Publication

Geotemporal Analysis of Neisseria meningitidis Clones in the United States: 2000-2005

Downloadable Content

Persistent URL
Last modified
  • 06/17/2025
Type of Material
Authors
    Ann E. Wiringa, University of PittsburghKathleen A. Shutt, University of PittsburghJane W. Marsh, University of PittsburghAmanda C. Cohn, Centers for Disease Control and PreventionNancy E. Messonnier, Centers for Disease Control and PreventionShelley M. Zansky, New York State Department of HealthSusan Petit, Connecticut Department of Public HealthMonica Farley, Emory UniversityKen Gershman, Colorado Department of Public Health and EnvironmentRuth Lynfield, Minnesota Department of HealthArthur Reingold, University of California BerkeleyWilliam Schaffner, Vanderbilt UniversityJamie Thompson, Oregon Public Health DivisionShawn T. Brown, Carnegie Mellon UniversityBruce Y. Lee, University of PittsburghLee H. Harrison, University of Pittsburgh
Language
  • English
Date
  • 2013-12-12
Publisher
  • PUBLIC LIBRARY SCIENCE
Publication Version
Copyright Statement
  • This is an open-access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose.
License
Final Published Version (URL)
Title of Journal or Parent Work
Volume
  • 8
Issue
  • 12
Start Page
  • e82048
End Page
  • e82048
Abstract
  • Background: The detection of meningococcal outbreaks relies on serogrouping and epidemiologic definitions. Advances in molecular epidemiology have improved the ability to distinguish unique Neisseria meningitidis strains, enabling the classification of isolates into clones. Around 98% of meningococcal cases in the United States are believed to be sporadic. Methods: Meningococcal isolates from 9 Active Bacterial Core surveillance sites throughout the United States from 2000 through 2005 were classified according to serogroup, multilocus sequence typing, and outer membrane protein (porA, porB, and fetA ) genotyping. Clones were defined as isolates that were indistinguishable according to this characterization. Case data were aggregated to the census tract level and all non-singleton clones were assessed for non-random spatial and temporal clustering using retrospective space-time analyses with a discrete Poisson probability model. Results: Among 1,062 geocoded cases with available isolates, 438 unique clones were identified, 78 of which had ≥2 isolates. 702 cases were attributable to non-singleton clones, accounting for 66.0% of all geocoded cases. 32 statistically significant clusters comprised of 107 cases (10.1% of all geocoded cases) were identified. Clusters had the following attributes: included 2 to 11 cases; 1 day to 33 months duration; radius of 0 to 61.7 km; and attack rate of 0.7 to 57.8 cases per 100,000 population. Serogroups represented among the clusters were: B (n = 12 clusters, 45 cases), C (n = 11 clusters, 27 cases), and Y (n = 9 clusters, 35 cases); 20 clusters (62.5%) were caused by serogroups represented in meningococcal vaccines that are commercially available in the United States. Conclusions: Around 10% of meningococcal disease cases in the U.S. could be assigned to a geotemporal cluster. Molecular characterization of isolates, combined with geotemporal analysis, is a useful tool for understanding the spread of virulent meningococcal clones and patterns of transmission in populations.
Author Notes
Keywords
Research Categories
  • Biology, Virology
  • Health Sciences, Immunology

Tools

Relations

In Collection:

Items

Thumbnail Title File Description Date Uploaded Visibility Actions
file details Publication File - w5h8w.pdf Primary Content 2025-06-04 Public Download