Archive (2016–2006)

How to Exploit Twitter for Public Health Monitoring?

Journal: Methods of Information in Medicine
Subtitle: A journal stressing, for more than 50 years, the methodology and scientific fundamentals of organizing, representing and analyzing data, information and knowledge in biomedicine and health care
ISSN: 0026-1270
Topic:

Focus Theme
GMDS 2012 – Medical Informatics, Medicine and Neighboring Disciplines
Guest Editor: J. Stausberg

DOI: https://doi.org/10.3414/ME12-02-0010
Issue: 2013 (Vol. 52): Issue 4 2013
Pages: 326-339

How to Exploit Twitter for Public Health Monitoring?

GMDS 2012 – Medical Informatics, Medicine and Neighboring Disciplines

K. Denecke (1, 2), M. Krieck (3), L. Otrusina (4), P. Smrz (4), P. Dolog (5), W. Nejdl (2), E. Velasco (6)

(1) Innovation Center Computer Assisted Surgery, Leipzig, Germany; (2) Forschungszentrum L3S, Hannover, Germany; (3) Niedersächsisches Landesgesundheitsamt, Hannover, Germany; (4) Brno University of Technology, Brno, Czech Republic; (5) Aalborg University, Aalborg, Denmark; (6) Robert Koch Institut, Berlin, Germany

Keywords

Public Health, population surveillance, Web science, Medicine 2.0, Textmining, epidemic intelligence

Summary

Objectives: Detecting hints to public health threats as early as possible is crucial to prevent harm from the population. However, many disease surveillance strategies rely upon data whose collection requires explicit reporting (data transmitted from hospitals, laboratories or physicians). Collecting reports takes time so that the reaction time grows. Moreover, context information on individual cases is often lost in the collection process. This paper describes a system that tries to address these limitations by processing social media for identifying information on public health threats. The primary objective is to study the usefulness of the approach for supporting the monitoring of a population's health status.

Methods: The developed system works in three main steps: Data from Twitter, blogs, and forums as well as from TV and radio channels are continuously collected and filtered by means of keyword lists. Sentences of relevant texts are classified relevant or irrelevant using a binary classifier based on support vector machines. By means of statistical methods known from biosurveillance, the relevant sentences are further analyzed and signals are generated automatically when unexpected behavior is detected. From the generated signals a subset is selected for presentation to a user by matching with user queries or profiles. In a set of evaluation experiments, public health experts assessed the generated signals with respect to correctness and relevancy. In particular, it was assessed how many relevant and irrelevant signals are generated during a specific time period.

Results: The experiments show that the system provides information on health events identified in social media. Signals are mainly generated from Twitter messages posted by news agencies. Personal tweets, i.e. tweets from persons observing some symptoms, only play a minor role for signal generation given a limited volume of relevant messages. Relevant signals referring to real world outbreaks were generated by the system and monitored by epidemiologists for example during the European football championship. But, the number of relevant signals among generated signals is still very small: The different experiments yielded a proportion between 5 and 20% of signals regarded as “relevant” by the users. Vaccination or education campaigns communicated via Twitter as well as use of medical terms in other contexts than for outbreak reporting led to the generation of irrelevant signals.

Conclusions: The aggregation of information into signals results in a reduction of monitoring effort compared to other existing systems. Against expectations, only few messages are of personal nature, reporting on personal symptoms. Instead, media reports are distributed over social media channels. Despite the high percentage of irrelevant signals generated by the system, the users reported that the effort in monitoring aggregated information in form of signals is less demanding than monitoring huge social-media data streams manually. It remains for the future to develop strategies for reducing false alarms.

You may also be interested in...

1.
Contribution of the IMIA Primary Healthcare Working Group

Special Section: Big Data - Smart Health Strategies

Working Group Contributions

H. Liyanage (1), S. de Lusignan (1), S-T. Liaw (2), C. E. Kuziemsky (3), F. Mold (1), P. Krause (4), D. Fleming (1), S. Jones (1)

Yearb Med Inform 2014 : 27-35

https://doi.org/10.15265/IY-2014-0016

2.

Focus Theme – Editorial

K. Denecke (1), E. Brooks (2)

Methods Inf Med 2013 52 2: 148-151

3.
K. Rettig 1, C. Trenkwalder 2, K. Berger3

Nervenheilkunde 2008 27 4: 334-338