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Research about the optimal strategies for prevention and control of varicella outbreak in a school in a central city of China: based on an SEIR dynamic model

Published online by Cambridge University Press:  17 March 2020

Wen-ting Zha ,
Feng-rui Pang Open the ORCID record for Feng-rui Pang [Opens in a new window] ,
Nan Zhou ,
Bin Wu Open the ORCID record for Bin Wu [Opens in a new window] ,
Ying Liu ,
Yan-bing Du ,
Xiu-qin Hong  and
Yuan Lv Open the ORCID record for Yuan Lv [Opens in a new window]
Wen-ting Zha
Affiliation:
Key Laboratory of Molecular Epidemiology of Hunan Province, School of Medicine, Hunan Normal University, Changsha, Hunan410081, People's Republic of China
Feng-rui Pang
Affiliation:
Key Laboratory of Molecular Epidemiology of Hunan Province, School of Medicine, Hunan Normal University, Changsha, Hunan410081, People's Republic of China
Nan Zhou
Affiliation:
Key Laboratory of Molecular Epidemiology of Hunan Province, School of Medicine, Hunan Normal University, Changsha, Hunan410081, People's Republic of China
Bin Wu
Affiliation:
Key Laboratory of Molecular Epidemiology of Hunan Province, School of Medicine, Hunan Normal University, Changsha, Hunan410081, People's Republic of China
Ying Liu
Affiliation:
Key Laboratory of Molecular Epidemiology of Hunan Province, School of Medicine, Hunan Normal University, Changsha, Hunan410081, People's Republic of China
Yan-bing Du
Affiliation:
Key Laboratory of Molecular Epidemiology of Hunan Province, School of Medicine, Hunan Normal University, Changsha, Hunan410081, People's Republic of China
Xiu-qin Hong
Affiliation:
Key Laboratory of Molecular Epidemiology of Hunan Province, School of Medicine, Hunan Normal University, Changsha, Hunan410081, People's Republic of China
Yuan Lv*
Affiliation:
Key Laboratory of Molecular Epidemiology of Hunan Province, School of Medicine, Hunan Normal University, Changsha, Hunan410081, People's Republic of China
*
Author for correspondence: Yuan LV, E-mail: 183259829@qq.com or ly598598@126.com
Rights & Permissions [Opens in a new window]

Abstract

Varicella is an acute respiratory infectious diseases, with high transmissibility and quick dissemination. In this study, an SEIR (susceptible-exposed-infected-recovered) dynamic model was established to explore the optimal prevention and control measures according to the epidemiological characteristics about varicella outbreak in a school in a central city of China. Berkeley Madonna 8.3.18 and Microsoft Office Excel 2010 software were employed for the model simulation and data management, respectively. The result showed that the simulated result of SEIR model agreed well with the reported data when β (infected rate) equal to 0.067. Models showed that the cumulative number of cases was only 13 when isolation adopted when the infected individuals were identified (assuming isolation rate was up to 100%); the cumulative number of cases was only two and the TAR (total attack rate) was 0.56% when the vaccination coefficient reached 50%. The cumulative number of cases did not change significantly with the change of efficiency of ventilation and disinfection, but the peak time was delayed; when δ (vaccination coefficient) = 0.1, m (ventilation efficiency) = 0.7 or δ = 0.2, m = 0.5 or δ = 0.3, m = 0.1 or δ = 0.4 and above, the cumulative number of cases would reduce to one case and TAR would reduce to 0.28% with combined interventions. Varicella outbreak in school could be controlled through strict isolation or vaccination singly; combined interventions have been adopted when the vaccination coefficient was low.

