To the Editor—Multidrug-resistant organisms (MDROs) have recently caused infection outbreaks with increased morbidity and mortality.Reference Furuya, Larson and Landers 1 , Reference Ma, Wu and Li 2 Colonization of the inanimate hospital environment and intestines may contribute to the increased prevalence of MDROs.Reference Karageorgopoulos and Falagas 3 , Reference Bernard, Lanotte and Lawrence 4 To prevent the spread of MDROs in the intensive care unit (ICU), the correlation between colonization of MDROs and the length of patient hospitalization is important to consider. However, there are few reports in the literature on the epidemiology of MDROs in China that highlight the change in trends of their colonization rate.
Here, we studied the contamination of the surrounding environment (eg, telemetry units, blood pressure cuffs, flashlights, stethoscopes, bedside tables, and bed frames, controllers, and mattresses) and rectal colonization of ICU patients at a tertiary teaching hospital in China with 5 types of MDROs (ie, multidrug-resistant [MDR] Acinetobacter baumannii [AB], methicillin-resistant Staphylococcus aureus, MDR-Pseudomonas aeruginosa, MDR-Escherichia coli, and MDR-Klebsiella pneumoniae). Samples were collected using cotton swabs. Methicillin-resistant S. aureus was isolated by CHROMagar MRSA plates (CHROMagar) and identified using Staphytect Plus kits (Oxoid). Gram-negative MDROs were isolated by ChromID Extended-Spectrum Beta-Lactamase plates (bioMeriéux) and identified using the analytical profile index system (bioMeriéux). AB and P. aeruginosa isolates that were resistant to ceftazidime were considered MDROs.
The overall MDRO contamination rate of ICU patients’ surrounding environment was 26.4%. The MDR-AB contamination rate was 18.9%, and its proportion versus all MDROs was 71.6%. The contamination rates of methicillin-resistant S. aureus, MDR-K. pneumonia, MDR-E. coli, and MDR-P. aeruginosa were 3.4%, 3.0%, 1.6%, and 1.1%, respectively. Furthermore, the MDRO contamination rate was 10.0% on day 1, and it increased to 35.4% by day 3, 35.8% by day 7, and 46.6% by day 14 or longer. The MDR-AB contamination rate and the proportion of MDR-AB versus all MDROs increased with the length of stay in ICU (Table 1).
NOTE. χ2 test for trend (day 1, day 3, day 7, day ≥14): a, P<.001; b, P<.001, c, P=.05, d, P=.004, e, P<.001, f, P=.008. χ2 test: G vs g, P<.001; H vs h, P<.001; I vs i, P=.474; K vs k, P=.653; M vs m, P=.578; N vs n, P=.457. MDR-AB, multidrug-resistant Acinetobacter baumannii.
The overall MDRO rectal colonization rate was 67.7%, with MDR-E. coli at 49.2%, MDR-AB at 20.1%, MDR-K. pneumoniae at 18.0%, and MDR-P. aeruginosa at 2.7%. The colonization rate for MDROs was 56.1% on day 1, and it was 73.5% by day 3, 71.4% by day 7, and 81.8% by day 14 or longer. In addition, the MDR-AB colonization rate and proportion of MDR-AB versus all MDROs isolated from the rectums of ICU patients were also positively associated with the length of stay in ICU (Table 1).
We implemented a series of interventions, including enhancing the adherence to hand hygiene, disinfecting the environment using Metrex CaviWipes (Metrex) immediately after MDROs detection, and contact isolation. After interventions, the overall MDRO and MDR-AB contamination rates in the surrounding environment decreased to 10.7% and 7.1%, respectively (Table 1). Nevertheless, the overall MDRO and MDR-AB rectal colonization rates showed no significant differences (69.8% and 17.9%, respectively).
These results show that contamination and colonization with MDROs, particularly MDR-AB, in the surrounding environment and rectums of ICU patients, are augmented with increasing of length of stay in ICU. The phenomenon could be explained by the spread of organisms from contaminated sites to other surfaces, the contamination of the environment by sputum, feces, blood, and body fluids from patients, and the selective pressure exerted by antibiotic use. Furthermore, Acinetobacter spp. are able to survive on inanimate surfaces for a long time,Reference Karageorgopoulos and Falagas 3 thus the proportion of MDR-AB versus all MDROs on the surrounding environmental surfaces increased with length of stay in ICU. Therefore, more efforts should be put towards the cleaning and disinfection of the surrounding environment of patients, particularly those who stay in ICU for an extended time. Conventional interventions could lead to the decontamination of MDROs on the surrounding environmental surfaces; however, these procedures will not reduce rectal colonization of gram-negative MDROs. Additional measures, including decreasing unnecessary antibiotic exposure, decontamination of the digestive tract, and chlorhexidine bathing,Reference Climo, Yokoe and Warren 5 are needed for the decolonization of endosomatic MDROs.
ACKNOWLEDGMENTS
Financial support. Specialty Fund of Chinese Ministry of Health (No. 201002021); Hunan Provincial Science Fund (No. 2012SK3200).
Potential conflicts of interest. All authors report no conflicts of interest relevant to this article.