Abstract
Attention Deficit Hyperactivity Disorder (ADHD) is a neurodevelopmental condition that affects up to 5% of adults worldwide. Recent research has suggested that diagnostic support technologies for ADHD may be less effective for adults while many focus on identifying attention deficits, leaving assessments of hyperactivity largely to subjective criteria and observations by clinicians. In this paper, we present a virtual reality (VR) based continuous performance test (CPT) intended to provide users with an attention task, during which their physical movements are measured by the system’s sensors, within an environment designed to resemble a real-world situation in which symptoms of ADHD would typically manifest. The design of this virtual environment was informed through a series of interviews and collaborative design sessions with clinicians. The VR-CPT system was tested using 20 adult participants with and without ADHD in order to determine which of any single or combined measures of motion by sensor (head-mounted display, arm controller, leg controller) and inertial variable (acceleration, velocity, angular acceleration, angular velocity) can be used to distinguish the two groups. Our results indicate that of our single measures, angular velocity across all sensors, angular acceleration of the leg controller, and velocity of the arm controller proved significant. Additionally, isolating high levels of mean motion activity, as measured by our combined inertial variables measure for a single sensor, proved insufficient at distinguishing between motion activity events corresponding to observations of physical movements considered indicative of hyperactivity and events considered non-indicative by a clinician.
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Notes
- 1.
The complete code for the VR-CPT system can be found in the following repository: https://github.com/GeorgiNedelev/Hyperactivity-screening-tool-for-adults-with-ADHD.
- 2.
A given three-dimensional sensor data point, p, is represented as \(\langle |x|,|y|,|z|\rangle \) where |.| denotes the absolute value and x, y, z are the coordinate values of the vector along their respective dimension. These non-negative coordinate values for p are summed to provide a single, instantaneous data point for each sensor which forms the basis of the data we use in the sets of combined sensor and variable measurements reported in our evaluation.
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Jensen, T.D., Korbutt, W.K., Nedelev, G.P., Bemman, B. (2022). Towards Diagnostic Support of Hyperactivity in Adults with ADHD Using a Virtual Reality Based Continuous Performance Test and Motion Sensor Data. In: Lewy, H., Barkan, R. (eds) Pervasive Computing Technologies for Healthcare. PH 2021. Lecture Notes of the Institute for Computer Sciences, Social Informatics and Telecommunications Engineering, vol 431. Springer, Cham. https://doi.org/10.1007/978-3-030-99194-4_31
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