Keywords

IsolationSEIR modelvaccineventilation and disinfectionvaricella
Type
Original Paper
Information
Epidemiology & Infection , Volume 148 , 2020 , e56
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2020

Introduction

Varicella, commonly caused by varicella-zoster virus (VZV), is an acute respiratory infectious disease characterised by pruritic macules, papules and blisters, often accompanied by headache, fever, sore throat or other respiratory infection symptoms [Reference Su, Xing and Liang1]. Varicella outbreaks often occur in schools in children with high transmissibility and quick dissemination [Reference Parkins, Mcneil and Laupland2]. In the USA, 90% of children under 15 years old have been exposed to VZV, and at least 90% of children over 9 years old in Germany or Belgium showed positive varicella serum antibodies [Reference Wiese-Posselt3]. In China, about 77.06% of varicella outbreaks occurred in primary schools [Reference Su4], which could significantly affect the health of students, the provision of education in schools and the normal life of families [Reference Liu5]. The prevention and control of varicella outbreak have become the focus of health work in schools [Reference Pan and Zhang6].

Currently, there is no specific treatment for varicella, the main prevention and control strategies of varicella outbreaks included vaccination, closure and isolation, window ventilation, wiping or spraying disinfection [Reference Wang7]. But due to ethical issues, limited research has been conducted regarding the comparative effectiveness of control measures for varicella [Reference Chen8], and it is difficult to evaluate the effectiveness of preventive and control measures through traditional epidemiological methods. Dynamic model, such as the susceptible-infected-recovered (SIR) model which successfully simulates the prevalence of infectious diseases [Reference Chen9, Reference Chen and Liu10], has been used to evaluate the efficacy of preventive and control measures for infectious diseases. But no SIR model of varicella in central China has been researched. Thus, in this study, a susceptible-exposed-infected-recovered (SEIR) epidemic dynamics model was established to explore the optimal prevention and control measures according to the epidemiological characteristics about varicella outbreak in the school in ChangSha, a central city of China, which could provide a reference for dealing with similar incidents in other areas and formulate the prevention and control strategies of varicella outbreak in school.

Methods

Data collection

Data on varicella outbreak came from a public primary school in a central city in China reported by the Center for Disease Control and Prevention (CDC) of Changsha in the year 2016. The school contained six grades, eight classes, a total of 360 people. Students attend classes 5 days a week (from Monday to Friday), and boiled water was unified supplied by the school. Varicella cases were diagnosed clinically based on the history of infectious agent exposure and clinical features, such as pruritic macules, papules, blisters and respiratory infection symptoms.

Models

Model of varicella outbreak without interventions

An SEIR model [Reference Horn, Damm and Greiner11, Reference Hethcote, Zhien and Shengbing12] was established to simulate the transmission of varicella in school without any intervention. Population in this model was divided into four categories according to the disease status (Fig. 1a): susceptible (S), exposed (E), infected (I) and recovered (R). The model was developed based on the following facts or assumptions, which assumed that some individuals moved among categories because of infection or recovery: (1) The population was defined as closed and stable, because the varicella outbreak usually occurred in school in which birth, death and migration were negligible; (2) susceptible person was assumed to have an equal infected rate (β) with the disease; (3) after infection, the exposed person (E) would turn to infected individuals (I) after a certain exposed period (1/ω), the number of newly infected individuals per unit time was ωE; (4) γ represented the recovery rate, and 1/γ meant the infective period, the number of newly recovered individuals per unit time was γI; (5) the fatality rate of both varicella and asymptomatic infection was ignored. The corresponding model equations are as follows, dS/dt, dE/dt, dI/dt and dR/dt denoted the number of individuals (n) at time t in the corresponding categories:

(1)$$\left\{ \matrix{dS/dt = -\beta SI \hfill \cr dE/dt = \beta SI-\omega E \hfill \cr dI/dt = \omega E-\gamma I \hfill \cr dR/dt = \gamma I \hfill} \right.$$

Fig. 1. Flow chart of models of varicella outbreak in school.

Model of varicella outbreak with case isolation

Isolation would be adopted when the infected individuals (I) were identified. We assumed that the isolation rate was ψ, ψI individuals have been isolated and turned to quarantine (Q), which were not infectious. Population in the SEIQR model was divided into five categories (Fig. 1b), and the corresponding model equations are as follows:

(2)$$\left\{ \matrix{dS/dt = -\beta SI \hfill \cr dE/dt = \beta SI-\omega E \hfill \cr dI/dt = \omega E-\psi I-(1-\psi )\gamma I \hfill \cr dQ/dt = \psi I-\gamma Q \hfill \cr dR/dt = \gamma Q + (1-\psi )\gamma I \hfill} \right.$$

Model of varicella outbreak with vaccination

The SEIRV model was constructed by vaccinating susceptible people, who were separated from susceptible people and turned to vaccination (V) directly because of their immunity to varicella. Assuming that the vaccination coefficient was δ, the number of susceptible (S) individuals turned to exposed (E) at t time were (1–δ)SβI. Population in this model was divided into five categories (Fig. 1c), and the corresponding model equations are as follows, the epidemic trend under different vaccination coefficients would be simulated by adjusting δ.

(3)$$\left\{ \matrix{dS/dt = -\delta S-(1-\delta )\beta SI \hfill \cr dE/dt = (1-\delta )\beta SI-\omega E \hfill \cr dI/dt = \omega E-\gamma I \hfill \cr dR/dt = \gamma I \hfill \cr dV/dt = \delta S \hfill} \right.$$

Model of varicella outbreak with ventilation and disinfection

Ventilation and disinfection (spraying or wiping the classroom, corridor floor and public facilities with ‘84’ disinfectants or disinfecting the air through oxyacetic acid and ultraviolet lamp) were adopted to reduce the infected rate (β) of varicella virus [Reference Zhao13, Reference Liu14]. Assuming that m was the efficiency of ventilation and disinfection to eliminate the varicella virus, the number of individuals in some categories in this model would change. The model is shown in Fig. 1d and the corresponding equations are as follows:

(4)$$\left\{ \matrix{dS/dt = -\beta S(1-m)I \hfill \cr dE/dt = \beta S(1-m)I-\omega E \hfill \cr dI/dt = \omega E-\gamma I \hfill \cr dR/dt = \gamma I \hfill} \right.$$

Modelling combinations of the intervention strategies

For the varicella outbreak in a school, we simulated the combinations of intervention strategies (isolation, vaccine, ventilation and disinfection) to explore the influence on the control of varicella outbreak in school.

(5)$$\left\{ \matrix{dS/dt = -\delta S-(1-\delta )S(1-m)\beta I \hfill \cr dE/dt = (1-\delta )S(1-m)\beta I-\omega E \hfill \cr dI/dt = \omega E-\psi I-(1-\psi )\gamma I \hfill \cr dQ/dt = \psi I-\gamma Q \hfill \cr dR/dt = \gamma Q + (1-\psi )\gamma I \hfill \cr dV/dt = \delta S \hfill} \right.$$

Parameter estimation

There were six parameters in all models in this study, which were infected rate (β), latency coefficient (ω), removal rate (γ), isolation rate (ψ), vaccination coefficient (δ), disinfection and ventilation efficiency (m). The parameters ω, γ, ψ and δ could be obtained by combining the actual situation with literatures, while β could be obtained by fitting the actual data of model (1) and typical outbreak cases. Literature analysis showed that the exposure period of varicella is 10–21 days [Reference Marin15]; in this study, we assumed the exposure period (1/ω) as 21 days, so ω would equal to 1/21. Usually, the infected period of varicella was from 1 to 2 days before the eruption to scab formation; however, students would take medical measures once they have fever, rash or other symptoms; so, the infected period of varicella in school was usually shorter than the natural infection period. In this study, we assumed the isolation rate ψ was equal to 100%, the infection period (1/γ) was 3 days and the recovery rate γ was equal to 1/3 [Reference Suo, Lu and Chen16Reference Liu, Mu and Lv17]. Combining with the actual situation, in order to explore the influence of vaccination coefficient (δ) and the efficiency of ventilation and disinfection (m) on the control of epidemic situation of varicella outbreak in school, we have set δ as 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7 and m as 0.1, 0.3, 0.5, 0.7, 0.9, respectively. All parameters and initial values of each category are listed in Table 1.

