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Delays in the Application of Outbreak Control Prophylaxis for Influenza a in a Nursing Home

Published online by Cambridge University Press:  02 January 2015

Paul J. Drinka*
Affiliation:
Wisconsin Veterans Home, King; Internal Medicine/Geriatrics, University of Wisconsin, Madison and theMedical College of Wisconsin, Milwaukee, Wisconsin
Peggy Krause
Affiliation:
Wisconsin Veterans Home, King, Wisconsin
Lori Nest
Affiliation:
Wisconsin Veterans Home, King, Wisconsin
Stefan Gravenstein
Affiliation:
Internal Medicine/Geriatrics, Eastern Virginia Medical School, Norfolk, Virginia
Brian Goodman
Affiliation:
Veterans Administration Medical Center, Madison, Wisconsin
Peter Shult
Affiliation:
Communicable Diseases Division, State Laboratory of Hygiene, Madison, Wisconsin
*
Wisconsin Veterans Home, N2665 County Road QQ, King, WI54946-0620

Abstract

Objective:

To identify delayed prophylaxis from a preexisting database and strategies to improve performance.

Setting:

A skilled nursing facility with 14 floors (4 buildings). The “outbreak unit” was a 50- to 60-bed floor.

Methods:

We performed surveillance during six seasons using one protocol. Prophylaxis was started when influenza was cultured in the building and 10% of residents on the floor had a new respiratory illness within 7 days. We defined delayed prophylaxis as four or more residents on a floor with positive cultures whose specimens had been collected within 5 days before the application of prophylaxis.

Results:

We identified 14 examples of delayed prophylaxis. In three, delayed prophylaxis was related to the 3.9-day delay between culture collection and culture report. There was a high degree of commonality among building attack rates within a season. During six seasons, the first case in the last building occurred 27 to 64 days after the first case in the facility. The two seasons with the greatest activity (68 and 154 cases, respectively) began with explosive, multi-floor outbreaks in a single building. The match between the circulating strain and the vaccine was good, except in 1997-1998 when there were seven examples of delayed prophylaxis.

Conclusions:

Influenza may involve buildings sequentially with a commonality of building attack rates. Explosive, multi-floor outbreaks early in the season could lead to a lower threshold for prophylaxis within a larger area when initial cases are encountered later in the season. This strategy could have prevented five examples of delayed prophylaxis. Rapid testing of multiple specimens while waiting for culture confirmation could have prevented three examples of delayed prophylaxis. (Infect Control Hosp Epidemiol 2002;23:600-603).

Type
Original Articles
Copyright
Copyright © The Society for Healthcare Epidemiology of America 2002

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