Efficient surveillance for healthcare-associated infections spreading between hospitals

被引:35
|
作者
Ciccolini, Mariano [1 ,2 ]
Donker, Tjibbe [2 ,3 ]
Grundmann, Hajo [2 ,3 ]
Bonten, Marc J. M. [4 ]
Woolhouse, Mark E. J. [1 ]
机构
[1] Univ Edinburgh, Ctr Immun Infect & Evolut, Edinburgh EH9 3JT, Midlothian, Scotland
[2] Univ Groningen, Univ Med Ctr Groningen, Dept Med Microbiol, NL-9713 GZ Groningen, Netherlands
[3] Natl Inst Publ Hlth & Environm, Ctr Infect Dis Control, NL-3721 MA Bilthoven, Netherlands
[4] Univ Med Ctr Utrecht, Julius Ctr Hlth Sci & Primary Care, NL-3584 CX Utrecht, Netherlands
来源
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA | 2014年 / 111卷 / 06期
基金
英国医学研究理事会;
关键词
patient referrals; network; RESISTANT STAPHYLOCOCCUS-AUREUS; TRANSMISSION; MRSA; UK; COLONIZATION; ENTEROCOCCI; EMERGENCE; COUNTY;
D O I
10.1073/pnas.1308062111
中图分类号
O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];
学科分类号
07 ; 0710 ; 09 ;
摘要
Early detection of new or novel variants of nosocomial pathogens is a public health priority. We show that, for healthcare-associated infections that spread between hospitals as a result of patient movements, it is possible to design an effective surveillance system based on a relatively small number of sentinel hospitals. We apply recently developed mathematical models to patient admission data from the national healthcare systems of England and The Netherlands. Relatively short detection times are achieved once 10-20% hospitals are recruited as sentinels and only modest reductions are seen as more hospitals are recruited thereafter. Using a heuristic optimization approach to sentinel selection, the same expected time to detection can be achieved by recruiting approximately half as many hospitals. Our study provides a robust evidence base to underpin the design of an efficient sentinel hospital surveillance system for novel nosocomial pathogens, delivering early detection times for reduced expenditure and effort.
引用
收藏
页码:2271 / 2276
页数:6
相关论文
共 50 条
  • [11] Moving into the future: electronic surveillance for healthcare-associated infections
    Woeltje, K. F.
    JOURNAL OF HOSPITAL INFECTION, 2013, 84 (02) : 103 - 105
  • [12] Surveillance of Healthcare-Associated Bloodstream and Urinary Tract Infections in a National Level Network of Indian Hospitals
    Mathur, Purva
    Malpiedi, Paul
    Walia, Kamini
    Malhotra, Rajesh
    Srikantiah, Padmini
    Katoch, Omika
    Katyal, Sonal
    Khurana, Surbhi
    Misra, Mahesh Chandra
    Gupta, Sunil
    Kumar, Subodh
    Sagar, Sushma
    Vig, Naveet
    Garg, Pramod
    Kapil, Arti
    Sahu, Manoj
    Chakrabarti, Arunaloke
    Ray, Pallab
    Biswal, Manisha
    Taneja, Neelam
    Rupali, Priscilla
    Chacko, Binila
    Michael, Joy Sarojini
    Balaji, Veeraraghavan
    Rodrigues, Camilla
    Nag, Vijaya Lakshmi
    Tak, Vibhor
    Venkatesh, Vimala
    Mukhopadhyay, Chiranjay
    Vandana, K. E.
    Varma, Muralidhar
    Deotale, Vijayshri
    Attal, Ruchita
    Padmaja, Kanne
    Wattal, Chand
    Goel, Neeraj
    Bhattacharya, Sanjay
    Karuna, Tadepalli
    Saigal, Saurabh
    Behera, Bijayini
    Singh, Sanjeev
    Thirunarayan, M. A.
    Nath, Reema
    Ray, Raja
    Baveja, Sujata
    D'Souza, Desma
    Chandy, Mammen
    Mukherjee, Sudipta
    Roy, Manas
    Goel, Gaurav
    INFECTION CONTROL AND HOSPITAL EPIDEMIOLOGY, 2020, 41 : S398 - S399
  • [13] Surveillance of healthcare-associated infections in a Tunisian university hospital
    Hannachi, H.
    Ben Cheikh, A.
    Bhiri, S.
    Ghali, H.
    Khefacha, S.
    Dhidah, L.
    Ben Rejeb, M.
    Latiri, H. Said
    EUROPEAN JOURNAL OF PUBLIC HEALTH, 2019, 29
  • [14] Bloodstream Infections and Clinical Significance of Healthcare-associated Bacteremia: A Multicenter Surveillance Study in Korean Hospitals
    Son, Jun Seong
    Song, Jae-Hoon
    Ko, Kwan Soo
    Yeom, Joon Sup
    Ki, Hyun Kyun
    Kim, Shin-Woo
    Chang, Hyun-Ha
    Ryu, Seong Yeol
    Kim, Yeon-Sook
    Jung, Sook-In
    Shin, Sang Yop
    Oh, Hee Bok
    Lee, Yeong Seon
    Chung, Doo Ryeon
    Lee, Nam Yong
    Peck, Kyong Ran
    JOURNAL OF KOREAN MEDICAL SCIENCE, 2010, 25 (07) : 992 - 998
  • [15] Getting it right: automated surveillance of healthcare-associated infections
    van Mourik, Maaike S. M.
    CLINICAL MICROBIOLOGY AND INFECTION, 2021, 27 : S1 - S2
  • [16] Data Requirements for Electronic Surveillance of Healthcare-Associated Infections
    Woeltje, Keith F.
    Lin, Michael Y.
    Klompas, Michael
    Wright, Marc Oliver
    Zuccotti, Gianna
    Trick, William E.
    INFECTION CONTROL AND HOSPITAL EPIDEMIOLOGY, 2014, 35 (09): : 1083 - 1091
  • [17] Automated Surveillance for Healthcare-Associated Infections: Opportunities for Improvement
    van Mourik, Maaike S. M.
    Troelstra, Annet
    van Solinge, Wouter W.
    Moons, Karel G. M.
    Bonten, Marc J. M.
    CLINICAL INFECTIOUS DISEASES, 2013, 57 (01) : 85 - 93
  • [18] Healthcare-associated infections in Australia: is it time for national surveillance?
    Shalit, Natalie
    AUSTRALIAN HEALTH REVIEW, 2016, 40 (04) : 475 - 475
  • [19] Validation of healthcare-associated infection surveillance in smaller Australian hospitals
    Hoskins, A. J.
    Worth, L. J.
    Imam, N.
    Johnson, S. A.
    Bull, A. L.
    Richards, M. J.
    Bennett, N. J.
    JOURNAL OF HOSPITAL INFECTION, 2018, 99 (01) : 85 - 88
  • [20] Establishing the prevalence of healthcare-associated infections in Australian hospitals: protocol for the Comprehensive Healthcare Associated Infection National Surveillance (CHAINS) study
    Russo, Philip L.
    Stewardson, Andrew
    Cheng, Allen C.
    Bucknall, Tracey
    Marimuthu, Kalisvar
    Mitchell, Brett G.
    BMJ OPEN, 2018, 8 (11):
12345