Environmental factors on the SARS epidemic: air temperature, passage of time and multiplicative effect of hospital infection

KUN LIN; DANIEL YEE-TAK FONG; BILIU ZHU; JOHAN KARLBERG

doi:10.1017/S0950268805005054

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

The study sought to identify factors involved in the emergence, prevention and elimination of severe acute respiratory syndrome (SARS) in Hong Kong during 11 March to 22 May 2003. A structured multiphase regression analysis was used to estimate the potential effects of weather, time and interaction effect of hospital infection. In days with a lower air temperature during the epidemic, the risk of increased daily incidence of SARS was 18·18-fold (95% confidence interval 5·6–58·8) higher than in days with a higher temperature. The total daily new cases might naturally decrease by an average of 2·8 patients for every 10 days during the epidemic. The multiplicative effect of infected hospital staff with patients in an intensive care unit (ICU) and the proportion of SARS patients in ICUs might respectively increase the risk of a larger SARS epidemic in the community. The provision of protective gear in hospitals was also a very important factor for the prevention of SARS infection. SARS transmission appeared to be dependent on seasonal temperature changes and the multiplicative effect of hospital infection. SARS also appeared to retreat naturally over time.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Deguchi, Hiroshi Kanatani, Yasuhiro Kaneda, Toshiyuki Koyama, Yusuke Ichikawa, Manabu and Tanuma, Hideki 2006. Anti Pandemic Simulation by SOARS. p. 4581.

Cai, Quan-Cai Lu, Jian Xu, Qin-Feng Guo, Qiang Xu, De-Zhong Sun, Qing-Wen Yang, Hua Zhao, Gen-Ming and Jiang, Qing-Wu 2007. Influence of meteorological factors and air pollution on the outbreak of severe acute respiratory syndrome. Public Health, Vol. 121, Issue. 4, p. 258.

Bi, P. Wang, J and Hiller, J. E. 2007. Weather: driving force behind the transmission of severe acute respiratory syndrome in China?. Internal Medicine Journal, Vol. 37, Issue. 8, p. 550.

Chan, K. H. Peiris, J. S. Malik Lam, S. Y. Poon, L. L. M. Yuen, K. Y. and Seto, W. H. 2011. The Effects of Temperature and Relative Humidity on the Viability of the SARS Coronavirus. Advances in Virology, Vol. 2011, Issue. , p. 1.

Ladha, Nikhilesh Bhardwaj, Pankaj Charan, Jaykaran Mitra, Prasenjit Goyal, Jagdish Prasad Sharma, Praveen Singh, Kuldeep and Misra, Sanjeev 2020. Association of Environmental Parameters with COVID-19 in Delhi, India. Indian Journal of Clinical Biochemistry, Vol. 35, Issue. 4, p. 497.

Cai, Yuwen Huang, Tianlun Liu, Xin and Xu, Gaosi 2020. The effects of “Fangcang, Huoshenshan, and Leishenshan” hospitals and environmental factors on the mortality of COVID-19. PeerJ, Vol. 8, Issue. , p. e9578.

Meyer, Anne Sadler, Rohan Faverjon, Céline Cameron, Angus Robert and Bannister-Tyrrell, Melanie 2020. Evidence That Higher Temperatures Are Associated With a Marginally Lower Incidence of COVID-19 Cases. Frontiers in Public Health, Vol. 8, Issue. ,

Ozyigit, Ahmet 2020. Understanding Covid-19 transmission: The effect of temperature and health behavior on transmission rates. Infection, Disease & Health, Vol. 25, Issue. 4, p. 233.

Sobral, Marcos Felipe Falcão Duarte, Gisleia Benini da Penha Sobral, Ana Iza Gomes Marinho, Marcelo Luiz Monteiro and de Souza Melo, André 2020. Association between climate variables and global transmission oF SARS-CoV-2. Science of The Total Environment, Vol. 729, Issue. , p. 138997.

