Bed-integrated local exhaust ventilation system combined with local air cleaning for improved IAQ in hospital patient rooms
2016
Building and Environment
Journal Article
Author(s): Bivolarova, M. P., Melikov, A. K., Mizutani, C., Kajiwara, K., Bolashikov, Z. D.
Ventilation in patient rooms can contribute to the health and comfort of both patients and staff. Indoor air quality (IAQ) is indeed an important factor in healthcare environments, especially when it comes to mitigating the spread of germs and potentially toxic airborne chemicals. Ventilated mattresses (VMs) can be effective for capturing and removing potentially harmful airborne particles before they spread throughout a given space.
Added June 2017
Airflow patterns through single hinged and sliding doors in hospital isolation rooms – Effect of ventilation, flow differential and passage
2016
Building and Environment
Journal Article
Author(s): Kalliomäki, p., Saarinen, P., Tang, J. W., Koskela, h.
Patients with highly contagious diseases are often housed in negative pressure isolation rooms. These rooms attempt to reduce cross-infections within the hospital. However, airflows produced by healthcare worker movements and door opening motions pose the risk of spreading pathogen-laden air from negative pressure isolation rooms into other spaces. A significant number of previous studies have examined the impact of single-hinged door-generated airflows, but few have compared hinged doors with sliding doors.
Added December 2016
Secondary exposure risks to patients in an airborne isolation room: Implications for anteroom design
2016
Building and Environment
Journal Article
Author(s): Mousavi, E. S., Grosskopf, K. R.
Previous research has shown that negatively pressurized Airborne Infectious Isolation Rooms (AIIRs) can protect hospitals from fatal airborne pathogens such as tuberculosis. But this use of negative pressurization can simultaneously increase the chances of isolated patients contracting secondary infections, or healthcare-acquired infections (HAIs), caused by air blowing in from adjacent spaces. Research is needed to better assess the actual likelihood of secondary infections occurring in these scenarios so that steps can be taken to mitigate these risks.
Added December 2016
The Creation of a Biocontainment Unit at a Tertiary Care Hospital: The Johns Hopkins Medicine Experience
2016
Annals of the American Thoracic Society
Journal Article
Issue 5
Volume 13
Pages 600-608
Author(s): Garibaldi, B. T., Kelen, G. D., Brower, R. G., Bova, G., Ernst, N., Reimers, M., Langlotz, R., Gimburg, A., Iati, M., Smith, C., MacConnell, S., James, H., Lewin, J. J., Trexler, P., Black, M. A., Lynch, C., Clarke, W., Marzinke, M. A., Sokoll, L. J., Carroll, K. C., Parish, N. M., Dionne, K., Biddison, E. L. D., Gwon, H. S., Sauer, L., Hill, P., Newton, S. M., Garrett, M. R., Miller, R. G., Perl, T. M., Maragakis, L. L.
Prior to the 2014 Ebola virus disease (EVD) outbreak in West Africa, the United States had only one to three specialized biocontainment units. Once the EVD crisis began, a group of reputable American healthcare institutions worked together to renovate a deactivated clinical space into a functioning biocontainment unit (BCU).
Added April 2016
