1. Methodology for Establishing a Community-Wide Life Laboratory for Capturing Unobtrusive and Continuous Remote Activity and Health Data
- Author
-
Zachary Beattie, Thomas Riley, Nora Mattek, Nicole Sharma, Molly Bowman, Katherine Wild, Adriana Seelye, Jeffrey Kaye, Ona Golonka, Christina Reynolds, Johanna Austin, Charlie Quinn, and Jonathan Lee
- Subjects
Ubiquitous computing ,020205 medical informatics ,Aging in place ,Computer science ,General Chemical Engineering ,Wearable computer ,02 engineering and technology ,General Biochemistry, Genetics and Molecular Biology ,03 medical and health sciences ,0302 clinical medicine ,Home automation ,Human–computer interaction ,0202 electrical engineering, electronic engineering, information engineering ,medicine ,Humans ,Aged ,Monitoring, Physiologic ,Behavior ,030214 geriatrics ,General Immunology and Microbiology ,business.industry ,Computers ,General Neuroscience ,Continuous monitoring ,Loneliness ,Remote Sensing Technology ,Sleep (system call) ,Self Report ,medicine.symptom ,business ,Laboratories ,Independent living - Abstract
An end-to-end suite of technologies has been established for the unobtrusive and continuous monitoring of health and activity changes occurring in the daily life of older adults over extended periods of time. The technology is aggregated into a system that incorporates the principles of being minimally obtrusive, while generating secure, privacy protected, continuous objective data in real-world (home-based) settings for months to years. The system includes passive infrared presence sensors placed throughout the home, door contact sensors installed on exterior doors, connected physiological monitoring devices (such as scales), medication boxes, and wearable actigraphs. Driving sensors are also installed in participants' cars and computer (PC, tablet or smartphone) use is tracked. Data is annotated via frequent online self-report options that provide vital information with regard to the data that is difficult to infer via sensors such as internal states (e.g., pain, mood, loneliness), as well as data referent to activity pattern interpretation (e.g., visitors, rearranged furniture). Algorithms have been developed using the data obtained to identify functional domains key to health or disease activity monitoring, including mobility (e.g., room transitions, steps, gait speed), physiologic function (e.g., weight, body mass index, pulse), sleep behaviors (e.g., sleep time, trips to the bathroom at night), medication adherence (e.g., missed doses), social engagement (e.g., time spent out of home, time couples spend together), and cognitive function (e.g., time on computer, mouse movements, characteristics of online form completion, driving ability). Change detection of these functions provides a sensitive marker for the application in health surveillance of acute illnesses (e.g., viral epidemic) to the early detection of prodromal dementia syndromes. The system is particularly suitable for monitoring the efficacy of clinical interventions in natural history studies of geriatric syndromes and in clinical trials.
- Published
- 2018
- Full Text
- View/download PDF