Alimuddin Zumla1, David S Hui2. 1. Department of Infection, Division of Infection and Immunity, Centre for Clinical Microbiology, University College London, London, UK; NIHR Biomedical Research Centre, University College London Hospitals, London, UK. 2. Department of Medicine and Therapeutics and Stanley Ho Center for Emerging Infectious Diseases, The Chinese University of Hong Kong, Shatin, New Territories, Hong Kong. Electronic address: dschui@cuhk.edu.hk.
The recent exponential rise in the number of reported cases of Middle East respiratory syndrome coronavirus (MERS-CoV) is of major global concern. The Fifth Meeting of the International Health Regulations Emergency Committee concerning MERS-CoV was convened on May 13, 2014, by WHO's Director-General and concluded that, although the seriousness of the situation had increased, there was no evidence of sustained human-to-human transmission and that conditions for a Public Health Emergency of International Concern have not yet been met.MERS-CoV was first reported in September, 2012, when a novel β coronavirus was isolated from a Saudi Arabian patient in Jeddah, who had died of severe pneumonia and multiple organ failure in June, 2012. More recently, a large number of MERS-CoV cases have been reported from Saudi Arabia and for the first time cases have been detected in Malaysia, Philippines, Greece, Egypt, Netherlands, and the USA. There have been a total of 572 cases of MERS-CoV infection reported to WHO globally as of May 15, 2014, with 173 deaths (30% mortality rate).The large number of MERS-CoV cases (229 cases) reported between April 11, 2014, and May 4, 2014, by Saudi Arabia were probably seasonal (related to the camel birthing season), reminiscent of the clusters of hospital cases that were previously confirmed in a hospital in Jordan in April, 2012, which involved haemodialysis units within hospitals in Al Hasa in April and May, 2013. Sequencing of the MERS-CoV isolates from the Jeddah outbreak has shown no substantial genetic changes. The WHO Emergency Committee concluded that the increase in cases reported among health-care workers from hospitals in Jeddah was amplified due to overcrowding and inadequate infection control measures.1, 3Acute viral respiratory tract infections, such as severe acute respiratory syndrome (SARS) and MERS, are predominantly spread by large respiratory droplets (≥10 μm in diameter) during coughing and sneezing, whereas contact with fomite (including hand contamination with subsequent self-inoculation) might be another potential route of transmission.6, 7 The SARS outbreak in 2003 provided good lessons for the evaluation of environmental influences on the aerosol transmission of communicable respiratory diseases and the importance of good infection control measures in the prevention of nosocomial infections. One intriguing aspect of the 2003 SARS epidemic was the occurrence of super-spreading events, which accounted for 71·1% and 74·8% of SARS cases in Hong Kong and Singapore, respectively. During the SARS outbreak in 2003, SARS-coronavirus (CoV) was moderately transmissible, with 2·7 secondary infections for every index case. However, infectivity was substantially increased when coupled with environmental factors: 138 patients, many of whom were health-care workers, were infected within 2 weeks as a result of exposure to one patient with community-acquired pneumonia who was admitted to a general medical ward. This super-spreading event seemed to be related to overcrowding and poor ventilation in the dry air-conditioned hospital ward, together with some contribution by the use of a jet nebuliser for the index case. Evidence of airborne transmission of SARS-CoV was also supported by positive air samples of the virus obtained from a hospital room occupied by a patient with SARS in Toronto, Canada.On the basis of analysis of data in a case-control study that involved 124 medical wards in 26 hospitals in Guangzhou, China, and Hong Kong, the risk factors for super-spreading events of SARS-CoV in the hospital setting were: close separation between beds of less than 1 m; performance of resuscitation; staff working while experiencing symptoms; and patients requiring oxygen or non-invasive ventilation therapy. This study also showed that the availability of washing or changing facilities for health-care staff was a protective factor. These findings have important clinical implications in the prevention of nosocomial infections of MERS-CoV in health-care facilities in the Middle East.A systematic review of five case-control and five retrospective cohort studies identified tracheal intubation, tracheotomy, and manual ventilation before intubation as procedures associated with risk of transmission of SARS-CoV to health-care workers. Opportunistic airborne transmission might occur through fine particle aerosols as an efficient means of propagation under special environmental conditions, such as with aerosol-generating procedures in a ward environment with poor ventilation and insufficient air changes.The main infection prevention and control measures for managing acute viral respiratory tract infections are simple and well documented: droplet precaution (wearing a surgical mask within 1 m of the patient) and contact precaution (wearing gown and gloves on entering the room and removing them on leaving). Droplet precautions should be added to standard precautions for patients with symptoms of acute respiratory infection. Contact precautions and eye protection should be added when caring for probable or confirmed cases of MERS-CoV infection. Airborne precautions should be applied when performing aerosol-generating procedures.3, 6, 7, 15 To reduce room contamination in the hospital setting, major health organisations have recommended the application of a minimum room ventilation rate of six air changes per hour in existing facility, whereas a higher ventilation rate of 12 air changes per hour is recommended for new or renovated construction, especially when caring for patients receiving mechanical ventilation and during aerosol-generating procedures.16, 17 Infection source and engineering control, including avoidance of aerosol generation with appropriate airborne precautions, and improvement of ventilation design in hospital wards warrant serious consideration for the prevention of nosocomial outbreaks. The MERS-CoV outbreak in Jeddah, and the increasing number of health-care workers acquiring the infection as a result of poor infection control measures, remind us of the need to go back to the basics of infection control to help prevent MERS-CoV infection in health-care workers.This online publication has been corrected. The corrected version first appeared at thelancet.com on May 21, 2014
Authors: Steven Riley; Christophe Fraser; Christl A Donnelly; Azra C Ghani; Laith J Abu-Raddad; Anthony J Hedley; Gabriel M Leung; Lai-Ming Ho; Tai-Hing Lam; Thuan Q Thach; Patsy Chau; King-Pan Chan; Su-Vui Lo; Pak-Yin Leung; Thomas Tsang; William Ho; Koon-Hung Lee; Edith M C Lau; Neil M Ferguson; Roy M Anderson Journal: Science Date: 2003-05-23 Impact factor: 47.728
Authors: Nelson Lee; David Hui; Alan Wu; Paul Chan; Peter Cameron; Gavin M Joynt; Anil Ahuja; Man Yee Yung; C B Leung; K F To; S F Lui; C C Szeto; Sydney Chung; Joseph J Y Sung Journal: N Engl J Med Date: 2003-04-07 Impact factor: 91.245
Authors: Ali M Zaki; Sander van Boheemen; Theo M Bestebroer; Albert D M E Osterhaus; Ron A M Fouchier Journal: N Engl J Med Date: 2012-10-17 Impact factor: 91.245
Authors: Timothy F Booth; Bill Kournikakis; Nathalie Bastien; Jim Ho; Darwyn Kobasa; Laurie Stadnyk; Yan Li; Mel Spence; Shirley Paton; Bonnie Henry; Barbara Mederski; Diane White; Donald E Low; Allison McGeer; Andrew Simor; Mary Vearncombe; James Downey; Frances B Jamieson; Patrick Tang; Frank Plummer Journal: J Infect Dis Date: 2005-03-18 Impact factor: 5.226
Authors: Ignatius T Yu; Zhan Hong Xie; Kelvin K Tsoi; Yuk Lan Chiu; Siu Wai Lok; Xiao Ping Tang; David S Hui; Nelson Lee; Yi Min Li; Zhi Tong Huang; Tao Liu; Tze Wai Wong; Nan Shan Zhong; Joseph J Sung Journal: Clin Infect Dis Date: 2007-03-09 Impact factor: 9.079