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Protective isolation in single-bed rooms: studies in a modified hospital ward

Published online by Cambridge University Press:  15 May 2009

G. A. J. Ayliffe
Affiliation:
Hospital Infection Research Laboratory, Summerfield Hospital, Birmingham 18 and Department of Statistics, Birmingham Regional Hospital Board
B. J. Collins
Affiliation:
Hospital Infection Research Laboratory, Summerfield Hospital, Birmingham 18 and Department of Statistics, Birmingham Regional Hospital Board
E. J. L. Lowbury
Affiliation:
Hospital Infection Research Laboratory, Summerfield Hospital, Birmingham 18 and Department of Statistics, Birmingham Regional Hospital Board
Mary Wall
Affiliation:
Hospital Infection Research Laboratory, Summerfield Hospital, Birmingham 18 and Department of Statistics, Birmingham Regional Hospital Board
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Studies were made in a modified hospital ward containing 19 beds, 14 of them in the open ward, one in a window-ventilated side-room, two in rooms with partial-recirculation ventilators giving 7–10 air changes per hour, and two in self-contained isolation suites with plenum ventilation (20 air changes per hour), ultra-violet (UV) barriers at doorways and airlocks.

Preliminary tests with aerosols of tracer bacteria showed that few bacteria entered the plenum or recirculation-ventilated rooms. Bacteria released inside mechanically ventilated cubicles escaped into the corridor, but this transfer was reduced by the presence of an airlock. UV barriers at the entrance to the airlock and the cubicle reduced the transfer of bacteria from cubicle to corridor.

During a period of 4 years while the ward was in use for surgical and gynaecological patients, the incidence of post-operative sepsis and colonization of wounds by multiple-resistant Staphylococcus aureus was lower (though not significantly lower) in the plenum-ventilated rooms than in the open ward, the recirculator-ventilated cubicles and the window-ventilated cubicles. Nasal acquisition of multiple-resistant Staph. aureus was significantly less common in the plenum-ventilated than in the recirculator-ventilated cubicles and in the other areas. Mean counts of bacteria on settle-plates were significantly lower in the plenum-ventilated cubicles than in the other areas; mean settle-plate counts in the recirculator-ventilated cubicles were significantly lower than in the open ward and in the window-ventilated side-room; similar results were shown by slit-sampling of air. Mean settle-plate counts were significantly lower in all areas when the ward was occupied by female patients. Staph. aureus was rarely carried by air from plenum-ventilated or other cubicles to the open ward, or from the open ward to the cubicles; though staphylococci were transferred from one floor area to another, they did not appear to be redispersed into the air in sufficient numbers to infect the patients. Ultra-violet irradiation caused a significant reduction in the total and staphylococcal counts from the floors of airlocks, and a significant reduction of total counts in the air.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1971

References

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