5 results on '"Nora Mang"'
Search Results
2. ESDR143 - Automated Anatomical Mapping of Hand Eczema
- Author
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Alexander Navarini, Marc Pouly, Michael Kunz, Julia-Tatjana Maul, Alvaro Gonzalez Jimenez, Philippe Gottfrois, Nora Mang, and Ludovic Amruthalingam
- Published
- 2022
3. Understanding short-term transmission dynamics of methicillin-resistant Staphylococcus aureus in the patient room
- Author
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Kristen Gibson, Lona Mody, Silvio D. Brugger, Kyle J. Gontjes, Hugo Sax, Aline Wolfensberger, Nora Mang, Marco Cassone, University of Zurich, and Wolfensberger, Aline
- Subjects
Microbiology (medical) ,medicine.medical_specialty ,Epidemiology ,MRSA colonization ,Transmission (medicine) ,business.industry ,610 Medicine & health ,2725 Infectious Diseases ,Contamination ,medicine.disease_cause ,Methicillin-resistant Staphylococcus aureus ,2726 Microbiology (medical) ,10234 Clinic for Infectious Diseases ,Patient room ,Infectious Diseases ,Internal medicine ,medicine ,In patient ,business ,2713 Epidemiology - Abstract
Objective:Little is known about the short-term dynamics of methicillin-resistant Staphylococcus aureus (MRSA) transmission between patients and their immediate environment. We conducted a real-life microbiological evaluation of environmental MRSA contamination in hospital rooms in relation to recent patient activity.Design:Observational pilot study.Setting:Two hospitals, hospital 1 in Zurich, Switzerland, and hospital 2 in Ann Arbor, Michigan, United States.Patients:Inpatients with MRSA colonization or infection.Methods:At baseline, the groin, axilla, nares, dominant hands of 10 patients and 6 environmental high-touch surfaces in their rooms were sampled. Cultures were then taken of the patient hand and high-touch surfaces 3 more times at 90-minute intervals. After each swabbing, patients’ hands and surfaces were disinfected. Patient activity was assessed by interviews at hospital 1 and analysis of video footage at hospital 2. A contamination pressure score was created by multiplying the number of colonized body sites with the activity level of the patient.Results:In total, 10 patients colonized and/or infected with MRSA were enrolled; 40 hand samples and 240 environmental samples were collected. At baseline, 30% of hands and 20% of high-touch surfaces yielded MRSA. At follow-up intervals, 8 (27%) of 30 patient hands, and 10 (6%) of 180 of environmental sites were positive. Activity of the patient explained 7 of 10 environmental contaminations. Patients with higher contamination pressure score showed a trend toward higher environmental contamination.Conclusion:Environmental MRSA contamination in patient rooms was highly dynamic and was likely driven by the patient’s MRSA body colonization pattern and the patient activity.
- Published
- 2022
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4. Understanding short-term transmission dynamics of methicillin-resistant
- Author
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Aline, Wolfensberger, Nora, Mang, Kristen E, Gibson, Kyle, Gontjes, Marco, Cassone, Silvio D, Brugger, Lona, Mody, and Hugo, Sax
- Subjects
Methicillin-Resistant Staphylococcus aureus ,Cross Infection ,Patients' Rooms ,Humans ,Staphylococcal Infections ,Hospitals - Abstract
Little is known about the short-term dynamics of methicillin-resistantObservational pilot study.Two hospitals, hospital 1 in Zurich, Switzerland, and hospital 2 in Ann Arbor, Michigan, United States.Inpatients with MRSA colonization or infection.At baseline, the groin, axilla, nares, dominant hands of 10 patients and 6 environmental high-touch surfaces in their rooms were sampled. Cultures were then taken of the patient hand and high-touch surfaces 3 more times at 90-minute intervals. After each swabbing, patients' hands and surfaces were disinfected. Patient activity was assessed by interviews at hospital 1 and analysis of video footage at hospital 2. A contamination pressure score was created by multiplying the number of colonized body sites with the activity level of the patient.In total, 10 patients colonized and/or infected with MRSA were enrolled; 40 hand samples and 240 environmental samples were collected. At baseline, 30% of hands and 20% of high-touch surfaces yielded MRSA. At follow-up intervals, 8 (27%) of 30 patient hands, and 10 (6%) of 180 of environmental sites were positive. Activity of the patient explained 7 of 10 environmental contaminations. Patients with higher contamination pressure score showed a trend toward higher environmental contamination.Environmental MRSA contamination in patient rooms was highly dynamic and was likely driven by the patient's MRSA body colonization pattern and the patient activity.
- Published
- 2021
5. Understanding the Short-Term Dynamics of MRSA Between Patients and Their Immediate Environment
- Author
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Kyle J. Gontjes, Hugo Sax, Kristen Gibson, Nora Mang, Lona Mody, Marco Cassone, and Aline Wolfensberger
- Subjects
Microbiology (medical) ,medicine.medical_specialty ,Epidemiology ,Hospitalized patients ,Transmission (medicine) ,business.industry ,Medical record ,MRSA infection ,Brief periods ,Infectious Diseases ,Internal medicine ,Acute care ,medicine ,Vancomycin ,business ,medicine.drug - Abstract
Background: Methicillin-resistant Staphylococcus aureus (MRSA) colonization of patients and contamination of their immediate environmental surfaces is common in the acute care setting, but there is much to be learned about the dynamics of MRSA transmission over a short period of time. Methods: A prospective, observational time-motion qualitative study was conducted at 2 hospitals: 1 in Michigan (hospital 1) and 1 in Zurich, Switzerland (hospital 2)—between November 2018 and July 2019. Hospitalized patients with a MRSA infection or colonization were enrolled. Microbiologic cultures for MRSA were collected from patient nares, axilla, groin and hands and several high-touch surfaces in their room (bed controls, call button, tray table, etc) at the first visit, and patient hands and high-touch surfaces continued to be swabbed every 90 minutes over the course of 5 hours. Patient hands and environment were disinfected after each swabbing. Clinical data were collected from patient’s medical chart. Results: We recruited 10 MRSA colonized or infected patients for the study with 50 hours of observation and obtained 360 patient and environmental swabs. Most were women (7 of 10); the average age was 52.8 years (Table 1). At the first visit, 8 (80%) patients were MRSA-colonized (at 1 or more body sites) and 5 (50%) rooms were MRSA-contaminated (at 1 or more surfaces). Also, 6 patients (60%) had an active MRSA infection and were actively receiving an anti-MRSA agent (eg, Vancomycin). Among those 6 patients receiving an anti-MRSA agent, 4 patients (67%) and 2 rooms (33%) were contaminated at the first visit. Among those 4 patients not receiving an anti-MRSA agent, all 4 patients (100%) and 3 rooms (75%) were contaminated at the baseline visit. Acquisitions (ie, MRSA recovered from a site it was not previously recovered from) occurred on 3 of 7 patient hands (43%) and on 6 occasions in the room (among 5 patients), most commonly at the toilet seat (2 of 6 times). MRSA prevalence on patient and room surfaces for the 5 patients enrolled at hospital 2 are illustrated in Figure 1, which shows colonization of patient and contamination of environment as well as activities performed by the patient in between culturing. Conclusions: We evaluated transmission of MRSA over brief periods of time; our results show that transmission of MRSA depended on patient activity in the room. Furthermore, degree of patient colonization is reflected by environmental contamination and supports the notion of constant transmission of MRSA from patients to environment.Funding: NoneDisclosures: None
- Published
- 2020
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