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Abstract

The Johns Hopkins Hospital created a biocontainment unit (BCU) to care for patients with highly infectious diseases while assuring healthcare worker safety. Research to date for BCU protocols and practices are based on case reports and lessons learned from patient care and exercises. This study seeks to be the first to explore the influences of healthcare worker movement and personal protective equipment (PPE) doffing on the transport of simulant pathogen particles in a BCU. A cough device released 1 μm fluorescent polystyrene beads (PSLs) in the patient room. PSL transport was then examined under 2 scenarios: (1) PSL release only, no healthcare workers; and (2) PSL release during 5-minute simulated activity by healthcare workers. Airborne PSL concentrations were quantified every second for 30 minutes per scenario by 7 optical particle sensors located throughout the BCU. PSLs were not detected in the donning room at any time nor in the doffing room during the first test scenario where no healthcare worker was present. The main difference detected between the tested scenarios was the presence of PSLs in the doffing room when healthcare workers were removing PPE, potentially due to re-aerosolization of PSLs off the exterior PPE surface or opening of the patient room door. Future work will further explore the potential for re-aerosolization of particles off of PPE during doffing. The present study provides the groundwork for a systematic method for evaluating the BCU and doffing procedures for their respective safety, and it also pilots a systematic method for evaluating potential pathogen exposure pathways for BCU healthcare workers.

This study explores the influences of healthcare worker movement and personal protective equipment doffing on the transport of simulant pathogen particles in a biocontainment unit. It provides the groundwork for a systematic method for evaluating the safety of the biocontainment unit and of the doffing procedures.

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References

Baize

, Pannetier

, Oestereich

, et al. Emergence of Zaire Ebola virus disease in Guinea. N Engl J Med, 2014; 371(15):1418-1425.

Heymann

, Chen

, Takemi

, et al. Global health security: the wider lessons from the West African Ebola virus disease epidemic. Lancet, 2015; 385(9980):1884-1901.

Frieden

, Damon

, Bell

, Kenyon

, Nichol

. Ebola 2014—new challenges, new global response and responsibility. N Engl J Med, 2014; 371(13):1177-1180.

Centers for Disease Control and Prevention. 2014 Ebola outbreak in West Africa—case counts. CDC website. Updated April 13,. 2016. http://www.cdc.gov/vhf/ebola/outbreaks/2014-west-africa/case-counts.html. Accessed February 1, 2018.

van Doremalen

, Bushmaker

, Munster

. Stability of Middle East respiratory syndrome coronavirus (MERS-CoV) under different environmental conditions. Euro Surveill, 2013; 181(38).

Lee

, Wong

. Probable transmission chains of Middle East respiratory syndrome coronavirus and the multiple generations of secondary infection in South Korea. Int J Infect Dis, 2015; 38:65-67.

Dowell

, Simmerman

, Erdman

, et al. Severe acute respiratory syndrome coronavirus on hospital surfaces. Clin Infect Dis, 2004; 39(5):652-657.

McCarthy

. US to “rethink” Ebola infection control after nurse falls ill. BMJ, 2014; 349:g6240.

Smith

, Anderson

, Christopher

, et al. Designing a biocontainment unit to care for patients with serious communicable diseases: a consensus statement. Biosecur Bioterror, 2006; 4(4):351-365.

10.

Kortepeter

, Smith

, Hewlett

, Cieslak

. Caring for patients with Ebola: a challenge in any care facility. Ann Intern Med, 2015; 162(1):68-69.

11.

Hewlett

, Varkey

, Smith

, Ribner

. Ebola virus disease: preparedness and infection control lessons learned from two biocontainment units. Curr Opin Infect Dis, 2015; 28(4):343-348.

12.

Johnson

, Sullivan

, Piquette

, et al. Lessons learned: critical care management of patients with Ebola in the United States. Crit Care Med, 2015; 43(6):1157-1164.

13.

Lowe

, Gibbs

, Schwedhelm

, Nguyen

, Smith

. Nebraska Biocontainment Unit perspective on disposal of Ebola medical waste. Am J Infect Control, 2014; 42(12):1256-1257.

14.

Jelden

, Gibbs

, Smith

, et al. Nebraska Biocontainment Unit patient discharge and environmental decontamination after Ebola care. Am J Infect Control, 2015; 43(3):203-205.

15.

Lowe

, Jelden

, Schenarts

, et al. Considerations for safe EMS transport of patients infected with Ebola virus. Prehosp Emerg Care, 2015; 19(2):179-183.

16.

Janosko

, Holbrook

, Adams

, et al. Safety precautions and operating procedures in an (A)BSL-4 laboratory: 1. Biosafety Level 4 suit laboratory suite entry and exit procedures. J Vis Exp, 2016;(116).

