the TiLite Aero X (Permobil, Lebanon, TN), Sunrise Medical Quickie 2 (Fresno, CA) and Ki Mobility Catalyst 5 (Stevens Point, WI)., Interventions: ANSI/RESNA standardized tests., Main Outcome Measures: Mass and critical measurements, static stability, static strength, impact strength, fatigue strength and cost analysis., Results: The ultralight folding wheelchairs continued to outperform their lightweight and rigid framed counterparts. According to these data, the quality of ultralight wheelchairs has not declined over the past 10 years. The Ki Catalyst did not pass strength and durability testing, while the TiLite Aero X and Sunrise Medical Quickie 2 surpassed these tests., Conclusions: This result exemplifies the need for ongoing research to identify whether wheelchairs satisfy ANSI/RESNA testing requirements and highlights the importance of creating a resource data set. This is particularly important when numerous other wheelchairs fail to meet minimum ANSI/RESNA requirements.Implications for RehabilitationFolding frame wheelchairs offer benefits such as transportability and convenience that may benefit certain wheelchair users, assuming their durability is sufficient and they provide similar benefits vs. other wheelchair construction.Previous studies have shown that folding wheelchairs perform meet the minimum requirements of standardized testing, and it is important to see if durability has increased, decreased or remained the same over the years. Other wheelchair types have remained stagnant with respect to durability and are less likely to meet the minimum durability requirements.Durable devices will improve a wheelchair user's quality of life by reducing downtime while waiting for repairs, and also reduce the likelihood of injury due to component failure.

Published

2022

22. Curb Negotiation With Dynamic Human-Robotic Wheelchair Collaboration.

Author

Candiotti JL, Daveler BJ, Sivakanthan S, Grindle GG, Cooper R, and Cooper RA

Abstract

Wheelchair users often face architectural barriers such as curbs, limiting their accessibility, mobility, and participation in their communities. The mobility enhancement robotic (MEBot) wheelchair was developed to navigate over such architectural barriers. Its application allows wheelchair users to negotiate curbs automatically while the user remains in control. The application was optimized from a manual to a semiautomated process based on wheelchair users' feedback. The optimized application was evaluated by experienced wheelchair users who navigated over curbs of different heights. Participants evaluated MEBot in terms of effectiveness, workload demand, and usability. Ten participants successfully ascended and descended curbs of different heights at an average completion time of 55.7 ± 19.5 and 30.3 ± 9.1 s, respectively. MEBot maintained stability during the process, while participants reported low levels of effort, frustration, and overall cognitive demand to operate MEBot. Furthermore, participants were satisfied with the ease of learning and using the MEBot curb negotiation application to overcome the curbs but suggested less wheel adjustment for comfort and a faster pace to overcome curbs during real-world conditions.

Published

2021

23. VA TECHNOLOGY TRANSFER PROGRAM RESPONDS TO COVID-19 PANDEMIC.

Author

Duvall J, Grindle GG, Kaplan J, Marks D, Sylvers L, Patel J, Lain M, Bagay A, Chung CS, and Cooper RA

Abstract

The COVID-19 pandemic stressed healthcare systems all over the world. Two primary challenges that healthcare systems faced were a shortage of personal protective equipment and the need for new technologies to handle infection prevention for staff and patients. The Department of Veteran's Affairs (VA) Technology Transfer Program responded by prioritizing the development of innovations in the Technology Transfer Assistance Project which addressed the pandemic. This paper describes several innovations that addressed the needs of the VA healthcare system during the pandemic and how they were rapidly developed.

Published

2021

24. Assessment of Muscle Activation of Caregivers Performing Dependent Transfers With a Novel Robotic-Assisted Transfer Device Compared With the Hoyer Advance.

