NETEC Resource Library

Design Strategies for Biocontainment Units to Reduce Risk During Doffing of High-level Personal Protective Equipment.

Item

Click for External Resource*


Click to read full article*


*The link above may share a zip file (.zip) hosted on repository.netecweb.org. Zip files will download automatically.
*All other links are external and will open in a new window. If you click an external link, you are leaving the NETEC site, and we do not maintain, review, or endorse these materials. See our terms of use.


Item Type

Publication

Terms of Use

By accessing these materials you are agreeing to our terms of use, which may be found here: Terms of Use.

Was this resource helpful?


Title

Design Strategies for Biocontainment Units to Reduce Risk During Doffing of High-level Personal Protective Equipment.

Description

Few data exist to guide the physical design of biocontainment units, particularly the doffing area.

Creator

Source

Wong, Maria F., Zorana Matić, Gabrielle C. Campiglia, Craig M. Zimring, Joel M. Mumma, Colleen S. Kraft, Lisa M. Casanova, Francis T. Durso, Victoria L. Walsh, Puja Y. Shah, Andi L. Shane, Jesse T. Jacob, Jennifer R. Dubose.

Date

2019-09-13

Citation

Wong, Maria F., Zorana Matić, Gabrielle C. Campiglia, Craig M. Zimring, Joel M. Mumma, Colleen S. Kraft, Lisa M. Casanova, Francis T. Durso, Victoria L. Walsh, Puja Y. Shah, Andi L. Shane, Jesse T. Jacob, Jennifer R. Dubose, and C. D. C. Prevention Epicenters Program for the. 2019. "Design Strategies for Biocontainment Units to Reduce Risk During Doffing of High-level Personal Protective Equipment." Clinical Infectious Diseases 69 (Supplement_3):S241-S7.

Abstract

Abstract

BACKGROUND:

Few data exist to guide the physical design of biocontainment units, particularly the doffing area. This can impact the contamination risk of healthcare workers (HCWs) during doffing of personal protective equipment (PPE).

METHODS:

In phase I of our study, we analyzed simulations of a standard patient care task with 56 trained HCWs focusing on doffing of high-level PPE. In phase II, using a rapid cycle improvement approach, we tested different balance aids and redesigned doffing area layouts with 38 students. In phase III, we tested 1 redesigned layout with an additional 10 trained HCWs. We assessed the effectiveness of design changes on improving the HCW performance (measured by occurrence and number of risky behaviors) and reducing the physical and cognitive load by comparing the results from phase I and phase III.

RESULTS:

The physical load was highest when participants were removing their shoe covers without any balance aid; the use of a chair required the lowest physical effort, followed by horizontal and vertical grab bars. In the revised design (phase III), the overall performance of participants improved. There was a significant decrease in the number of HCW risky behaviors (P = .004); 5 risky behaviors were eliminated and 2 others increased. There was a significant decrease in physical load when removing disposable shoe covers (P = .04), and participants reported a similar workload in the redesigned doffing layout (P = .43).

CONCLUSIONS:

Through optimizing the design and layout of the doffing space, we reduced risky behaviors of HCWs during doffing of high-level PPE.

KEYWORDS:

Ebola; biocontainment unit design; design improvements; doffing personal protective equipment; occupational health

Accessibility

Read online through Oxford academic

Collection