Table 1. List of parameters and initial values of each category in models

Simulation methods

We fitted the data from the varicella outbreak in a school in a central city of China to an SEIR model curve to estimate β and then simulated the effects of isolation, vaccine, ventilation and disinfection in the outbreak. Berkeley Madonna 8.3.18 and Microsoft Office Excel 2010 software were employed for the model simulation and data management, respectively. Graphpad prism 5 was used for the figure development, while the curve fitting problem was solved by the Runge–Kutta fourth-order method, with a tolerance of 0.001. A goodness-of-fit test (χ2 test) was performed using the IBM-SPSS software, in which the significance level was α = 0.05.

Intervention assessment

The total attack rate (TAR), cumulative number of cases and duration of outbreak (DO, duration in days from index case to last case) were used to assess the effectiveness of control interventions in the varicella outbreak. Epidemic curves were used to evaluate the effectiveness using the strategies that are compared with the actual situation.

Results

Epidemiological features of the outbreak

From September 23 to October 29 in the year 2016, 35 students in a school of Changsha had been diagnosed with varicella, the incidence rate was 9.72%. The first case was a fourth-grade girl, who developed symptoms on September 23. Thirty-five patients (16 boys and 19 girls) ranged from 5 to 11 years old and most of them were in the fourth grade (44.4%) and fifth grade (25.0%). Most cases were concentrated from September 23 to October 11, and no new cases of varicella were reported in the school and surrounding areas, all of them were cured as of 27 October 2016. (During this period, the school did not adopt targeted prevention and control measures.) The distribution of time among students of varicella outbreak was shown in Figure 2.

Fig. 2. The distribution of time among students in the outbreak.

Results of curve fitting

We set the simulation period of this study to 100 days, and the simulation result showed that the number of cases increased heading into the peak in the first 13 days, then decreased until no cases existed, indicating that the outbreak was complete (Fig. 3). The results of curve fitting of the outbreak data and SEIR model showed that the simulated result agreed well with the reported data when β is equal to 0.067 (R 2 = 0.816, P < 0.01), there was no significant difference between the theoretical value and the actual value (χ 2 = 0.608, P > 0.05).

Fig. 3. The result of curve fitting of outbreak data and SEIR model.

Case isolation

SEIQR model showed that the cumulative number of cases would drop to 13 when isolation started from the date of discovery of patients (assuming isolation rate was up to 100%). The cumulative number of cases was significantly less than the actual situation, which meant that strict isolation of patients could effectively reduce the number of cases (Fig. 4a).

Fig. 4. The control effect of isolation, vaccination, ventilation and disinfection.

Vaccination

SEIRV model showed that the cumulative number of cases would drop to two and the TAR would drop to 0.56% when the vaccination coefficient reached 50%, which meant that the epidemic situation could be well controlled through vaccination, and the higher the vaccination coefficient, the better the epidemic control effect (Fig. 4b).

Ventilation and disinfection

SEIR model showed that when the effective rates of ventilation and disinfection were 10%, 30%, 50%, 70% and 90%, the cumulative number of cases were 35, 35, 34, 33 and 25, and the duration of the epidemic was 19, 20, 23, 26 and 46 days, respectively. With the change of ventilation and disinfection efficiency, the cumulative number of patients did not change significantly, but the peak time was delayed. Only when the disinfection efficiency reached 90%, the cumulative number of patients could be slightly reduced, but the duration of the epidemic was also significantly prolonged; ventilation and disinfection had no obvious effect on the control of varicella outbreak in school (Fig. 4c).

Combined intervention

The cumulative number of patients and TAR could be significantly reduced with combined interventions. When δ = 0.1, m = 0.7 or δ = 0.2, m = 0.5 or δ = 0.3, m = 0.1 or δ = 0.4 and above, the cumulative number of cases would reduce to one case and TAR would reduce to 0.28%, the varicella outbreak could be controlled well (Table 2 and Fig. 5).