Author

Blaauw ER, Greenhalgh M, Vegter R, Bass S, Kulich H, Grindle GG, Cooper R, Koontz AM, and Cooper RA

Subjects

Adolescent, Adult, Biomechanical Phenomena, Electromyography, Female, Humans, Male, Middle Aged, Young Adult, Caregivers, Equipment Design, Moving and Lifting Patients instrumentation, Muscle, Skeletal physiology, Occupational Health, Robotics

Abstract

Objective: The purpose of this study was to compare muscle activity in caregivers while using a novel robotic-assisted transfer device (Strong Arm) to a clinical standard of care (Hoyer Advance)., Design: A quasi-experimental design was used in which 20 caregivers (33 ± 15 yrs old) performed transfers with three surfaces (toilet, bench, and shower chair) with the Strong Arm and Hoyer Advance. Transfer completion time (seconds), peak percentage surface electromyography (EMG), and integrated EMG of the bilateral erector spinae, latissimus dorsi, pectoralis major and anterior deltoid were measured., Results: Caregivers required less transfer time when transferring from wheelchair to surface using the Hoyer Advance (P = 0.011, f = 0.39). For the lower back, significantly lower peak percentage EMGs were found using Strong Arm in 50% and for the integrated EMG in 25% of the cases, with the remaining cases showing no significant differences. For the shoulder, significantly lower peak percentage EMG values were found using Strong Arm in 19% of transfers and lower integrated EMG was found in 25% of transfers when using the Hoyer Advance, with the remaining cases showing no significant differences., Conclusion: Although back muscle activation during Strong Arm transfers is statistically, but not clinically, lower, additional features that couple with significantly lower muscle activation make it an alternative to the clinical standard for further research and possible clinical applicability., (Copyright © 2020 Wolters Kluwer Health, Inc. All rights reserved.)

Published

2021

25. TECHNOLOGY TRANSFER ASSISTANCE PROJECT BRINGS VA HEALTH CARE IDEAS TO LIFE.

Author

Duvall J, Grindle GG, Kaplan J, Lain M, and Cooper RA

Abstract

Clinicians and staff of the Department of Veterans Affairs Health Care System (VA), who provide services to veterans, have invented many devices and methods for improving veterans' lives. However, translating those inventions to the market has been a challenge due to limited collaboration between the clinical inventors and the scientists, researchers, and engineers who can produce the prototypes necessary for licensing the technology. The VA Technology Transfer Program office and the Human Engineering Research Laboratories, a research laboratory with experience with developing prototypes and licensing technology, jointly developed a program called the Technology Transfer Assistance Project (TTAP) to bridge the gap between clinical inventors and prototypes ready for licensing. This paper describes TTAP and provides examples of the first inventions that were developed or enhanced through TTAP.

Published

2021

26. Usability evaluation of attitude control for a robotic wheelchair for tip mitigation in outdoor environments.

Author

Sivakanthan S, Candiotti JL, Sundaram SA, Battles C, Daveler BJ, Chung CS, Grindle GG, Cooper R, Dicianno BE, and Cooper RA

Subjects

Electricity, Equipment Design, Humans, Robotic Surgical Procedures, Robotics, Wheelchairs

Abstract

Tips and falls are the most prominent causes of wheelchair accidents that occur when driving on uneven terrains and less accessible environments. The Mobility Enhancement Robotic Wheelchair (MEBot) was designed to improve the stability of Electric Powered Wheelchairs (EPW) when driving over these environments. MEBot offers six independently height-adjustable wheels to control attitude of its seat over uneven and angled terrains. Its attitude control application uses an inertial measurement unit to detect seat angles changes to adjust each wheel-height accordingly. MEBot was compared to commercial EPWs in terms of EPW performance (seat angle changes and response time) and participant perception (satisfaction and task-load demand) towards each device. Ten participants drove their own EPW and MEBot for five trials each through driving tasks that replicated outdoor environments. Results showed less change in the pitch angle when driving up and down a 10° slope using MEBot (5.6 ± 1.6°, 6.6 ± 0.5°) compared to the participants' own EPW (14.6 ± 2.6°, 12.1 ± 2.6°). However, MEBot required 7.8 ± 3.0 s to self-adjust to the minimum angle when driving over the tasks. Participants reported no difference in satisfaction and task load demand between EPWs due to similarities in comfort and ease-of-use. Improving the speed and efficiency of MEBot's attitude control application will be addressed in future work based upon participants' feedback., Competing Interests: Declaration of Competing Interest None, (Copyright © 2020. Published by Elsevier Ltd.)

