Risk-adjusted zero-inflated Poisson CUSUM charts for monitoring influenza surveillance data

The influenza surveillance has been received much attention in public health area. For the cases with excessive zeroes, the zero-inflated Poisson process is widely used. However, the traditional control charts based on zero-inflated Poisson model, ignore the association between influenza cases and risk factors, and thus may lead to unexpected mistakes when implementing monitoring charts. In this paper, we proposed risk-adjusted zero-inflated Poisson cumulative sum control charts, in which the risk factors were put to adjust the risk of influenza and the adjustment was made by zero-inflated Poisson regression. We respectively proposed the control chart monitoring the parameters individually and simultaneously. The performance of our proposed risk-adjusted zero-inflated Poisson cumulative sum control chart was evaluated and compared with the unadjusted standard cumulative sum control charts in simulation studies. The results show that for different distribution of impact factors and different coefficients, the risk-adjusted cumulative sum charts can generate much less false alarm than the standard ones. Finally, the influenza surveillance data from Hong Kong is used to illustrate the application of the proposed chart. Our results suggest that the adjusted cumulative sum control chart we proposed is more accurate and credible than the unadjusted standard control charts because of the lower false alarm rate of the adjusted ones. Even the unadjusted control charts may signal a little faster than the adjusted ones, the alarm they raise may have low credibility since they also raise alarm frequently even the processes are in control. Thus we suggest using the risk-adjusted cumulative sum control charts to monitor the influenza surveillance data to alert accurately, credibly and relatively quickly.

[1]  Christos Koukouvinos,et al.  Monitoring of zero‐inflated Poisson processes with EWMA and DEWMA control charts , 2019, Qual. Reliab. Eng. Int..

[2]  E. S. Page CONTINUOUS INSPECTION SCHEMES , 1954 .

[3]  Thong Ngee Goh,et al.  Zero-inflated Poisson model in statistical process control , 2002 .

[4]  E. Lofgren,et al.  Influenza Seasonality: Underlying Causes and Modeling Theories , 2006, Journal of Virology.

[5]  R. Serfling Methods for current statistical analysis of excess pneumonia-influenza deaths. , 1963, Public health reports.

[6]  Keiji Fukuda,et al.  Mortality associated with influenza and respiratory syncytial virus in the United States. , 2003, JAMA.

[7]  Diane Lambert,et al.  Zero-inflacted Poisson regression, with an application to defects in manufacturing , 1992 .

[8]  Richard K. Kiang,et al.  The Role of Temperature and Humidity on Seasonal Influenza in Tropical Areas: Guatemala, El Salvador and Panama, 2008–2013 , 2014, PloS one.

[9]  Fugee Tsung,et al.  Online profile monitoring for surgical outcomes using a weighted score test , 2018 .

[10]  G. Pazour,et al.  Ror2 signaling regulates Golgi structure and transport through IFT20 for tumor invasiveness , 2017, Scientific Reports.

[11]  Christos Koukouvinos,et al.  A generally weighted moving average control chart for zero‐inflated Poisson processes , 2019, Qual. Reliab. Eng. Int..

[12]  Benjamin J Cowling,et al.  Methods for monitoring influenza surveillance data. , 2006, International journal of epidemiology.

[13]  Shuguang He,et al.  CUSUM charts for monitoring a zero‐inflated poisson process , 2012, Qual. Reliab. Eng. Int..

[14]  J. Tang,et al.  Association between meteorological variations and activities of influenza A and B across different climate zones: a multi-region modelling analysis across the globe. , 2019, The Journal of infection.

[15]  Shuguang He,et al.  A combination of CUSUM charts for monitoring a Zero-inflated Poisson process , 2012 .

[16]  Zhiwei Xu,et al.  Monitoring Pertussis Infections Using Internet Search Queries , 2017, Scientific Reports.

[17]  J. Crilly,et al.  Prediction and surveillance of influenza epidemics , 2011, The Medical journal of Australia.

[18]  M. H. Lim,et al.  Attribute Charts for Zero-Inflated Processes , 2008, Commun. Stat. Simul. Comput..

[19]  Nan Chen,et al.  Attribute control charts using generalized zero‐inflated Poisson distribution , 2008, Qual. Reliab. Eng. Int..

[20]  Rassoul Noorossana,et al.  ZERO INFLATED POISSON EWMA CONTROL CHART FOR MONITORING RARE HEALTH-RELATED EVENTS , 2012 .

[21]  Vern T. Farewell,et al.  An overview of risk‐adjusted charts , 2004 .

[22]  Mahmoud A. Mahmoud,et al.  An adaptive EWMA control chart for monitoring zero-inflated Poisson processes , 2019, Commun. Stat. Simul. Comput..

[23]  LambertDiane Zero-inflated Poisson regression, with an application to defects in manufacturing , 1992 .

[24]  Hilde van der Togt,et al.  Publisher's Note , 2003, J. Netw. Comput. Appl..

[25]  S. Steiner,et al.  Monitoring surgical performance using risk-adjusted cumulative sum charts. , 2000, Biostatistics.

[26]  Zhen He,et al.  A Combination of CUSUM Charts for Monitoring a Zero-Inflated Poisson Process , 2014, Commun. Stat. Simul. Comput..

[27]  Thong Ngee Goh,et al.  Spc of a near zero-defect process subject to random shocks , 1993 .

[28]  Kerrie Mengersen,et al.  Using Google Trends and ambient temperature to predict seasonal influenza outbreaks. , 2018, Environment international.

[29]  Richard K. Kiang,et al.  Modeling and Predicting Seasonal Influenza Transmission in Warm Regions Using Climatological Parameters , 2010, PloS one.

[30]  Dankmar Böhning,et al.  On estimation of the Poisson parameter in zero-modified Poisson models , 2000 .

[31]  R. Kiang,et al.  Associations between Meteorological Parameters and Influenza Activity in Berlin (Germany), Ljubljana (Slovenia), Castile and León (Spain) and Israeli Districts , 2015, PloS one.