17.

Sprecher

, Caluwaerts

, Draper

, et al. Personal protective equipment for filovirus epidemics: a call for better evidence. J Infect Dis, 2015; 212(Suppl 2):S98-S100.

18.

Beam

, Schwedhelm

, Boulter

, et al. Personal protective equipment processes and rationale for the Nebraska Biocontainment Unit during the 2014 activations for Ebola virus disease. Am J Infect Control, 2016; 44(3):340-342.

19.

Alderman

, Stiegel

, Estes

, Thomann

, Sempowski

. Field-testing method for loose-fitting powered air-purifying respirators equipped with HEPA filters. Appl Biosaf, 2016; 21(2):71-78.

20.

American Hospital Association. HHS announces 35 U.S. hospitals identified as Ebola treatment centers. December 2,. 2014. http://www.aha.org/advocacy-issues/tools-resources/advisory/2014/141202-ebola-adv.pdf. Accessed February 1, 2018.

21.

Garibaldi

, Kelen

, Brower

, et al. The creation of a biocontainment unit at a tertiary care hospital. The Johns Hopkins Medicine experience. Ann Am Thorac Soc, 2016; 13(5):600-608.

22.

Herstein

, Biddinger

, Kraft

, et al. Current capabilities and capacity of Ebola treatment centers in the United States. Infect Control Hosp Epidemiol, 2016; 37(3):313-318.

23.

Lindsley

, Reynolds

, Szalajda

, Noti

, Beezhold

. A cough aerosol simulator for the study of disease transmission by human cough-generated aerosols. Aerosol Sci Technol, 2013; 47(8):937-944.

24.

Liljegren

, Brown

, Lunden

, Silcott

. Particle deposition onto people in a transit venue. Health Secur, 2016; 14(4):237-249.

25.

Department of Homeland Security; Science and Technology. DHS NYC subway tracer studies, May 9-13, 2016. https://www.dhs.gov/sites/default/files/publications/DHS NYC Subway Tracer Studies May 9-13%2C 2016.pdf. Accessed February 1, 2018.

26.

Patterson

, Fennington

, Bayha

, et al. Biocontainment laboratory risk assessment: perspectives and considerations. Pathog Dis, 2014; 71(2):102-108.

27.

Shurtleff

, Garza

, Lackemeyer

, et al. The impact of regulations, safety considerations and physical limitations on research progress at maximum biocontainment. Viruses, 2012; 4(12):3932-3951.

28.

Reponen

, Willeke

, Grinshpun

, Nevalainen

. Biological particle sampling. In: Kulkarni

, Baron

, Willeke

, eds. Aerosol Measurement. Hoboken, NJ: John Wiley & Sons;. 2011:549-570.

29.

Gralton

, Tovey

, McLaws

, Rawlinson

. The role of particle size in aerosolised pathogen transmission: a review. J Infect, 2011; 62(1):1-13.

30.

Tellier

. Review of aerosol transmission of influenza A virus. Emerg Infect Dis, 2006; 12(11):1657-1662.

31.

FLIR. Biological agent detection. http://www.flir.com/threatdetection/display/?id=63346. Accessed February 1, 2018.

32.

Joint Program Executive Office for Chemical and Biological Defense.. Instantaneous bio-analyzer and collector [fact sheet]. May 6,. 2013. https://jacks.jpeocbd.army.mil/Public/FactSheetProvider.ashx?productId=607. Accessed February 1, 2018.

33.

Nazaroff

. Indoor bioaerosol dynamics. Indoor Air, 2016; 26(1):61-78.

34.

Bhangar

, Adams

, Pasut

, et al. Chamber bioaerosol study: human emissions of size-resolved fluorescent biological aerosol particles. Indoor Air, 2016; 26(2):193-206.

35.

Pereira

, Knibbs

, He

, et al. Sources and dynamics of fluorescent particles in hospitals. Indoor Air, 2017; 27(5):988-1000.

36.

Harding

, Hara

, Hall

, et al. Unique DNA-barcoded aerosol test particles for studying aerosol transport. Aerosol Sci Technol, 2016; 50(5):429-435.

37.

Sterk

, Plomp

, van de Vate

, Quanjer

. Physical properties of aerosols produced by several jet- and ultrasonic nebulizers. Bull Eur Physiopathol Respir, 1984; 20(1):65-72.

38.

Torabi-Parizi

, Davey

Jr , Suffredini

, Chertow

. Ethical and practical considerations in providing critical care to patients with Ebola virus disease. Chest, 2015; 147(6):1460-1466.

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Identifying Potential Provider and Environmental Contamination on a Clinical Biocontainment Unit Using Aerosolized Pathogen Simulants

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