Published

2020

27. A Heuristic Approach to Overcome Architectural Barriers Using a Robotic Wheelchair.

Author

Candiotti JL, Daveler BJ, Kamaraj DC, Chung CS, Cooper R, Grindle GG, and Cooper RA

Subjects

Adult, Aged, Algorithms, Equipment Design, Female, Humans, Male, Middle Aged, Software, Architectural Accessibility, Heuristics, Robotics methods, Wheelchairs

Abstract

The Mobility Enhancement roBotic (MEBot) wheelchair was developed to improve the safety and accessibility of wheelchair users when facing architectural barriers. MEBot uses pneumatic actuators attached to its frame and six wheels to provide curb ascending/descending for heights up to 20.3 cm. To improve MEBot's application, this study used a heuristic approach with power wheelchair users to evaluate and improve the MEBot application at different curb heights. Wheelchair users were trained on MEBot's features to operate its curb ascending/descending application. Three trials were carried out with wheelchair users ascending and descending three curbs of different height. Quantitative variables were analyzed to improve the sequential steps to ascend/descend curbs. Additionally, the application's effectiveness and efficiency were measured by the number of completed tasks, change in seat angle, and task completion time. Results showed that participants completed each trial and applied alternative strategies to traverse different curb heights. Furthermore, results suggested the combination and/or re-arrangement of steps to reduce task completion time. MEBot demonstrated its effectiveness to ascend/descend different curb heights with a heterogeneous participant sample. Future work will incorporate participant's most efficient strategies to improve the ascending/ascending process and the efficiency of the MEBot application.

Published

2019

28. Assessment of Usability and Task Load Demand Using a Robot-Assisted Transfer Device Compared With a Hoyer Advance for Dependent Wheelchair Transfers.

Author

Greenhalgh M, Landis JM, Brown J, Kulich H, Bass S, Alqahtani S, Deepak N, Cryzter TM, Grindle GG, Koontz AM, and Cooper RA

Subjects

Adult, Caregivers, Cross-Sectional Studies, Equipment Design, Female, Humans, Male, Middle Aged, Weight-Bearing, Young Adult, Moving and Lifting Patients instrumentation, Robotics, Self-Help Devices, Wheelchairs

Abstract

Objective: Manual lifting can be burdensome for people who care for power wheelchair users. Although technologies used for dependent transfers are helpful, they have shortcomings of their own. This study compares the usability and task load demand of a novel robot-assisted transfer device to a clinical standard when performing dependent transfers., Design: A cross-sectional study was conducted to assess caregivers (N = 21) transferring a 56-kg mannequin with the Strong Arm and Hoyer Advance at three transfer locations. Feedback was gathered through qualitative surveys., Results: Usability was significant in multiple areas important for transfers. Caregiver fatigue and discomfort intensity were reduced, and the Strong Arm was preferred at the three transfer locations. Device ease and efficiency favored Strong Arm at two stations as was discomfort frequency. In addition, physical demand, frustration, and effort were significantly lower using Strong Arm compared with the Hoyer Advance., Conclusions: Compared with the Hoyer, participants favored Strong Arm for transfer usability and task load demand. However, further Strong Arm developments are needed.

Published

2019

29. Design and operation verification of an automated pressure mapping and modulating seat cushion for pressure ulcer prevention.

Author

Carrigan W, Nuthi P, Pande C, Wijesundara MBJ, Chung CS, Grindle GG, Brown JD, Gebrosky B, and Cooper RA

Subjects

Automation, Biomechanical Phenomena, Pressure Ulcer physiopathology, Weight-Bearing, Equipment Design, Pressure, Pressure Ulcer prevention & control

Abstract

A sensorized air cell-based seat cushion system was developed to address the issues of loading magnitude and duration at a sitting interface to aid in reducing risk of sitting acquired pressure ulcers. This system is capable of pressure mapping, redistribution, and offloading which were verified using an anthropomorphic model and a human subject. The system is comprised of an air cell array cushion, a pneumatic control unit, and a graphical user interface. ISO load deflection testing confirmed that the cushion's loading response is comparable to commercial air cell-based seat cushions. Testing demonstrated that the internal pressure of the air cells are indicative of interface pressure and can be used as input to pressure modulating algorithms. Uniform pressure distribution was achieved through automated pressure redistribution algorithm implementation where the immersion of a subject into the seat cushion increased and interface pressure decreased. High pressure point identification and automatic offloading were performed in which newly created high pressure points were addressed using subsequent redistribution. Pressure mapping enabled offloading and redistribution can objectively manage the effects of loading magnitude and duration at the sitting interface., (Copyright © 2019 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published