Qi, Hongchao Xiao, Shuang Shi, Runye Ward, Michael P. Chen, Yue Tu, Wei Su, Qing Wang, Wenge Wang, Xinyi and Zhang, Zhijie 2020. COVID-19 transmission in Mainland China is associated with temperature and humidity: A time-series analysis. Science of The Total Environment, Vol. 728, Issue. , p. 138778.

Palialol, Bruno Pereda, Paula and Azzoni, Carlos 2020. Does weather influence COVID‐19 transmission?. Regional Science Policy & Practice, Vol. 12, Issue. 6, p. 981.

Rouen, A. Adda, J. Roy, O. Rogers, E. and Lévy, P. 2020. COVID-19: relationship between atmospheric temperature and daily new cases growth rate. Epidemiology and Infection, Vol. 148, Issue. ,

Godderis, Lode Boone, Anke and Bakusic, Jelena 2020. COVID-19: a new work-related disease threatening healthcare workers. Occupational Medicine, Vol. 70, Issue. 5, p. 315.

Lin, Yi-Fan Duan, Qibin Zhou, Yiguo Yuan, Tanwei Li, Peiyang Fitzpatrick, Thomas Fu, Leiwen Feng, Anping Luo, Ganfeng Zhan, Yuewei Liang, Bowen Fan, Song Lu, Yong Wang, Bingyi Wang, Zhenyu Zhao, Heping Gao, Yanxiao Li, Meijuan Chen, Dahui Chen, Xiaoting Ao, Yunlong Li, Linghua Cai, Weiping Du, Xiangjun Shu, Yuelong and Zou, Huachun 2020. Spread and Impact of COVID-19 in China: A Systematic Review and Synthesis of Predictions From Transmission-Dynamic Models. Frontiers in Medicine, Vol. 7, Issue. ,

Xu, Hao Yan, Chonghuai Fu, Qingyan Xiao, Kai Yu, Yamei Han, Deming Wang, Wenhua and Cheng, Jinping 2020. Possible environmental effects on the spread of COVID-19 in China. Science of The Total Environment, Vol. 731, Issue. , p. 139211.

Rupani, P. F. Nilashi, M. Abumalloh, R. A. Asadi, S. Samad, S. and Wang, S. 2020. Coronavirus pandemic (COVID-19) and its natural environmental impacts. International Journal of Environmental Science and Technology, Vol. 17, Issue. 11, p. 4655.

Méndez-Arriaga, Fabiola 2020. The temperature and regional climate effects on communitarian COVID-19 contagion in Mexico throughout phase 1. Science of The Total Environment, Vol. 735, Issue. , p. 139560.

Kabir, Md. Tanvir Uddin, Md. Sahab Hossain, Md. Farhad Abdulhakim, Jawaher A. Alam, Md. Asraful Ashraf, Ghulam Md Bungau, Simona G. Bin-Jumah, May N. Abdel-Daim, Mohamed M. and Aleya, Lotfi 2020. nCOVID-19 Pandemic: From Molecular Pathogenesis to Potential Investigational Therapeutics. Frontiers in Cell and Developmental Biology, Vol. 8, Issue. ,

Shahzad, Farrukh Shahzad, Umer Fareed, Zeeshan Iqbal, Najaf Hashmi, Shujahat Haider and Ahmad, Fayyaz 2020. Asymmetric nexus between temperature and COVID-19 in the top ten affected provinces of China: A current application of quantile-on-quantile approach. Science of The Total Environment, Vol. 736, Issue. , p. 139115.

Li, Adam Y. Hannah, Theodore C. Durbin, John R. Dreher, Nickolas McAuley, Fiona M. Marayati, Naoum Fares Spiera, Zachary Ali, Muhammad Gometz, Alex Kostman, JT and Choudhri, Tanvir F. 2020. Multivariate Analysis of Black Race and Environmental Temperature on COVID-19 in the US. The American Journal of the Medical Sciences, Vol. 360, Issue. 4, p. 348.

Download full list

Article contents

Environmental factors on the SARS epidemic: air temperature, passage of time and multiplicative effect of hospital infection

Abstract

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests