Over 240,000 Veterans with disabilities use mobility devices such as manual and power wheelchairs and scooters, and this number continues to grow. Mobility devices have been described as the most enabling technology a clinician can provide to a person with a disability. Appropriate mobility devices improve function, independence, home and community integration; activity and participation; comfort; and quality of life. Yet, battery-powered mobility devices (BPMDs) have many drawbacks. Despite advances in technology, batteries are still hazardous to humans and the environment, heavy (which limits transportability), and incompatible with wet or highly humid environments. Repairs to electrical systems and replacement of batteries are frequently needed. These are costly and result in being stranded, missing medical appointments, missing work or school, injury, increased pain, lower self-perceived health, skin breakdown, higher hospitalization rates, and reduced community participation. Surveys conducted by our VA Center on Wheelchairs and Associated Rehabilitation Engineering (WARE) identified alternative power sources as a top research priority of Veterans and providers. Compressed air is a power source that has many advantages over batteries, including safety to both humans and the environment, lighter weight, waterproof nature, and lack of any electrical components which can reduce the frequency of repairs. Two novel pneumatically-powered mobility devices (PPMDs), a scooter and wheelchair, were developed and tested for feasibility with 107 users. The devices were lighter and had sufficient driving range per charge for the average user. There were no safety or repair issues encountered in the 11-week field test. Filling air tanks was also much faster than charging a typical battery. With pilot funds, we then built two new scooters and two new power wheelchairs with longer driving ranges. We also developed a portable backup tank system that allows us to refill or replace the tanks easily in the community. The purpose of this study is to clinically evaluate the impact of PPMDs on Veterans living in long-term care facilities, and to obtain feedback from key stakeholders regarding the design and feasibility of use of PPMDs in long-term care. Long-term care was chosen because it is an ideal setting for technology that is water-proof (e.g., compatible with inclement weather, ease of cleaning, and resistant to incontinence and requires less maintenance and upkeep. In Phase 1 (Technical), we will build 8 pneumatically-powered scooters, 8 pneumatically-powered wheelchairs, 2 air filling stations with flow switches that measure air filling time, 20 dataloggers that will measure battery charging time, and 20 dataloggers that will monitor activity levels. Phase 2 (clinical evaluation) will comprise two aims. First, we will enroll 50 Veterans into a cross-over trial in which they use a BPMD provided to them that is the same make and model as their own BPMD, and its PPMD counterpart in random order, each for 6 months. We will compare pneumatically-powered and battery- powered scooters and wheelchairs with respect to functional mobility, satisfaction, psychosocial impact, ?charging time,? maintenance and repairs. We hypothesize that Veterans will have higher levels of mobility, satisfaction, and psychosocial impact when using PPMDs compared to when using BPMDs. We also hypothesize that PPMDs will be faster to ?charge? and have fewer maintenance and repair issues than BPMDs. Second, we will conduct qualitative interviews of the 40 participants in the clinical evaluation and an additional 54 key stakeholders involved in PPMD and BPMD use (e.g., family members/caregivers, clinicians, and technical support personnel). We will assess patient, facility, VA healthcare system, and other factors that may be barriers or facilitators to use of PPMDs and identify modifiable factors that may further improve the design. Results of the proposed study will pave the way for potential adoption of this technology within the VA. Such adoption could have a direct and positive impact on Veterans' lives. This research has the potential for national impact on the wheelchair provision process and services within the VA.
Over 240,000 Veterans with disabilities use mobility devices such as manual and power wheelchairs and scooters, and this number continues to grow. Mobility devices have been described as the most enabling technology a clinician can provide to a person with a disability. Yet, the batteries used to power scooters and wheelchairs have many drawbacks. Batteries are hazardous to humans and the environment, heavy (which limits transportability), and incompatible with wet or highly humid environments. Repairs to electrical systems and replacement of batteries are frequently needed. These are costly and adversely affect the Veteran. Compressed air is a power source that overcomes many of these disadvantages. We have developed a scooter and a wheelchair that are powered solely by compressed air. The purpose of this study is to clinically evaluate the impact of these new devices on Veterans living in long-term care facilities, and to obtain feedback from nurses, therapists, and engineers regarding their design and feasibility of use in long-term care.