2019

30. Usability Evaluation of a Novel Robotic Power Wheelchair for Indoor and Outdoor Navigation.

Author

Candiotti JL, Kamaraj DC, Daveler B, Chung CS, Grindle GG, Cooper R, and Cooper RA

Subjects

Aged, Computer-Aided Design, Electric Power Supplies, Environment, Female, Humans, Male, Middle Aged, Spatial Navigation, Architectural Accessibility methods, Equipment Design methods, Robotics, Wheelchairs

Abstract

Objective: To compare the Mobility Enhancement roBotic (MEBot) wheelchair's capabilities with commercial electric-powered wheelchairs (EPWs) by performing a systematic usability evaluation., Design: Usability in effectiveness, efficacy, and satisfaction was evaluated using quantitative measures. A semistructured interview was employed to gather feedback about the users' interaction with MEBot., Setting: Laboratory testing of EPW driving performance with 2 devices in a controlled setting simulating common EPW driving tasks., Participants: A convenience sample of expert EPW users (N=12; 9 men, 3 women) with an average age of 54.7±10.9 years and 16.3± 8.1 years of EPW driving experience., Interventions: Not applicable., Main Outcome Measures: Powered mobility clinical driving assessment (PMCDA), Satisfaction Questionnaire, National Aeronautics and Space Administration's Task Load Index., Results: Participants were able to perform significantly higher number of tasks (P=.004), with significantly higher scores in both the adequacy-efficacy (P=.005) and the safety (P=.005) domains of the PMCDA while using MEBot over curbs and cross-slopes. However, participants reported significantly higher mental demand (P=.005) while using MEBot to navigate curbs and cross-slopes due to MEBot's complexity to perform its mobility applications which increased user's cognitive demands., Conclusions: Overall, this usability evaluation demonstrated that MEBot is a promising EPW device to use indoors and outdoors with architectural barriers such as curbs and cross-slopes. Current design limitations were highlighted with recommendations for further improvement., (Copyright © 2018 American Congress of Rehabilitation Medicine. Published by Elsevier Inc. All rights reserved.)

Published

2019

31. Accessible machining for people who use wheelchairs.

Author

Marino DJ, Rivera V, Joseph J, Williams R, Jeannis H, Goldberg M, Grindle GG, Kimmel J, and Cooper RA

Subjects

Adult, Disabled Persons rehabilitation, Equipment Design standards, Female, Health Services Accessibility standards, Humans, Male, Middle Aged, Wheelchairs trends, Disabled Persons psychology, Equipment Design methods, Ergonomics methods, Wheelchairs standards

Abstract

Despite the Americans with Disabilities Act mandate for reasonable accommodations, wheelchair users are often placed in the role of observer and note-taker when learning machining and fabrication skills due to a lack of accessibility. The focus of this case study report is to identify and develop reasonable accommodations for wheelchair users in an academic machine shop environment to address accessibility limitations of original equipment manufacturer (OEM) machines. Individual wheelchair users working and learning within the Human Engineering Research Laboratories (HERL) were observed and interviewed about their experiences using the machine shop equipment without modifications, followed by further observations after accommodations were implemented.

Published

2019

32. Integration of Pneumatic Technology in Powered Mobility Devices.

Author

Daveler B, Wang H, Gebrosky B, Grindle GG, Schneider U, and Cooper RA

Subjects

Humans, Electric Power Supplies, Equipment Design, Wheelchairs

Abstract

Advances in electric motors, electronics, and control systems have enhanced the capability and drivability of electric power mobility devices over the last 60 years. Yet, battery technologies used in powered mobility devices (PMDs) have not kept pace. Recent advances in pneumatic technology, primarily the high torque, low speed design of rotary piston air motors, directly align with the needs of PMD. Pneumatic technology has advantages over battery-powered technology, including lighter weight, lower operating costs, decreased environmental impact, better reliability, and increased safety. Two prototypes were created that incorporated rotary piston air motors, high-pressure air tanks, and air-pressure regulators. Prototype 1 was created by modifying an existing electric PMD. Range tests were performed to determine the feasibility of pneumatic technology and the optimal combination of components to allow the longest range possible at acceptable speeds over ideal conditions. Using a 1.44 L air tank for feasibility testing, prototype 1 was capable of traveling 800 m, which confirmed the feasibility of pneumatic technology usage in PMDs. Prototype 2 was designed based on the testing results from prototype 1. After further optimization of prototype 2, the average maximum range was 3,150 m. Prototype 2 is up to 28.3% lighter than an equivalent size electric PMD and can be fully recharged in approximately 2 minutes. It decreases the cost of PMDs by approximately $1,500, because batteries do not need to be replaced over the lifetime of the device. The results provide justification for the use of pneumatic technology in PMDs., Competing Interests: The authors report no conflicts of interest.

