［1］SOSIN D M. Draft framework for evaluating syndromic surveillance systems［J］. J Urban Health, 2003, 80( suppl 1):i8-i13.
［2］MAY L, CHRETIEN J P, PAVLIN J A. Beyond traditional surveillance: Applying syndromic surveillance to developing settings: Opportunities and challenges［J］. BMC Public Health, 2009, 9:242.
［3］GONG M C, LIU L, SUN X, et al. Cloud-based system for effective surveillance and control of COVID-19:Useful experiences from Hubei, China［J］. J Med Internet Res, 2020, 22(4):e18948.
［4］WEE L E, SIM X Y J, CONCEICAO E P, et al. Containment of COVID-19 cases among healthcare workers: The role of surveillance, early detection, and outbreak management［J］. Infect Control Hosp Epidemiol, 2020, 41(7):765-771.
［5］DENIS F, GALMICHE S, DINH A, et al. Epidemiological observations on the association between anosmia and COVID-19 infection: Analysis of data from a selfassessment web application［J］. J Med Internet Res, 2020, 22(6):e19855.
［6］LOKUGE K, BANKS E, DAVIS S, et al. Exit strategies: Optimising feasible surveillance for detection, elimination, and ongoing prevention of COVID-19 community transmission［J］. BMC Med, 2021, 19(1):50.
［7］SIM J X Y, CONCEICAO E P, WEE L E, et al. Utilizing the electronic health records to create a syndromic staff surveillance system during the COVID-19 outbreak［J］. Am J Infect Control, 2021, 49(6):685-689.
［8］ENGLAND PUBLIC HEALTH: Syndromic surveillance: systems and analyses［EB/OL］. (2021-01-27)［2021-09-07］. https://www.gov.uk/government/collections/syndromic-surveillance-systems-and-analyses#remote-health-advice-syndromic-surveillance-system.
［9］MENNI C, VALDES A M, FREIDIN M B, et al. Real-time tracking of self-reported symptoms to predict potential COVID-19［J］. Nat Med, 2020, 26(7):1037-1040.
［10］GÜEMES A, RAY S, ABOUMERHI K, et al. A syndromic surveillance tool to detect anomalous clusters of COVID-19 symptoms in the United States［J］. Sci Rep, 2021, 11(1):4660.

［11］LAPOINTE-SHAW L, RADER B, ASTLEY C M, et al. Web and phone-based COVID-19 syndromic surveillance in Canada: A cross-sectional study［J］. PLoS One, 2020, 15(10):e0239886. 
［12］MAHMUD A S, CHOWDHURY S, SOJIB K H, et al. Participatory syndromic surveillance as a tool for tracking COVID-19 in Bangladesh［J］. Epidemics, 2021, 35:100462. 
［13］LUO H X, LIE Y C, PRINZEN F W. Surveillance of COVID-19 in the general population using an online questionnaire: Report from 18, 161 respondents in China［J］. JMIR Public Health Surveill, 2020, 6(2):e18576.
［14］KATZ R, MAY L, BAKER J, et al. Redefining syndromic surveillance［J］. J Epidemiol Glob Health, 2011, 1(1):21-31. 
［15］KURIAN S J, BHATTI A U R, ALVI M A, et al. Correlations between COVID-19 cases and google trends data in the United States: A state-by-state analysis［J］. Mayo Clin Proc, 2020, 95(11):2370-2381. 
［16］江震．美国预防突发传染疾病，建立快速预警监测系统［J］．国外医学(卫生经济分册)，2004，21(1)：44-47． 
［17］汪雪洋，张玉，龚文胜．襄阳市新型冠状病毒肺炎疫情期间发热门诊症状监测系统数据分析［J］．公共卫生与预防医学，2020，31(4)：28-30． 
［18］YONEOKA D, TANOUE Y, KAWASHIMA T, et al. Largescale epidemiological monitoring of the COVID-19 epidemic in Tokyo［J］. Lancet Reg Health West Pac, 2020, 3:100016.
［19］MARZAN-RODRIGUEZ M, MORALES L M, MARTINEZ I S, et al. Syndromic surveillance in Puerto Rico during the COVID-19 response: An alternative approach to scarce molecular testing［J］. Am J Public Health, 2020, 110(9):1348-1349. 
［20］GOULD D W, WALKER D, YOON P W. The evolution of BioSense: Lessons learned and future directions［J］. Public Health Rep, 2017, 132(1_suppl):7S-11S. 
［21］[KG*2]〖ZK(]YONEOKA D, KAWASHIMA T, TANOUE Y, et al. Early SNS-based monitoring system for the COVID-19 outbreak in Japan: A population-level observational study［J］. J Epidemiol, 2020, 30(8):362-370.
［22］程瑾，杨晓茹，张群，等．美军症状监测系统ESSENCE典型案例分析及借鉴［J］．军事医学，2014，38(2)：112-116． 
［23］DAI Y Y, WANG J M. Identifying the outbreak signal of COVID-19 before the response of the traditional disease monitoring system［J］. PLoS Negl Trop Dis, 2020, 14(10):e0008758.