The design of isolation ward for reducing airborne infection in common clinical settings. / 臨床環境條件下隔離病房設計以減少空氣傳播感染 / CUHK electronic theses & dissertations collection / Digital dissertation consortium / Lin chuang huan jing tiao jian xia ge li bing fang she ji yi jian shao kong qi chuan bo gan ran

January 2011

According to recommendations from the Facility Guidelines Institute (FGI) of the American Institute of Architects (AIA), World Health Organization (WHO) and Center for Disease Control and Prevention (CDC), a common engineering approach to isolation room design is to maintain the air ventilation rate at a minimum of 12 air changes per hour (ACH) for mixing and dilution, and a negative pressure in the room to direct airflow inwards, instead of leaking outwards. / In collaborations with physicians in the Respiratory Division and the Intensive Care Unit (ICU) at the Chinese University of Hong Kong (CUHK), a series of experiments were carried out to verify the ventilation performance of an All room at the Princess Margaret Hospital (PMH). Experiments investigated the effects of ACH, the control of airflow direction, the air tightness of the automatic swing door and the application of positive pressure ventilation procedures, such as high flow rate oxygen masks, jet nebulizers and NPPV. These were extensively tested in two different isolation rooms of the Prince of Wales Hospital (PWH) and PMH, under common clinical circumstances and environmental conditions. / Many patients with severe respiratory infection require supportive therapy for respiratory failure. Common interventions involve supplemental oxygen to improve tissue oxygenation. In the worst scenario, mechanical ventilation via non-invasive positive pressure ventilation (NPPV) may be required. Since a large amount of aerosols is generated during these interventions, there is a great risk of spreading infectious aerosols from the respiratory tract of the patient to the surrounding environment. / The aerodynamic data in this thesis infonns architects and engineers on how to improve the hospital ward ventilation design so as to avoid aerosol and ventilation leakage. Ultimately, it is hoped that this work may play a role in preventing devastating nosocomial outbreaks in the future. / The design of airborne infection isolation (AII) room has become one of the major research domains following the emergence of the global concern of acute respiratory diseases in this century. These include severe acute respiratory syndrome (SARS) in 2003, H5N1 avian influenza, and pandemic influenza H1N1 in 2009. All of which have claimed thousands of lives. Even with the current stringent design and practice guidelines, nosocomial infection of healthcare workers (HCWs) and inpatients continues to occur. This implies that there might be limitations in current isolation ward designs. / The experiments implemented a high-fidelity human patient simulator (HPS) which could be programmed with different lung breathing conditions and oxygen flow rate settings. The patient exhaled air dispersion distances and airflow patterns were captured in detail with a non-intrusive, laser light sheet, smoke particle scattering technique, designed for this thesis. Thin laser light sheets were generated by a high energy YAG laser with custom cylindrical optics. Smoke concentration in the patient exhaled air and leakage jets was estimated from the intensity of light scattered, which was then expressed as nonnalized particle concentration contours using computer programs developed for this study. / The study quantitatively revealed the distinctive patient exhaled airflow patterns and the extent of bioaerosol, generated directly from the patient source with the application of different oxygen delivery interventions for different patient lung conditions and oxygen flow rates. It was found that contamination was more critical during the administration of oxygen therapies, which is common in clinical circumstances. Source control is therefore the most efficient and effective approach to the reduction and even elimination of patient exhaled bioaerosol contaminants. Thus, when working in an isolation room environment, full preventive measure should be taken and it is essential to consider the location of mechanical vents and the patient exhaled airflow patterns. It has also been shown in experiment that applications of bacterial viral filter could be a solution to the problem. / Chow, Ka Ming. / Advisers: Puay Peng Ho; Jin Yeu Tsou. / Source: Dissertation Abstracts International, Volume: 73-09(E), Section: A. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2011. / Includes bibliographical references (leaves 115-147). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. Ann Arbor, MI : ProQuest Information and Learning Company, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.

Airborne infection--Prevention

Hospital wards--Design and construction

Isolation (Hospital care)

Infection Control

Patient Isolation

Patients' Rooms

Alternative solutions to 1960's single corridor ward design in hospitals: a case study based on nurses's perspectives

Rastogi, Nandita P.

17 March 2010

Many existing hospitals have problems with their ward layouts. However, the increase in construction costs and the decrease in the number of hospitals have made renovation more economical than building new facilities. Compounding the problem of inefficient floor layouts is the increasing severity of cases treated on an inpatient basis. This research was designed to evaluate the problems faced by nurses working on long corridor patient wards in Montgomery Regional Hospital in Blacksburg, Virginia. It was shown in the study and through previous studies in the literature that these types of wards have physical design problems that affect adversely nurses’ activities in patient care. This study used a time travel method to evaluate the amount of time the nurses spent traveling between the nurses’ station, patient rooms, and other functional areas. Nurses’ perspectives concerning their physical environment and layout were also studied using a questionnaire. It was found that the travel time on the ward was directly related to the geometry of the ward. It was also shown that the total travel time was dependant on the number of patients in the ward. The average amount of time nurses spent traveling in Ward-A was more than the average time they spent in patient rooms. The average time the nurses spent traveling in Ward-B was less than the average time they spent in patient rooms. In addition to a discussion of the time travel data the study also posed several design solutions to problems found in Montgomery Regional Hospital. / Master of Science

LD5655.V855 1991.R388

Hospitals -- Designs and plans