Published

2017

33. A Patient-Controlled Analgesia Adaptor to Mitigate Postsurgical Pain for Combat Casualties With Multiple Limb Amputation: A Case Series.

Author

Pasquina PF, Isaacson BM, Johnson E, Rhoades DS, Lindholm MP, Grindle GG, and Cooper RA

Subjects

Adult, Amputation, Surgical adverse effects, Equipment Design methods, Equipment Reuse standards, Humans, Male, Military Personnel, Analgesia, Patient-Controlled instrumentation, Pain Management methods, Self-Help Devices standards, Upper Extremity injuries

Abstract

The use of explosive armaments during Operation Iraqi Freedom, Operation Enduring Freedom, and Operation New Dawn has resulted in a significant number of injured U.S. service members. These weapons often generate substantial extremity trauma requiring multiple surgical procedures to preserve life, limb, and restore function. For those individuals who require multiple surgeries, the use of patient-controlled analgesia (PCA) devices can be an effective way to achieve adequate pain management and promote successful rehabilitation and recovery during inpatient treatment. A subpopulation of patients are unable to independently control a PCA device because of severe multiple limb dysfunction and/or loss. In response to the needs of these patients, our team designed and developed a custom adaptor to assist service members who would otherwise not be able to use a PCA. Patient feedback of the device indicated a positive response, improved independence, and overall satisfaction during inpatient hospitalization., (Reprint & Copyright © 2016 Association of Military Surgeons of the U.S.)

Published

2016

34. Design and evaluation of a seat orientation controller during uneven terrain driving.

Author

Candiotti J, Wang H, Chung CS, Kamaraj DC, Grindle GG, Shino M, and Cooper RA

Subjects

Equipment Design, Safety, Mechanical Phenomena, Motion, Wheelchairs

Abstract

Electric powered wheelchairs (EPWs) are essential devices for people with disabilities as aids for mobility and quality of life improvement. However, the design of currently available common EPWs is still limited and makes it challenging for the users to drive in both indoor and outdoor environments such as uneven surfaces, steep hills, or cross slopes, making EPWs susceptible to loss of stability and at risk for falls. An alternative wheel-legged robotic wheelchair, "MEBot", was designed to improve the safety and mobility of EPW users in both indoor and outdoor environments. MEBot is able to elevate its six wheels using pneumatic actuators, as well to detect changes in the seat angle using a gyroscope and accelerometer. This capability enables MEBot to provide sensing for a dynamic self-leveling seat application that can maintain the center of mass within the boundaries of the wheelchair, thereby, improving EPW safety. To verify the effectiveness of the application, MEBot was tested on a motion platform with six degrees of freedom to simulate different slopes that could be experienced by the EPW in outdoor environments. The results demonstrate the robustness of the application to maintain the wheelchair seat in a horizontal reference against changes in the ground angle., (Published by Elsevier Ltd.)

Published

2016

35. Participatory design and validation of mobility enhancement robotic wheelchair.

Author

Daveler B, Salatin B, Grindle GG, Candiotti J, Wang H, and Cooper RA

Subjects

Adult, Computer-Aided Design, Electric Power Supplies, Environment, Equipment Design methods, Female, Focus Groups, Humans, Male, Middle Aged, Surveys and Questionnaires, Robotics, Safety, Wheelchairs

