Online Simulation

And More

  1. biomarker discovery
  2. cancer care engineering
  3. cceHUB
  4. colorectal cancer
  5. diet
  6. global proteomics
  7. health services research
  8. lipidomics
  9. mass spectrometry
  10. metabolomics
  11. OMIC analysis
  12. population-based models
  13. proteome discovery pipeline
  14. proteomics
  15. sample acquisition
  16. screening
  17. statistical models
  18. visual analytics

Other

Support

Trouble Report

For immediate assistance browse through our support center. You can find answers to many questions in just a few minutes.

If still experiencing problems, send us a report.

required
Why the math question?

Syndromic Surveillance Hypothesis Development Using Visual Analytics

Posted 09 Sep, 2008 in Downloads

0 review(s) (Review this)

0 citations

View Presentation (WMV)

Contributor(s) Ross Maciejewski

David Ebert
Purdue University
Abstract image When analyzing syndromic surveillance data, health care officials look for areas with unusually high cases of syndromes. Unfortunately, many outbreaks are difficult to detect because their signal is obscured by the statistical noise. Consequently, many detection algorithms have a high false positive rate. While many false alerts can be easily filtered by trained epidemiologists, others require health officials to drill down into the data, analyzing specific segments of the population and historical trends over time and space. Furthermore, the ability to accurately recognize meaningful patterns in the data becomes more challenging as these data sources increase in volume and complexity. To facilitate more accurate and efficient event detection, we have created a visual analytics tool that provides analysts with linked geo-spatiotemporal and statistical analytic views.

We model syndromic hotspots by applying a kernel density estimation on the population sample. When an analyst selects a syndromic hotspot, temporal statistical graphs of the hotspot are created. Similarly, regions in the statistical plots may be selected to generate geospatial features specific to the current time period. Demographic filtering can then be combined to determine if certain populations are more affected than others. These tools allow analysts to perform real-time hypothesis testing and evaluation.

credits Ross Maciejewski
Stephen Rudolph
Shaun J. Grannis
David S. Ebert

Purdue University Regional Visualization and Analytics Center (PURVAC)
citations Ross Maciejewski, Stephen Rudolph, Ryan Hafen, Ahmad Abusalah, Mohamed Yakout, Mourad Ouzzani, William S. Cleveland, Shaun J. Grannis, Michael Wade, David S. Ebert. Understanding Syndromic Hotspots - A Visual Analytics Approach.IEEE Symposium on Visual Analytics Science and Technology (VAST), 2008 (To Appear).
sponsoredby Department of Homeland Security
Cite this work

If you reference this work in a publication, please cite as follows:

    Ross Maciejewski, Stephen Rudolph, Ryan Hafen, Ahmad Abusalah, Mohamed Yakout, Mourad Ouzzani, William S. Cleveland, Shaun J. Grannis, Michael Wade, David S. Ebert. Understanding Syndromic Hotspots - A Visual Analytics Approach.IEEE Symposium on Visual Analytics Science and Technology (VAST), 2008 (To Appear).

  • Ross Maciejewski; David Ebert (2008), "Syndromic Surveillance Hypothesis Development Using Visual Analytics," http://ccehub.org/resources/58.

    BibTex | EndNote

Tags
  1. health services research
  2. statistical models
  3. visual analytics