Tracking and Visualization of Space-time Activities for a Micro-scale Flu Transmission Study

Overview

Journal Int J Health Geogr

Publisher Biomed Central

Specialties Health Services
Public Health

Date 2013 Feb 8

PMID 23388060

Citations 18

Authors

Feng Qi

Fei Du

Affiliations

Soon will be listed here.

Abstract

Background: Infectious diseases pose increasing threats to public health with increasing population density and more and more sophisticated social networks. While efforts continue in studying the large scale dissemination of contagious diseases, individual-based activity and behaviour study benefits not only disease transmission modelling but also the control, containment, and prevention decision making at the local scale. The potential for using tracking technologies to capture detailed space-time trajectories and model individual behaviour is increasing rapidly, as technological advances enable the manufacture of small, lightweight, highly sensitive, and affordable receivers and the routine use of location-aware devices has become widespread (e.g., smart cellular phones). The use of low-cost tracking devices in medical research has also been proved effective by more and more studies. This study describes the use of tracking devices to collect data of space-time trajectories and the spatiotemporal processing of such data to facilitate micro-scale flu transmission study. We also reports preliminary findings on activity patterns related to chances of influenza infection in a pilot study.

Methods: Specifically, this study employed A-GPS tracking devices to collect data on a university campus. Spatiotemporal processing was conducted for data cleaning and segmentation. Processed data was validated with traditional activity diaries. The A-GPS data set was then used for visual explorations including density surface visualization and connection analysis to examine space-time activity patterns in relation to chances of influenza infection.

Results: When compared to diary data, the segmented tracking data demonstrated to be an effective alternative and showed greater accuracies in time as well as the details of routes taken by participants. A comparison of space-time activity patterns between participants who caught seasonal influenza and those who did not revealed interesting patterns.

Conclusions: This study proved that tracking technology an effective technique for obtaining data for micro-scale influenza transmission research. The findings revealed micro-scale transmission hotspots on a university campus and provided insights for local control and prevention strategies.

Citing Articles

COVID-19 hotspot detection in a university setting.

Duncan G, Christensen W, Handley C PLoS One. 2024; 19(5):e0289254.

PMID: 38753626 PMC: 11098366. DOI: 10.1371/journal.pone.0289254.

Systematic review of best practices for GPS data usage, processing, and linkage in health, exposure science and environmental context research.

Pearson A, Tribby C, Brown C, Yang J, Pfeiffer K, Jankowska M BMJ Open. 2024; 14(2):e077036.

PMID: 38307539 PMC: 10836389. DOI: 10.1136/bmjopen-2023-077036.

Characterizing human movement patterns using GPS data loggers in an area of persistent malaria in Zimbabwe along the Mozambique border.

Hast M, Mharakurwa S, Shields T, Lubinda J, Searle K, Gwanzura L BMC Infect Dis. 2022; 22(1):942.

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Quality of hybrid location data drawn from GPS-enabled mobile phones: Does it matter?.

Yoo E, Roberts J, Eum Y, Shi Y Trans GIS. 2022; 24(2):462-482.

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Relationships among COVID-19 Prevention Practices, Risk Perception and Individual Characteristics: A Temporal Analysis.

Wang L, Yu J, Chen D, Yang L Int J Environ Res Public Health. 2021; 18(20).

PMID: 34682656 PMC: 8535291. DOI: 10.3390/ijerph182010901.

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