Abstract

The design of the mobility enhancement robotic wheelchair (MEBot) was based on input from electric powered wheelchair (EPW) users regarding the conditions they encounter when driving in both indoor and outdoor environments that may affect their safety and result in them becoming immobilized, tipping over, or falling out of their wheelchair. Phase I involved conducting a participatory design study to understand the conditions and barriers EPW users found to be difficult to drive in/over. Phase II consisted of creating a computer-aided design (CAD) prototype EPW to provide indoor and outdoor mobility that addressed these conditions with advanced applications. Phase III involved demonstrating the advanced applications and gathering feedback from end users about the likelihood they would use the advanced applications. The CAD prototype incorporated advanced applications, including self-leveling, curb climbing, and traction control, that addressed the challenging conditions and barriers discussed with EPW users (n = 31) during the participatory design study. Feedback of the CAD design and applications in phase III from end users (n = 12) showed a majority would use self-leveling (83%), traction control (83%), and curb climbing (75%). The overall design of MEBot received positive feedback from EPW users. However, these opinions will need to be reevaluated through user trials as the design advances.

Published

2015

36. Design and user evaluation of a wheelchair mounted robotic assisted transfer device.

Author

Grindle GG, Wang H, Jeannis H, Teodorski E, and Cooper RA

Subjects

Adult, Disabled Persons, Female, Focus Groups, Humans, Male, User-Computer Interface, Wheelchairs, Young Adult, Equipment Design instrumentation, Robotics instrumentation

Abstract

Purpose: The aim of this study is to describe the robotic assisted transfer device (RATD) and an initial focus group evaluation by end users. The purpose of the device is to aid in the transfers of people with disabilities to and from their electric powered wheelchair (EPW) onto other surfaces. The device can be used for both stand-pivot transfers and fully dependent transfers, where the person being transferred is in a sling and weight is fully on the robot. The RATD is fixed to an EPW to allow for its use in community settings., Method: A functional prototype of the RATD was designed and fabricated. The prototype was presented to a group of 16 end users and feedback on the device was obtained via a survey and group discussion., Results: Thirteen out of sixteen (83%) participants agreed that it was important to develop this type of technology. They also indicated that user, caregiver, and robotic controls were important features to be included in the device., Conclusions: Participants in this study suggested that they would be accepting the use of robotic technology for transfers and a majority did not feel that they would be embarrassed to use this technology.

Published

2015

37. Stability analysis of electrical powered wheelchair-mounted robotic-assisted transfer device.

Author

Wang H, Tsai CY, Jeannis H, Chung CS, Kelleher A, Grindle GG, and Cooper RA

Subjects

Equipment Design, Equipment Safety, Humans, Manikins, Models, Theoretical, Moving and Lifting Patients instrumentation, Robotics, Wheelchairs

Abstract

The ability of people with disabilities to live in their homes and communities with maximal independence often hinges, at least in part, on their ability to transfer or be transferred by an assistant. Because of limited resources and the expense of personal care, robotic transfer assistance devices will likely be in great demand. An easy-to-use system for assisting with transfers, attachable to electrical powered wheelchairs (EPWs) and readily transportable, could have a significant positive effect on the quality of life of people with disabilities. We investigated the stability of our newly developed Strong Arm, which is attached and integrated with an EPW to assist with transfers. The stability of the system was analyzed and verified by experiments applying different loads and using different system configurations. The model predicted the distributions of the system's center of mass very well compared with the experimental results. When real transfers were conducted with 50 and 75 kg loads and an 83.25 kg dummy, the current Strong Arm could transfer all weights safely without tip-over. Our modeling accurately predicts the stability of the system and is suitable for developing better control algorithms to enhance the safety of the device.

Published

2014

38. Development of an advanced mobile base for personal mobility and manipulation appliance generation II robotic wheelchair.

Author

Wang H, Candiotti J, Shino M, Chung CS, Grindle GG, Ding D, and Cooper RA

Subjects

Activities of Daily Living, Computer Simulation, Elevators and Escalators, Humans, Robotics methods, Software, Disabled Persons, Movement, Robotics instrumentation, Wheelchairs

Abstract

Background: This paper describes the development of a mobile base for the Personal Mobility and Manipulation Appliance Generation II (PerMMA Gen II robotic wheelchair), an obstacle-climbing wheelchair able to move in structured and unstructured environments, and to climb over curbs as high as 8 inches. The mechanical, electrical, and software systems of the mobile base are presented in detail, and similar devices such as the iBOT mobility system, TopChair, and 6X6 Explorer are described., Findings: The mobile base of PerMMA Gen II has two operating modes: "advanced driving mode" on flat and uneven terrain, and "automatic climbing mode" during stair climbing. The different operating modes are triggered either by local and dynamic conditions or by external commands from users. A step-climbing sequence, up to 0.2 m, is under development and to be evaluated via simulation. The mathematical model of the mobile base is introduced. A feedback and a feed-forward controller have been developed to maintain the posture of the passenger when driving over uneven surfaces or slopes. The effectiveness of the controller has been evaluated by simulation using the open dynamics engine tool., Conclusion: Future work for PerMMA Gen II mobile base is implementation of the simulation and control on a real system and evaluation of the system via further experimental tests.