Fig. 5. The control effect of combined intervention.

Table 2. The effect of combined intervention on the control of varicella outbreak

Discussion

Varicella is very contagious and often occurs in children, which has a great negative effect on school [Reference Li and Liu18]. In this study, an SEIR epidemic dynamics model was established to explore the optimal prevention and control measures according to the epidemiological characteristics of varicella for controlling future outbreaks, which is the first time to establish an SEIR model of varicella outbreak in the school of China.

There were three common ways to prevent and control varicella, which were vaccination, isolation, ventilation and disinfection. Models showed that the epidemic situation of varicella outbreak could be well controlled through isolation or vaccination singly, but ventilation and disinfection alone had no obvious effect on the control of varicella outbreak in school. Strict isolation could control the outbreak of varicella, but due to the influence of diagnosis conditions and other factors, the cases with varicella we have found in the first time only accounted for a part of all patients, and the isolation rate was difficult to reach 100% [Reference Zhang19]. Therefore, in order to control the development of varicella, it is necessary to take initiative of students and parents to report the disease timely or monitor the temperature of students every day during the period of high incidence of varicella to raise the isolation rate in the actual situation. The varicella vaccine was approved and marketed in the USA in 1995, but the vaccination coefficient in China was not high because the varicella vaccine was voluntary. It took 15 days to produce antibodies after vaccination [Reference Wu20Reference Suo, Lu and Wang21]; therefore, it is necessary to improve the vaccination coefficient of varicella for students, a high-risk group, and they should be vaccinated early at least 15 days before the period of high incidence of varicella, which usually is in the 16th and 45th weeks per year [Reference Pang22]. In the actual prevention and control work, ventilation and disinfection are also one of the important prevention and control measures. However, the results of this study indicated that the epidemic situation has not been effectively alleviated by reducing the density of VZV in the environment through ventilation and disinfection measures alone, which may be due to the fact that varicella virus mainly comes from the herpes fluid in the skin lesion of the patient's eruption site or the respiratory secretion of the patient [Reference Su4].

Models showed that the cumulative number of patients and TAR could be significantly reduced with combined interventions. On the basis of strict case isolation, the vaccination coefficient of varicella vaccine among students was investigated. In the actual work, when the vaccination coefficient was lower than 0.4, combined interventions (isolation plus vaccination plus ventilation and disinfection) could be taken to intervene comprehensively.

We modelled a theoretical isolation and did not consider all actual interventions; therefore, differences remained between the simulation and the actual outbreak, which is the limitation in our study.

Conclusions

Varicella outbreak in the school of China could be well controlled through strict isolation or vaccination singly, but ventilation and disinfection alone had no obvious effect on the control of varicella outbreak in school; combined interventions of isolation, vaccination, ventilation and disinfection could be adopted when the vaccination coefficient was low.

Acknowledgements

We are grateful to everyone who helped us to complete this study successfully.

Financial support

The work was supported by JG2018B041, Education Project of Hunan Provincial Department ([2017] No. 451) and ([2017] No. 452).

Conflict of interest

On behalf of all authors, the corresponding author states that there is no conflict of interest.

Ethical standards

Not required.

Footnotes

*

Wen-ting ZHA and Feng-rui PANG contributed equally to this work

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Figure 0

Fig. 1. Flow chart of models of varicella outbreak in school.

Figure 1

Table 1. List of parameters and initial values of each category in models

Figure 2

Fig. 2. The distribution of time among students in the outbreak.

Figure 3

Fig. 3. The result of curve fitting of outbreak data and SEIR model.

Figure 4

Fig. 4. The control effect of isolation, vaccination, ventilation and disinfection.

Figure 5

Fig. 5. The control effect of combined intervention.

Figure 6

Table 2. The effect of combined intervention on the control of varicella outbreak