B de Jong1, A M Meeder1, K W A C Koekkoek2, M A Schouten3, P Westers4, A R H van Zanten5. 1. Department of Intensive Care, Gelderse Vallei Hospital, Ede, The Netherlands. 2. Department of Internal Medicine, Gelderse Vallei Hospital, Ede, The Netherlands. 3. Department of Microbiology, Gelderse Vallei Hospital, Ede, The Netherlands. 4. Julius Centre, University Medical Center Utrecht, Utrecht, The Netherlands. 5. Department of Intensive Care, Gelderse Vallei Hospital, Ede, The Netherlands. Electronic address: zantena@zgv.nl.
Abstract
BACKGROUND: Among patients admitted to European hospitals or intensive care units (ICUs), 5.7% and 19.5% will encounter healthcare-associated infections (HAIs), respectively, and antimicrobial resistance is emerging. As hospital surfaces are contaminated with potentially pathogenic bacteria, environmental cleanliness is an essential aspect to reduce HAIs. AIM: To address the efficacy of a titanium dioxide coating in reducing the microbial colonization of environmental surfaces in an ICU. METHODS: A prospective, controlled, single-centre pilot study was conducted to examine the effect of a titanium dioxide coating on the microbial colonization of surfaces in an ICU. During the pre- and post-intervention periods, surfaces were cultured with agar contact plates (BBL RODAC plates). Factors that were potentially influencing the bacterial colonization of surfaces were recorded. A repeated measurements analysis within a hierarchic multi-level framework was used to analyse the effect of the intervention, controlling for the explanatory variables. FINDINGS: The mean ratio for the total number of colony-forming units (cfus) in a room between the pre- and post-intervention periods was 0.86 (standard deviation 0.57). The optimal model included the following explanatory variables: intervention (P=0.065), week (P=0.002), culture surfaces (P<0.001), ICU room (P=0.039), and interaction between intervention and week (P=0.002) and between week and culture surfaces (P=0.031). The effect of the intervention on the number of cfus from all culture plates in Week 4 between the pre- and post-intervention periods was -0.47 (95% confidence interval -0.24 to - 0.70). CONCLUSION: This study found that a titanium dioxide coating had no effect on the microbial colonization of surfaces in an ICU.
BACKGROUND: Among patients admitted to European hospitals or intensive care units (ICUs), 5.7% and 19.5% will encounter healthcare-associated infections (HAIs), respectively, and antimicrobial resistance is emerging. As hospital surfaces are contaminated with potentially pathogenic bacteria, environmental cleanliness is an essential aspect to reduce HAIs. AIM: To address the efficacy of a titanium dioxide coating in reducing the microbial colonization of environmental surfaces in an ICU. METHODS: A prospective, controlled, single-centre pilot study was conducted to examine the effect of a titanium dioxide coating on the microbial colonization of surfaces in an ICU. During the pre- and post-intervention periods, surfaces were cultured with agar contact plates (BBL RODAC plates). Factors that were potentially influencing the bacterial colonization of surfaces were recorded. A repeated measurements analysis within a hierarchic multi-level framework was used to analyse the effect of the intervention, controlling for the explanatory variables. FINDINGS: The mean ratio for the total number of colony-forming units (cfus) in a room between the pre- and post-intervention periods was 0.86 (standard deviation 0.57). The optimal model included the following explanatory variables: intervention (P=0.065), week (P=0.002), culture surfaces (P<0.001), ICU room (P=0.039), and interaction between intervention and week (P=0.002) and between week and culture surfaces (P=0.031). The effect of the intervention on the number of cfus from all culture plates in Week 4 between the pre- and post-intervention periods was -0.47 (95% confidence interval -0.24 to - 0.70). CONCLUSION: This study found that a titanium dioxide coating had no effect on the microbial colonization of surfaces in an ICU.