Published

2013

39. Initial development of direct interaction for a transfer robotic Arm system for caregivers.

Author

Jeannis H, Grindle GG, Kelleher A, Wang H, Brewer B, and Cooper R

Subjects

Biomechanical Phenomena, Caregivers, Humans, Locomotion physiology, Moving and Lifting Patients statistics & numerical data, Robotics instrumentation, Moving and Lifting Patients instrumentation, Robotics methods

Abstract

The most common injuries in healthcare are related to transfers. The Strong Arm system assists caregivers in providing fully dependent transfers from an electric power wheelchair to a bed, shower bench, toilet or other surface. However, this system currently controlled by buttons could be more successful with a more intuitive method during use. This paper presents the initial development of direct interaction for a robotic transfer system called Strong Arm. Direct interaction was used to make a transfer system more intuitive to operate using a three-axis load cell. To move Strong Arm, the user must apply intentional force on any of the given axes by surpassing the axis threshold. Unintentional movement could lead to injury. The results indicate that the thresholds for each axis were at least 3.5 N in X, 16.9 N in Y and 5.3N in Z in order to prevent unintentional forces from a human hand that would cause the robot to move.

Published

2013

40. The Personal Mobility and Manipulation Appliance (PerMMA): a robotic wheelchair with advanced mobility and manipulation.

Author

Wang H, Grindle GG, Candiotti J, Chung C, Shino M, Houston E, and Cooper RA

Subjects

Adult, Female, Humans, Male, Middle Aged, Disabled Persons, Movement, Robotics, Wheelchairs

Abstract

The Personal Mobility and Manipulation Appliance (PerMMA) is a recently developed personal assistance robot developed to provide people with disabilities and older adults enhanced assistance in both mobility and manipulation, which are two fundamental components for independently activities of daily life performing, community participation, and quality of life. Technologies to assist with mobility and manipulation are among the most important tools for clinicians, end users and caregivers; however, there are currently few systems that provide practical and coordinated assistance with mobility and manipulation tasks. The PerMMA was not only developed and evaluated to provide users and caregivers enhanced mobility and manipulation options, but also as a clinical tool as well as research platform. The development and evaluation of PerMMA are presented in the paper.

Published

2012

41. The role of assistive robotics in the lives of persons with disability.

Author

Brose SW, Weber DJ, Salatin BA, Grindle GG, Wang H, Vazquez JJ, and Cooper RA

Subjects

Activities of Daily Living, Disability Evaluation, Equipment Design, Equipment Safety, Female, Forecasting, Humans, Male, Self-Help Devices trends, User-Computer Interface, Disabled Persons rehabilitation, Quality of Life, Robotics methods, Self-Help Devices statistics & numerical data

Abstract

Robotic assistive devices are used increasingly to improve the independence and quality of life of persons with disabilities. Devices as varied as robotic feeders, smart-powered wheelchairs, independent mobile robots, and socially assistive robots are becoming more clinically relevant. There is a growing importance for the rehabilitation professional to be aware of available systems and ongoing research efforts. The aim of this article is to describe the advances in assistive robotics that are relevant to professionals serving persons with disabilities. This review breaks down relevant advances into categories of Assistive Robotic Systems, User Interfaces and Control Systems, Sensory and Feedback Systems, and User Perspectives. An understanding of the direction that assistive robotics is taking is important for the clinician and researcher alike; this review is intended to address this need.

Published

2010

42. Real-time model based electrical powered wheelchair control.

Author

Wang H, Salatin B, Grindle GG, Ding D, and Cooper RA

Subjects

Activities of Daily Living, Algorithms, Computer Simulation, Computers, Electricity, Humans, Models, Theoretical, Neural Networks, Computer, Robotics, Software, Task Performance and Analysis, Time Factors, Equipment Design methods, Wheelchairs

Abstract

The purpose of this study was to evaluate the effects of three different control methods on driving speed variation and wheel slip of an electric-powered wheelchair (EPW). A kinematic model as well as 3D dynamic model was developed to control the velocity and traction of the wheelchair. A smart wheelchair platform was designed and built with a computerized controller and encoders to record wheel speeds and to detect the slip. A model based, a proportional-integral-derivative (PID) and an open-loop controller were applied with the EPW driving on four different surfaces at three specified speeds. The speed errors, variation, rise time, settling time and slip coefficient were calculated and compared for a speed step-response input. Experimental results showed that model based control performed best on all surfaces across the speeds.

Published

2009

43. An experimental method for measuring the moment of inertia of an electric power wheelchair.

Author

Wang H, Grindle GG, Connor S, and Cooper RA

Subjects

Architectural Accessibility, Electricity, Models, Theoretical, Reproducibility of Results, Equipment Design, Wheelchairs

Abstract

This study describe an experiment measuring the moment of inertia of an electric powered wheelchair (EPW) using a torsional pendulum method. Inertia of the wheelchair is an important factor for control, which is a key issue in wheelchair driving. The experimental test platform consisted of a bottom circular wood plate, an upper metal plate, and four ropes. Materials with known moments of inertia such as the metal disk and cylinder were used to test the accuracy of the system. The EPW used in the experiment was Invacare G3 Torque SP Storm Series. The measured result of the moment inertia of the wheelchair was 5.2280 kg.m(2) and the errors of the system are less than 10% even when the object is only 25lbs. The results are consistent when compared with other approximate methods. In addition, the experimental method could be used to measure the moment of inertia of manual wheelchairs and other irregular objects.

Published

2007

44. Personal mobility and manipulation using robotics, artificial intelligence and advanced control.

Author

Cooper RA, Ding D, Grindle GG, and Wang H

Subjects

Forecasting, Humans, Locomotion, Robotics methods, Natural Language Processing, Robotics trends

Abstract

Recent advancements of technologies, including computation, robotics, machine learning, communication, and miniaturization technologies, bring us closer to futuristic visions of compassionate intelligent devices. The missing element is a basic understanding of how to relate human functions (physiological, physical, and cognitive) to the design of intelligent devices and systems that aid and interact with people. Our stakeholder and clinician consultants identified a number of mobility barriers that have been intransigent to traditional approaches. The most important physical obstacles are stairs, steps, curbs, doorways (doors), rough/uneven surfaces, weather hazards (snow, ice), crowded/cluttered spaces, and confined spaces. Focus group participants suggested a number of ways to make interaction simpler, including natural language interfaces such as the ability to say "I want a drink", a library of high level commands (open a door, park the wheelchair, ...), and a touchscreen interface with images so the user could point and use other gestures.

Published

2007

45. Development and qualitative assessment of the GAME(Cycle) exercise system.

Author

Guo S, Grindle GG, Authier EL, Cooper RA, Fitzgerald SG, Kelleher A, and Cooper R

Subjects

Algorithms, Arm physiology, Data Interpretation, Statistical, Equipment Design, Ergometry, Feedback, Humans, Surveys and Questionnaires, Disabled Persons, Exercise physiology, Physical Fitness physiology, Video Games

Abstract

Increased physical activity is important for reducing the risk of cardiovascular disease. However, among people with disabilities, inactivity is prevalent. In order to encourage exercise among members of this group, an exercise system combining arm ergometry with video gaming, called the GAME(Cycle) was previously developed. User input was received through an arm crank ergometer on a swivel, with the angular velocity of the ergometer resistance wheel controlling one axis and rotation of ergometer about the swivel controlling the other. The purpose of this study was to detail the algorithms used in this device and present novel features included in a second generation of the GAME(Cycle). The features include a wheel on base, a steering return mechanism, and wireless fire buttons. A focus group of clinicians (n = 8), wheelchair users (n = 8), and clinician wheelchair users (n = 2) was conducted to evaluate the features of the GAME(Cycle). The focus group suggested improvements to the steering mechanism and to reduce vibration in the system. However, the focus group enjoyed the GAME(Cycle) and felt that it would encourage exercise among persons with disabilities.

Published

2006